Choice of Phylogenetic Method

The general goal of phylogenetic systematics is to explain the diversity of life by discovering the evolutionary relationships among species, where inferred transformations from one character-state to another provide the means to choose among competing explanations. That is, phylogenetic hypotheses are composite explanations consisting of both hypotheses of homology (transformation series; Hennig, 1966; see Grant and Kluge, 2004) and hypotheses of monophyly (topology). Farris (1967) expressed this succinctly by analyzing the concept of evolutionary relationship into its component parts of patristic relationship and cladistic relationship.

Operationally, phylogenetic analysis begins by decomposing the observed diversity of living things into its minimal historical units: character-states (sensu Grant and Kluge, 2004) and species (sensu Kluge, 1990; see also Grant, 2002). Although character-states are the evidential basis that underlies phylogenetic inference, they are effectively “bundled” into individual organisms, populations, and species, which constrains the ways in which they evolve and how they may be explained (e.g., females and males evolve as parts of the same lineage; defensible phylogenetic explanations are therefore not permitted to place them in separate clades). Likewise, species, which are the historical entities related through phylogeny (Hennig, 1966), may be decomposed into independently heritable (and independently variable) parts, that is, character-states. This ontological transitivity of taxic and character evolution is the foundation of phylogenetic inference (cf. Farris, 1967).

Once these minimal units have been individuated, all possible historical relationships between character-states and species are defined by pure logic (Siddall and Kluge, 1997; Wheeler, 1998). Phylogenetic analysis proceeds by mapping hypothetical character-state relationships to hypothetical species relationships and evaluating the competing composite hypotheses in terms of the number of character-state transformations they entail.

All phylogenetic methods aim to minimize character transformations. Unweighted (equally weighted) parsimony analysis minimizes hypothesized transformations globally, whereas assumptions (expressed as differential probabilities or costs) about the evolution or importance (e.g., reliability) of different classes of transformations employed in maximum likelihood, Bayesian analysis, and weighted parsimony methods lead to the minimization of certain classes of transformations at the expense of others. Operational considerations aside (e.g., tree-space searching capabilities), disagreements between the results of unweighted parsimony analysis and the other methods are due to the increased patristic distance required to accommodate the additional assumptions.

Kluge and Grant (2006) reviewed the justifications for parsimonious phylogenetic inference previously considered sufficient, namely, conviction (Hennig, 1966), descriptive efficiency (Farris, 1979), minimization of ad hoc hypotheses of homoplasy (Farris, 1983), and statistical, model-based inference (maximum likelihood, Sober, 1988). Finding significant inconsistencies in all of those justifications, Kluge and Grant (2006) proposed a novel justification for parsimony. Drawing on recent advances in the understanding of phylogenetics as a strictly ideographic, historical science and parsimonious inference generally in the philosophy of science literature (e.g., Barnes 2000; Baker, 2003), they argued that by minimizing globally the transformation events postulated to explain the character-states of terminal taxa, equally weighted parsimony analysis maximizes explanatory power. As such, in the present study we analyzed the total, equally weighted evidence under the parsimony criterion (for additional discussion of character weighting and total evidence, see Grant and Kluge, 2003). Given the size and complexity of this dataset, a further advantage of parsimony algorithms (whether weighted or unweighted) is that thorough analysis could be achieved in reasonable times given available hard- and software.

Sources of Evidence

The empirical evidence of phylogenetic systematics consists of transformation series (i.e., the ideographic character concept of Grant and Kluge, 2004). Traditionally, transformation series were derived exclusively from such sources as comparative morphology, molecular biology, and behavior, but as technological advances have made DNA sequencing simpler and less costly, phylogenetic studies have come to rely increasingly on the genotypic evidence of DNA sequences to test phylogenetic hypotheses. The present study exemplifies this trend. Nevertheless, both kinds of data provide evidence of phylogeny, and each has its own suite of strengths and weaknesses.

An important strength of phenotypic data is that the complexity of observed variation allows the historical identity of each transformation series to be tested independently (Grant and Kluge, 2004). By carrying out progressively more detailed structural and developmental studies, researchers are able to refine their hypotheses about the homology of phenotypic variants. However, the phenotype is determined by both the directly heritable components of the genotype and the nonheritable effects of the environment. In contrast, an obvious strength of DNA sequence evidence is that, because DNA is the physical material of genetic inheritance, the potentially confounding effects of environmental factors are avoided altogether.

Nevertheless, DNA sequence character-states are maximally reduced to physico-chemically defined classes of nucleotides, of which there are only four (cytosine, guanine, adenine, and thymine). Whereas this simplicity is advantageous in many kinds of genetics studies, it poses a serious problem for phylogenetics, because no structural or developmental complexity to distinguishes nucleotides that share a common evolutionary history (i.e., those that are homologous, their physico-chemical identity owing to the same transformation event) from those that evolved independently (i.e., those that are homoplastic, their physico-chemical identity owing to independent transformation events). For example, in terms of object properties, all adenines are physico-chemically identical, regardless of whether or not they arose through the same or different transformation events. Moreover, DNA sequences evolve through complete substitutions of one nucleotide for another (meaning that there are no intermediate states from which to infer historical identity) or complete insertions and deletions (meaning that any given nucleotide could be homologous with any other nucleotide). Phylogenetic analysis of DNA sequences must therefore contend with the problem of discovering both transformations between nucleotides and the insertion and deletion of nucleotides. To visualize homologous nucleotides, multiple sequence alignments codify insertions and deletions (indels) as gaps, that is, placeholders that shift portions of the sequence to align homologous nucleotides into column vectors.

Nucleotide Homology and the Treatment of Indels

The method of inferring indels and nucleotide homology (i.e., alignment) and the subsequent treatment of indels in evaluating phylogenetic explanations are of critical importance in empirical studies because, as is now widely appreciated, a given dataset aligned according to different criteria or under different indel treatments may result in strong support for contradictory solutions (e.g., McClure et al., 1994; Wheeler, 1995). Many workers infer indels in order to align nucleotides but then either treat them as nucleotides of unknown identity by converting gaps to missing data, or they eliminate gap-containing column vectors altogether, either because they believe them to be unreliable or because the implementation of a method of phylogenetic analysis does not allow them (Swofford et al., 1996). Others argue that indels provide valid evidence of phylogeny but suggest that sequence alignment (homology assessment) and tree evaluation are logically independent and must be performed separately (e.g., Simmons and Ochoterena, 2000; Simmons, 2004).

The position we take here is that indels are evidentially equivalent to any other classes of transformation events and, as such, are an indispensable component of the explanation of the DNA sequence diversity. Furthermore, because nucleotides lack the structural and/or developmental complexity necessary to test their homology separately, hypotheses of nucleotide homology can only be evaluated in reference to a topology (Grant and Kluge, 2004; see also Wheeler, 1994; Phillips et al., 2000; Frost et al., 2001). In recognition of these considerations, we assessed nucleotide homology dynamically by optimizing observed sequences directly onto topologies (Sankoff, 1975; Sankoff et al., 1976) and heuristically evaluating competing hypotheses by searching tree space (Wheeler, 1996). This is achieved using Direct Optimization techniques (Wheeler, 1996, 2003a, 2003b, 2003c), as implemented in the computer program POY (Wheeler et al., 1996–2003).

In this approach, determination of nucleotide homology is treated as an optimization problem in which the preferred scheme of nucleotide homologies for a given topology is that which requires the fewest transformation events when optimized onto that topology, that is, that which minimizes patristic distance, thus providing the most parsimonious explanation of the observed diversity. Determining the optimal alignment for a given topology is NP-complete2 (Wang and Jiang, 1994). For even a miniscule number of sequences, the number of possible alignments is staggering (Slowinski, 1998), making exact solutions impossible for any contemporary dataset, and heuristic algorithms are required to render this problem tractable. Likewise, finding the optimal topology for a given alignment is also an NP-complete problem (Garey and Johnson, 1977; Garey et al., 1977).

Phylogenetic analysis under Direct Optimization therefore consists of two nested NP-complete problems. POY searches simultaneously for the optimal homology/topology combination, and search strategies must take into consideration the severity and effectiveness of the heuristic shortcuts applied at both levels. In any heuristic analysis, a balance is sought whereby the heuristic shortcuts will speed up analysis enough to permit a sufficiently large and diverse sampling of topologies and homologies to discover the global optimum during final refinement, but not so severe that the sample is so sparse or misdirected that the global optimum is not within reach during final refinement. Ideally, indicators of search adequacy (e.g., multiple independent minimum-length hits, stable consensus; see Goloboff, 1999; Goloboff and Farris, 2001) should be employed to judge the adequacy of analysis, as is now reasonable in analysis of large datasets using prealigned data (e.g., in TNT; Goloboff et al., 2003). However, current hard- and software limitations make those indicators unreachable in reasonable amounts of time for the present dataset analyzed under Direct Optimization, and the adequacy of our analysis may only be judged intuitively in light of the computational effort and strategic use of multiple algorithms designed for large datasets (see below for details).

Total Evidence

The majority of phylogenetic studies, even those legitimately considered “total evidence” (Kluge, 1989), examine either higher level or lower level problems. The former are designed to address relationships between putative clades of multiple species (usually discussed as species groups, genera, families, etc.) by targeting exemplars from each of those units and sampling relatively invariable character systems. The latter are designed to address species limits and relationships among closely related species (and often phylogeographic questions also), and character sampling focuses on more variable systems.

The nestedness of phylogenetic problems both enables and weakens this divide-and-conquer approach. Assuming the monophyly of a group, the relationships within that clade have no bearing on the relationships of that clade to other clades. And assuming the sister-group relationships between the ingroup and outgroup taxa, the relationships within the ingroup clade are independent of the relationships between that clade and more distant relatives. Nevertheless, although this is a defensible (provided the assumed monophyly and placement of the ingroup are supported by evidence) and presently necessary strategy, these assumptions may ultimately be found to be false, and their elimination allows hypotheses at both levels to be more severely tested and may lead to more globally parsimonious explanations. Furthermore, the ripple effects that cladistically distant optimizations may have throughout the topology are unpredictable, so that the inclusion of distant terminals that are not immediately relevant to a problem may affect local topology. The ultimate goal of total evidence is to analyze all evidence from all sources and all terminals at all levels simultaneously.

There are many obstacles, computational and otherwise, that prevent this ideal from being achieved in the foreseeable future. A potential criticism of this study is that we did not include all of the data from Frost et al. (2006). We restricted the outgroup sample to Athesphatanura to prevent the already computationally challenging problem of analyzing 414 terminals from becoming even more intractable. However, once hard- and software improvements permit thorough analysis of larger datasets, studies that extend outgroup sampling beyond Athesphatanura will offer a test of our results. Insofar as this study was designed to test both the species limits of problematic taxa and the relationships among dendrobatid clades, and to further test the relationships between dendrobatids and other anurans by combining the data from Frost et al. (2006) with new data from key outgroup taxa, it is intended to be a step toward the total evidence ideal. That this study aimed to simultaneously address problems of such different hierarchic levels had important consequences in taxon sampling, character sampling, and the analytical strategy that was undertaken.

Taxon Sampling

Outgroup taxa and the rationale for their selection are discussed above (Phylogenetic Placement of Dendrobatids and Outgroup Sampling). Selection of ingroup terminals was governed by three considerations: (1) relevance to testing prior phylogenetic claims, (2) availability of tissues (or sequences on GenBank), and (3) availability of specimens for morphological study. In light of the many problems in species-level taxonomy, we also sought to sample as many localities as possible for problematic species.

To facilitate taxonomic changes, every effort was made to include type species of all dendrobatid genera. Both genotypic and phenotypic data were included for type species of as many genera as possible, including (genus name in parentheses): azureiventris (Cryptophyllobates), bicolor (Phyllobates), femoralis (Allobates), inguinalis (Prostherapis), nocturnus (Aromobates), pulchellus (Phyllodromus), pumilio (Oophaga), reticulatus (Ranitomeya), silverstonei (Phobobates), steyermarki (Minyobates), tinctorius (Dendrobates), tricolor (Epipedobates), and trivittatus (Ameerega). We did not include the type species alboguttatus (Nephelobates), fuliginosus (Hyloxalus), latinasus (Colostethus), or yustizi (Mannophryne), because adequate data were not available to allow their inclusion in the present study. Nevertheless, we included numerous, presumably closely related representatives of these genera and made taxonomic changes accordingly.

Phenotypic Character Sampling

We anticipate that a criticism of the present study will be that we were too catholic in the inclusion of phenotypic characters. It is common for morphological systematists to seek characters that are conservative at their level of interest, under the assumption that they are more informative or reliable indicators of relationship, either explicitly (e.g., Kluge, 1993) or, much more commonly, implicitly. As a result, much of the systematics literature—especially the precladistic literature—consists of special pleading for the validity (or not) of characters as “higher-level”, “family-level”, “genus-level”, “species-level” or some other rank-specific indicator. Some characters (e.g., presence or absence of teeth, pectoral girdle architecture, skull morphology), it has been argued, are “good” genus- or family-level characters, others (e.g., external morphology, soft-anatomy) are “good” only at the level of species, and still others are unreliable and should be excluded in their entirety. We disagree.

For evolution to occur, all character transformation events must take place at (or below) the species level, and it is only subsequent cladogenetic events that effectively push character transformations back in history and bring them to delimit clades; there can be no natural law regulating variation of characters among clades. The historical debate over the phylogenetic relevance of anuran teeth illustrates the futility of that approach to systematics: maxillary teeth are absent in all species of Bufonidae—which would make this a conservative, phylogenetically informative character at the family level—but vary intraspecifically in some species of dendrobatids—making this a completely uninformative character according to that view. Given the conceptual definition of characters as transformation series (Grant and Kluge, 2004), all characters have the same evidential status in terms of their ability to test phylogenetic hypotheses. Arguments over the rank-specific relevance or reliability of characters depend on the reification of ranks and lead ultimately to the ad hoc dismissal or overlooking of evidence, and such procedures should be eliminated from systematics.

In addition to the novel characters and character-states discovered in the course of this study, our goal was to include all characters that have figured in debates on the monophyly, placement, and internal relationships of Dendrobatidae. However, because this study aims primarily to test relationships within Dendrobatidae and not the position of Dendrobatidae among other frogs, the sample of characters is strongly biased to reflect variation among dendrobatid terminals.

Numerous characters date to the 19th century (mainly Duméril and Bibron, Cope, Boulenger), and we do not always cite the original sources for these traditional characters. However, we do cite more recent papers that have addressed them in the context of dendrobatid systematics, and we cite original sources for all more recent characters. All phenotypic character-states for caeruleodactylus, humilis, and nidicola were coded from the literature (Lima and Caldwell, 2001; Caldwell et al., 2002a; La Marca et al., 2002; Caldwell and Lima, 2003). Other sources for phenotypic data are cited in the relevant sections below. For the purposes of discussion, phenotypic transformation series are classified broadly as morphological, larval, behavioral, and biochemical, the latter referring to alkaloid profiles. Specific problems or concerns regarding particular characters or character systems are discussed below independently. In anticipation of the expansion of the present dataset, we list states and show illustrations for taxa not included in the present analysis.

Comparative anatomical study aimed to delimit transformation series and not to describe dendrobatid (or outgroup) anatomy per se. We have illustrated either photographically or in line drawings those character-states we believe may cause confusion, and character names and descriptions were intended only to be sufficiently precise to allow hypotheses of homology to be tested. With the exception of characters related to the median lingual process, we coded anatomical characters only from gross dissection under a dissecting microscope. This is a limitation of the present study, as greater insight into character-state identity and homology would undoubtedly be gained from histology (e.g., consider the remarkable insights into pectoral girdle architecture attained by Kaplan, 2004). Osteological character-states were coded from dried or cleared and stained (alcian blue and alizarin red) skeletons. We considered tissue with alizarin red-positive crystals to be calcified and uniformly alizarin red-positive tissue to be ossified.

We applied either Lugol's solution or alcian blue to facilitate coding of muscle characters. All muscles are bound by fibrous connective tissue, so the distinction between tendinous and fleshy origins and insertions is one of degree: Tendinous insertions and origins have a confluence of muscle fibers on a distinct segment of fibrous connective tissue, whereas those that are fleshy appear to insert or originate directly on the adjacent structure. We consider a slip to be a distinct bundle of fasciculi isolated from adjacent fasciculi of the same muscle by epimysium.

We examined the histology of the tongues of several species to individuate characters of the median lingual process (Grant et al., 1997). Tissues were embedded in paraffin, sectioned at 6–10 µm, and stained using either hematoxylin and eosin (H&E) or a trichrome stain consisting of Alcian Blue, Periodic Acid and Schiff's reagent (PAS), and H&E. Specifically, we examined histological sections of baeobatrachus, tepuyensis, panamensis, and auratus (the latter two lacking the MLP). For comparison we examined the histology of Arthroleptis variabilis, Mantidactylus femoralis, Phrynobatachus natalensis, P. petropedetoides, Platymantis dorsalis, and Staurois natator, although none of these species were coded for the present study. We also performed detailed dissections of the tongues of atopoglossus, Arthroleptis stenodactylus, Discodeles bufoniformis, and Discodeles opisthodon.

In addition to the phenotypic characters individuated for this study, other sources of variation will undoubtedly yield novel characters. For example, spermatozoa ultrastructure is promising but has been examined in too few species to warrant inclusion in the present study. Garda et al. (2002) examined the spermatozoa of flavopictus, Aguiar et al. (2003) studied femoralis and an undescribed species referred by them to Colostethus (OMNH 37001–37002), and Aguiar et al. (2002) looked at the spermatozoa of hahneli and trivittatus. (For a recent review of spermatozoa in nondendrobatids, see Scheltinga and Jamieson, 2003).

Relevant to the placement of Dendrobatidae, Haas (2003) presented an impressive matrix of detailed morphological evidence scored across the diversity of anurans, much of which was derived from studies of larval anatomy. The evidential value of such data is manifest, but adequate samples were unavailable for most species included in this study. Haas found (see fig. 16, above) that the four included dendrobatids were monophyletic, and that their sister group was Hylodes + Crossodactylus (Megaelosia was not included in that study).

Bhaduri (1953) studied the urinogenital systems of diverse amphibians, including auratus, tinctorius, and flotator (as Phyllobates nubicola flotator). He noted several differences among these species, such as the greater posterior extension of the kidneys in Dendrobates than in Phyllobates (p. 56), but he nonetheless concluded that “[t]he structural similarities of the urinogenital organs which we have observed in these two genera lend further support to Noble's view [that Dendrobates and Phyllobates are closely related]” (p. 72). Although we scored some visceral characters (e.g., pigmentation of the testes, pigmentation of the large intestine), in light of time constraints and the fact that specific characters used by Bhaduri have not been used since and have therefore not played an important role in dendrobatid systematics, we did not study this system in detail.

Burton (1998a) argued that hand musculature supports a relationship between Dendrobatidae and Hylodinae, “as the unusual condition of lacking any fibrous connection to the tendo superficialis or the adjacent aponeurosis is almost restricted to the hylodine genera Hylodes and Megaelosia, and Dendrobatidae” (p. 8). However, the phylogenetic implications of this character are not clear-cut; assuming hylodine monophyly and a sister-taxon relationship with Dendrobatidae, as implied by Burton, the occurrence of this character-state would optimize as either independently evolved in Dendrobatidae and Hylodes + Megaelosia or as a synapomorphy of the inclusive clade with subsequent loss in Crossodactylus. We did not examine hand musculature in this study.

Trewavas (1933) included tinctorius3 in her study of the anuran hyoid and larynx. We examined the osteology of this system but did not examine its musculature. Our experience with other groups suggests that hyoid musculature may be a rich source of characters, and these characters will be evaluated in the near future.

There are also several morphological variants that have been claimed as characters in the literature that we reject in the present study. First, La Marca (1994, 2004) claimed the occurrence of enlarged, fanglike maxillary teeth as a synapomorphy for Nephelobates, and they also have been reported for Megaelosia (e.g., Lynch, 1971) and Aromobates (Myers et al., 1991), among others. Although we agree with La Marca and Myers et al. that dendrobatid tooth morphology varies and that the teeth of Aromobates and Nephelobates seem strikingly elongate and recurved, we were unable to individuate transformations series for several reasons, as follows (see fig. 19).

Figure 19

Examples of variation in dendrobatid maxillary teeth. A, B: lateral (A) and lingual (B) views of pictus (UMMZ 184099).

Note that the teeth do not protrude beyond the edge of the maxilla. C: lateral view of riveroi (AMNH 134144). D: lateral view of subpunctatus (UMMZ 221159). E: lateral view of undulatus (AMNH 159142). F: lateral view of molinarii (UMMZ 176207). G: lateral view of dunni (UMMZ 167131). H: lateral view of nocturnus (AMNH 129940).

(1) No appropriate reference point to assess relative tooth size has been proposed, and without this it is impossible to compare objectively the size of teeth in specimens of different species and varying body sizes and maxilla sizes and shapes (especially the shape and depth of the facial process). (2) Tooth size varies along the maxilla, and it is unclear which teeth should serve as the basis of comparison. (3) Superficial assessment of tooth size in cleared and stained specimens of a number of species suggested that variation is continuous, which must be accounted for when individuating transformations series. (4) All well-developed maxillary teeth (i.e., those that protrude beyond the edge of the maxilla) are recurved, at least in dendrobatids, and comparison of digital images (which eliminates the effect of relative size) shows the curvature of the so-called fanglike teeth of species referred to Nephelobates and Aromobates is no greater than those referred to Colostethus. In light of these considerations, we coded the presence and absence of maxillary teeth, as well as their structure, but not variation in size and shape.

Similarly, Lynch (1982) characterized edwardsi and ruizi as possessing a conspicuously large and elongate cloacal sheath (vent tube, anal sheath, embudo cloacal), and Rivero (1990 “1988”) subsequently referred to these species as the edwardsi group of Colostethus. Later, La Marca (1994) also claimed the presence of a cloacal sheath as a synapomorphy for Nephelobates, although he made no reference to that structure in the edwardsi group. The cloacal sheath has now been included in numbered diagnoses in species descriptions (e.g., Lötters et al., 2003a), and Grant (1998) cited its synapomorphic occurrence as the basis for including Colostethus lynchi in the edwardsi group. More recently, Grant (2004) noted, without further comment, that “examination of extensive material of most species of dendrobatids has caused me to doubt the validity of that character.”

The reason for that doubt is that, as shown in figure 20, only the two species originally placed in the edwardsi group (exemplified here by edwardsi) possess a conspicuously modified vent (cloacal sheath). Variations among other species of dendrobatids (including lynchi) are minor and cannot be distinguished from artifacts of preservation. Specimens that are positioned differently for fixation (whether floated in formalin or laid out in a fixing tray) vary in apparent vent morphology. For example, when a frog specimen is positioned in a fixing tray, the flaccid thigh muscles and loose skin may be pushed posterodorsally, causing the vent and adjacent tissue to “bunch up”, or anteroventrally, causing the vent and adjacent tissue to be drawn downward, both of which alter the apparent prominence, length, and shape of the vent. Desiccation also affects vent prominence. In light of these observations, the cloacal sheath is restricted to the two known species of the edwardsi group. We did not include the cloacal sheath, thus delimited, in the character matrix because we did not include edwardsi or ruizi due to inadequate material.

Figure 20

Posterior view of several species of dendrobatids, showing variation in morphology of the vent. A: edwardsi (ICN 21936). Contrary to the other species depicted, the vent of edwardsi is conspicuously enlarged and elongated relative to that of other anurans. B: molinarii (UMMZ 176222, paratype), a species referred to Nephelobates by La Marca (1994).

The vertical folds vary as an artifact of preservation. C: alboguttatus (AMNH 10503), the type species of Nephelobates. D: trinitatis (AMNH 125796), a species referred to Mannophryne by La Marca (1992). E: petersi (AMNH 42546). F: petersi (AMNH 42506). This species has never been claimed to be part of or closely related to Nephelobates. Note the differing prominence and apparent shape and size of the vent as an artifact of preservation.

Finally, Savage (1968) was followed by Silverstone (1975a) in identifying dark pigmentation of the flesh as a synapomorphy of Dendrobates and Phyllobates. We paid considerable attention to this character, thanks largely to the numerous large series of skinned specimens collected by C. W. Myers and colleagues and deposited (cataloged and uncataloged) at AMNH. The variation we observed is much more complicated than the simple pigmented/unpigmented of Savage and Silverstone. Pigmentation occurs in diffuse, irregular patches and varies continuously in intensity from being entirely lacking to a few black specks or intense dark gray or black. We were unable to delimit transformation series objectively, and therefore excluded pigmentation of the flesh from this study.

Genotypic Character Sampling

In light of the vastly different levels of diversity included in this study (from within localities to among families), we sought to sample genes of differing degrees of variability. We targeted the mitochondrial H-strand transcription unit 1 (H1), which includes 12S ribosomal, tRNA^val, and 16S ribosomal sequence, yielding approximately 2,400 bp generated in 5–7 overlapping fragments. We also targeted a 385-bp fragment of cytochrome b and a 658-bp fragment of cytochrome oxidase c subunit I (COI). In addition to those five mitochondrial genes, we targeted the nuclear protein coding genes histone H3 (328 bp), rhodopsin (316 bp), tyrosinase (532 bp), recombination activating gene 1 (RAG1, 435 bp), and seventh in absentia (SIA, 397 bp), and the nuclear 28S ribosomal gene (ca. 700 bp), giving a total of approximately 6,100 bp of nuclear and mitochondrial DNA. Primers used in PCR amplification and cycle sequencing reactions (and their citations) are given in table 1. Included in this study is a novel primer pair (RAG1 TG1F and TG1R) designed to amplify the RAG1 product using the web-based program Primer3 (Rozen and Skaletsky, 2000), available at  http://frodo.wi.mit.edu/cgi-bin/primer3/primer3_www.cgi. As discussed below, the amount of sequence data analyzed per terminal varied (fig. 21), ranging from 426 bp (subpunctatus obtained from GenBank) to 6,245 bp (chlorocraspedus 385), with a mean of 3,740 bp per terminal.

Table 1

Figure 21

Number of DNA base-pairs analyzed per terminal.

For specific terminal data see appendices 4 and 5.

As noted above, we targeted loci that varied to differing degrees to test hypotheses of relationships at all levels, and we included multiple samples from the same and different localities of the same species in an effort to address problems in alpha taxonomy. We attempted to sequence all loci for at least one sample from every locality, but we did not sequence nuclear loci for all samples. We chose this strategy because early work on this project showed the nuclear loci to be generally less variable and usually identical in all samples from a given locality.

We augmented our own data with sequences from GenBank, listed in appendix 4, in order to include otherwise unsampled ingroup species and additional localities for taxonomically problematic species, that is, the dataset analyzed includes all species on GenBank as well as samples of some species from multiple localities. Nevertheless, we did not include all GenBank data. First, we only included loci for which we also generated data. For example, we did not include Widmer et al.'s (2000) cytochrome b data because their fragment did not overlap with ours. Second, although we included multiple samples to address taxonomic problems, we did not include all samples from population-level studies (e.g., Symula et al., 2003), as such dense intraspecific sampling was not required and would have impeded analysis by unnecessarily expanding the dataset.

Laboratory Protocols

Whole cellular DNA was extracted from frozen and ethanol-preserved tissues (liver or muscle) using the Qiagen DNeasy kit following the manufacturer's guidelines. PCR amplification was carried out in 25-µl reactions using puRe Taq Ready-To-Go Beads (Amersham Biosciences). The standard PCR program consisted of an initial denaturing step of 3 min at 94°C, 35–40 cycles of 1 min at 94°C, 1 min at 45–62°C, and 1–1.25 min at 72°C, followed by a final extension step of 6 min at 72°C. PCR-amplified products were cleaned and desalted using either the ARRAYIT kit (TeleChem International) on a Beckman Coulter Biomek 2000 robot or AMPure (Agencourt Biosciences Corporation). Cycle-sequencing using BigDye Terminators v. 3.0 (Applied Biosystems) was run in 8-µl reactions, and products were cleaned and desalted by standard isopropanol-ethanol precipitation or using cleanSEQ (Agencourt Biosciences Corporation). Sequencing was done on either an ABI 3700 or ABI 3730XL automated DNA sequencer. Contigs (sets of overlapping sequences) were assembled and edited using Sequencher (Gene Codes).

Molecular Sequence Formatting

To enable integration of incomplete sequence fragments (particularly those from GenBank; see Taxon Sampling Strategy and Character Sampling Strategy, above), accelerate cladogram diagnosis, and reduce memory requirements under Iterative Pass Optimization, we broke complete sequences into contiguous fragments. (This also improves the performance of POY's implementation of the parsimony ratchet; see Heuristic Tree Searching, below.) We did so sparingly, however, as these breaks constrain homology assessment by prohibiting nucleotide comparisons across fragments, that is, it is assumed that no nucleotides from fragment X are homologous with any nucleotides from fragment Y. As the number of breaks increases, so too does the risk of overly constraining the analysis and failing to discover the globally optimal solution.

We therefore inserted as few breaks as were necessary to maximize the amount of sequence data included, minimize the introduction of nucleotides of unknown identity into the sequences (see Character Sampling Strategy, above), and attain maximum length fragments of around 500 bases (see table 2). Breaks were placed exclusively in highly conserved regions (many of which correspond to commonly used PCR primers), as recovery of such highly invariable regions is generally alignment-method independent (unpublished data) and therefore does not prevent discovery of global optima. These highly conserved regions were identified via preliminary ClustalX (Thompson et al., 1997) alignments under default parameters and examination using BioEdit (Hall, 1999). Except for their usefulness in placing fragments derived from different PCR primers and detecting errors, these preliminary alignments were used solely for the purpose of identifying conserved regions; they did not otherwise inform or constrain our phylogenetic analysis. Once appropriate conserved regions were identified, fragments were separated by inserting pound signs (#) at break points. Thus, the multiple fragments of the mitochondrial H1 unit remain in the same file and order, for example.

Table 2

Total Evidence Analysis

We did not discriminate between classes of evidence in the phylogenetic analyses. To allow the molecular data to have bearing on problems of species taxonomy, we treated every specimen sequenced as a separate terminal, that is, we did not fuse putatively conspecific specimens into a single polymorphic terminal, which would prevent the molecular data from addressing alpha taxonomic problems and require that all decisions on species identity be made prior to phylogenetic analysis. Loci not sequenced for particular terminals—either because the primers failed or because other syntopic conspecifics were sequenced instead—were treated as missing for those terminals.

There are three possible methods of incorporating phenotypic evidence for specimens judged to be conspecific but coded separately for genotypic data.

The latter two options offer more defensible approaches. The second method has the advantage of minimizing ambiguous optimizations due to missing entries, which may be crucial in examining the evolution of some of the most interesting phenotypic characters (e.g., behaviors). The third approach appears to have the advantage of maximizing the severity of the molecular test of species identity, that is, terminals judged conspecific on phenotypic grounds could not be held together on those grounds alone in phylogenetic analysis. Although we see some validity to this argument, given the relative sizes of the phenotypic and genotypic partitions (ca. 170 characters vs. ca. 6,100 unaligned base pairs), we see no a priori reason to expect morphology to overwhelm the DNA sequence data. Moreover, the identical entries that would potentially hold those specimens together in the face of molecular evidence are, in fact, apomorphies for the species, and total evidence analysis demands that they be considered as such. That is, the goal in total evidence analysis is not to test the results of one data partition against another, but to allow all evidence to interact simultaneously to identify the hypothesis that best explains all the evidence.

As such, we opted to duplicate the morphological entries coded for the species, that is, each conspecific terminal was given identical entries in the phenotypic matrix. Phenotypic characters not expressed in the sequenced semaphoront (e.g., testis color in female specimens) were scored and species-level phenotypic polymorphisms were coded as ambiguities. A caveat is that we did not associate GenBank sequences with phenotypic data unless we lacked our own genotypic data for the taxon (e.g., sauli), and then only for one sample if more than one was on GenBank (e.g., we associated the phenotypic entries for kingsburyi with AY364549 only).

With a single exception, the reported ingroup characters were scored for single species (see Outgroup Sampling, above, for coding of outgroup species). The exception was alagoanus, for which the morphological characters were scored from specimens of olfersioides. The two species were named on the basis of few differences between small samples, and study of external morphology of larger samples from a greater number of localities suggests they may be conspecific (V.K. Verdade, personal commun.), although additional data from color in life, vocalizations, and DNA sequences have yet to be examined. DNA sequences were generated for alagoanus, but whole specimens were not available for examination. Tissue samples were unavailable for olfersioides (which has not been observed in Rio de Janeiro since approximately 1980 and may be extinct; C.F.B. Haddad, personal obs.), but numerous museum specimens were available for morphological study. As such, we combined the data from these two species under the asumption that they represent a unique clade; we refer to the resulting terminal as alagoanus because most of the evidence was scored from that species.

Simultaneous phylogenetic analysis was performed using the program POY (Wheeler et al., 1996–2003) version 3.0.11a and the MPI version 3.0.12a-1109195780.71. All POY runs were parallelized across 95 processors of the AMNH 256-processor Pentium 4 Xeon 2.8 GHz cluster or 16–32 processors of the 560-processor mixed 512 mHz and 1 GHz cluster. Results were visualized using Winclada (Nixon, 1999–2002), and we verified POY results and analyzed implied alignments using NONA (Goloboff, 1999) spawned from Winclada. Although character weighting was used heuristically in tree searching (see below), evidence was weighted equally to assess tree optimality.

Heuristic Character Optimization

Numerous algorithms of varying exhaustiveness have been proposed to optimize unaligned DNA sequences on a given topology. Our search strategy employed three Direct Optimization algorithms; in order of increasing exhaustiveness and execution time, these were Fixed-States Optimization (Wheeler, 1999), Optimization Alignment (Wheeler, 1996), and Iterative Pass Optimization (Wheeler, 2003b).

Although Fixed-States Optimization was proposed as a novel means of conceptualizing DNA sequence homology (Wheeler, 1999), we employed it here simply as a heuristic shortcut. Because Fixed-States is so much faster than the Optimization Alignment algorithm, it allowed more thorough sampling of the universe of trees for subsequent refinement under more exhaustive optimization algorithms. Our general strategy was therefore to examine a large pool of initial candidate trees quickly under Fixed-States and submit those trees as starting points for further analysis under Optimization Alignment. Because the potential exists for the globally optimal tree (or trees that would lead to the global optimum when swapped under a more exhaustive optimization algorithm) to be rejected from the pool of candidates under the heuristic algorithm, we also generated a smaller pool of candidate trees under Optimization Alignment. The resulting optimal and near-optimal candidate trees were then submitted to final evaluation and refinement under Iterative Pass optimization using iterativelowmem to reduce memory requirements. (For details on tree-searching algorithms, see Heuristic Tree Searching, below.)

We did not employ the exact command during most searches, although we did use it in the final stages of analysis to allow accurate matrix-based length verification (Frost et al., 2001). To verify lengths reported in POY, we output the implied alignment (Wheeler, 2003a) and binary version of the optimal topology in Hennig86 format with phastwincladfile and opened the resulting file in Winclada (Nixon, 1999–2002). Because each topology may imply a different optimal alignment, when multiple optimal topologies were obtained we examined them separately by inputting each as a separate file using topofile. Examination of the implied alignments, whether formatted as Hennig files or as standard alignments (impliedalignment), grants another opportunity to detect errors in formatting or sequencing.

Heuristic Tree Searching

Efficient search strategies for large datasets are, to a certain degree, dataset dependent (Goloboff, 1999), and, as discussed above, common indicators of sufficiency are impractical given current technological limitations. Therefore, rather than apply a simple, predefined search strategy (e.g., 100 random addition Wagner builds + TBR branch swapping), we employed a variety of tree searching algorithms, spending more time on those that proved most efficient. Optimal trees from different searches were pooled for tree-fusing and TBR swapping, all of which was followed by refinement under Iterative Pass Optimization (Wheeler, 2003b). The search strategy is summarized in table 3.

Table 3

Random addition sequence Wagner builds (RAS) were performed holding one or three trees. We conducted searches without slop or checkslop, both of which increase the pool of trees examined by swapping suboptimal trees found during the search; although these steps can be highly effective, initial trials showed they were too time consumptive for the present dataset.

The parsimony ratchet (Nixon, 1999) was proposed for analysis of fixed matrices. Given that under dynamic homology there are no prespecified column vectors to be reweighted, the original approach had to be modified. In the current version of POY, the ratchet is programmed to reweight randomly selected DNA fragments. The present dataset was broken into 31 fragments (see table 2), so ratchetpercent 15 randomly reweighted five fragments, regardless of their length or relative position. We reweighted 15–35% of the fragments and applied weights of 2–35 times.

As a complementary approach, we also performed quick searches (few random addition sequence Wagner builds + SPR) under indel-transversion-transition costs of 3-1-1, 1-3-1, and 1-1-3 and included the resulting topologies in the pool of trees submitted to fusing and refinement under equal weights, following the general procedure of d'Haese (2003). Reweighting in this method is not done stochastically and therefore differs from both Nixon's (1999) original version and POY's implementation of the ratchet and technically is not a simulated annealing or Metropolis-Hastings-type strategy like the others; however, because it weights sets of transformations drawn from throughout the entire dataset, it is likely to capture different patterns in the data and may actually be a closer approximation to the original ratchet than POY's implementation. Both approaches are effective methods to escape local optima.

We also performed constrained searches by calculating the strict consensus of trees within an arbitrary number of steps of the present optimum, saving the topology as a treefile, constructing the group inclusion matrix (Farris, 1973) in the program Jack2Hen, and then employing constraint in the subsequent searches. To calculate the consensus we included trees within 100–150 steps of the current optimum, the goal being to collapse enough nodes for swapping to be effective, but few enough nodes for significant speedups in RAS + swapping to find optimal arrangements within the polytomous groups (see Goloboff, 1999: 420). This is effectively a manual approximation of Goloboff's (1999) consensus-based sectorial search procedure, the main difference being that we collapsed nodes based only on tree length and not relative fit difference (Goloboff, 1999; Goloboff and Farris, 2001).

Using constraint files generated in the same way, we also input the current optimum as a starting point for fusing and/or ratcheting. This strategy avoids spending time on RAS builds of the unconstrained parts of the tree (which tend to be highly suboptimal) and seeks to escape local optima in the same way as unconstrained ratcheting, discussed above; however, there is a trade-off in that the arrangements may be less diverse but are likely to be, on average, closer to optimum, than those examined through RAS.

As a further manual approximation of sectorial searches, we analyzed subsets of taxa separately by defining reduced datasets with terminals files that listed only the targeted terminals. Rigorous searches (at least 100 RAS + TBR for each of the reduced datasets) of these reduced datasets were then performed, and the results were then used to specify starting topologies for additional searching of the complete dataset.

Static matrices may be thoroughly analyzed in a fraction of the time required to perform an equivalent analysis under dynamic homology. We therefore output implied alignments of current optima from POY and ran multiple replicates of RAS + 50 rounds of the parsimony ratchet using Winclada and NONA. Improvements were not always attained through this procedure, but when they were, we then input the optimal cladogram(s) from the static search as a starting point for further analysis in POY.

As a final attempt to discover more parsimonious solutions, we also rearranged branches of current optima manually. As a general search strategy this would obviously be highly problematic, if for no other reason than that it would bias analyses. However, we performed this step primarily to ensure that the “received wisdom” and other arrangements were evaluated explicitly in the analysis. The procedure was to open the current optimum in Winclada, target taxa whose placement was strongly incongruent with current taxonomy, and move them to their expected positions (or in polytomies, depending on the precision of the expectations). The resulting topologies were saved as treefiles that were read into POY as starting topologies for diagnosis and refinement (e.g., tree fusing). In this way we ensured that the more heterodox aspects of our results were not due to simply failing to evaluate the more orthodox alternatives during the automated searches.

Heuristic Data Exploration

To estimate support (sensu Grant and Kluge, 2003), we calculated Bremer (decay) values for all nodes present in the strict consensus of equally parsimonious solutions (Bremer, 1994). To accomplish this we output the implied alignment and optimal trees in Hennig86 format using phastwincladfile, converted it to NEXUS format in Winclada, and then generated a NEXUS inverse-constraints batch file in PRAP (Müller, 2004), which was analyzed in PAUP* 4.0b10 (Swofford, 1998–2002). Bremer analysis consisted of 1 RAS + 5 iterations of the parsimony ratchet (reweighting 25% of characters by 2) for each clade. More thorough analysis involving more rigorous tree searches of the unaligned data would undoubtedly lower the estimates; as is always the case with heuristic analysis, the Bremer values reported are an upper bound.

Species Identification

One of the goals of this study was to address problems in determining species identity. Through the course of the study species were identified on phenotypic grounds. Here we examine the bearing of evidence from DNA sequences and phylogenetic analysis on alpha taxonomic problems (see also Total Evidence Analysis, above).

As a means of identifying species limits, the results of phylogenetic analysis should be interpreted in light of several caveats: (1) Phylogenetic analysis presupposes that the genealogical relationships among the entities analyzed are phylogenetic (Davis and Nixon, 1992); as such, it will impose a hierarchy even on entities that are related tokogenetically, for example. In such cases, the branching structure would be an analytical artifact and finding that a species is or is not monophyletic would be irrelevant. (2) Species are historical individuals, and, as such, all parts of a given species need not form a clade (Skinner, 2004; see also Frost and Kluge, 1994). Incongruence between the history of different parts and the whole may be due to any number of natural phenomena, such as lineage sorting and partial/temporary introgression, none of which denies the historical individuality of the species. (3) Given a cladogram alone, there is no objective basis for identifying species limits, that is, there is no way to discriminate intra- from interspecific hierarchic structure without additional information. For example, dividing a pectinate cladogram of N terminals into 1 species, N − 1 species, and N species are all cladistically valid delimitations. As such, phylogenetic structure can only disconfirm hypotheses of species identity (but consider points 1 and 2); finding that the parts of a putative species form a clade does not deny that the clade may be composed of multiple species.

In spite of the above caveats, phylogenetic analysis is a valid (if fallible) species discovery operation (Frost et al., 1998). Conceptually, species are minimal historical individuals, meaning that species boundaries occur at the point where the properties of contemporary individuals dissolve (Kluge, 1990; Grant, 2002). Historical individuality may therefore be apprehended both from “below” by discovering the constituent parts that interact and “above” by individuating entities that are historically distinct. Incongruence between the results of complementary discovery operations (those directed from above and below, in this case) indicates heuristically that further study is warranted (Grant, 2002). Ultimately, species individuation requires diagnostic characters, and phylogenetic analysis facilitates their discovery.

To address the limits of problematic species, we considered (1) cladogram topology (cladistic distance), (2) branch lengths (patristic distance), and (3) uncorrected pairwise distance4 (uncorrected p, or number of base mismatches divided by total sequence length; no length variation was observed for this locus) of cytochrome b sequences within and between localities and/or closely related species. We focused on that sequence because (1) it is sufficiently variable and (2) it is almost completely represented in our dataset.

Our primary reason for including pairwise distances in this analysis is that they provide a rapid heuristic for species identification without conducting a complete phylogenetic analysis, in the same way that artificial dichotomous keys are efficient identification tools (Grant, 2002). We do not advocate using pairwise distances to delimit species. First, there is no justification for setting some arbitrary distance (e.g., 5%)—phenetic or otherwise—as “sufficient” for granting species status. Given variation in evolutionary rates and sampling density, it is expected that intraspecific variation may be greater in some species than interspecific variation among others. Indeed, the inability to distinguish between rate variation and artifacts due to taxon sampling (including extinction) casts doubt on all studies that base conclusions on degree of divergence or distance. What matters is the total evidence (including other loci, morphology, behavior, etc.) for the historical reality of the putative species and clades, for which character-state transformations must be identified to diagnose minimal historical individuals, not degree of similarity (pair- or otherwise). Second, as two-taxon statements, pairwise distances do not distinguish between symplesiomorphy and synapomorphy and therefore fail to explain the observed variation. Third, pairwise distance only discriminates among samples, that is, it is a relational concept and therefore cannot diagnose any particular entity (see Frost, 2000). Nevertheless, because they do not require extensive sampling or detailed analysis (phylogenetic or otherwise), pairwise comparisons are extremely fast and simple and therefore highly heuristic, and as such they are a useful starting point in examining species identity.

7–10. Expansion of Finger Discs (Fig. 25)

In the dendrobatid literature, expansion of finger discs is generally treated as one or at most two characters. Duellman and Simmons's (1988) standard diagnosis coded only the disc of finger III, and Dendrobates species descriptions often report the expansion of discs I and II–IV separately. However, there is no logical dependency between the discs of different digits, and the distribution of states in the matrix shows that the expansion of each digital disc is transformationally independent, and, as such, they are defensibly coded separately for analysis. A trend is that the disc of finger I is often (but not always) less expanded than those of the other fingers, but this does not violate the transformational independence of these characters.

We detected four discrete states in finger (and three in toe) disc expansion, shown schematically in figure 25. All dendrobatids have digital discs, so some degree of expansion is always detectable, although it may be extremely slight. This is exemplified by elachyhistus and pumilio, in which the disc of finger I appears unexpanded or at most weakly expanded (state 0). States 1 and 2 are found in most dendrobatids; state 3 is found in those species with greatly expanded discs (e.g., tinctorius). State 3 was only observed among fingers II–IV.

Figure 25

Characters 7–10 and 31–35, schematic illustration of the four states observed in the expansion of digital discs.

The digital shaft is indicated by the inner crosshatched area and the outer edges of the disc are indicated by the heavier outer line.

Polder (1973: 17) and Silverstone (1975a) claimed that some species of dendrobatids are sexually dimorphic in the expansion of the digital discs, with males possessing larger discs than females. Neither author provided quantitative data, however, and when Myers and Daly (1976b: 203) tested the claim quantitatively in histrionicus they found it to be unsupported. Although we detected (and coded) polymorphism in disc expansion in some species (including histrionicus), we concur with Myers and Daly (1976b) that it does not reflect differences between sexes. For example, in leucomelas the finger discs of male AMNH 137309 are larger than those of female AMNH 137310, but no more expanded than those of female AMNH 46051. We did not test the hypothesis that discs of males are statistically (i.e., on average) larger than those of females (Silverstone, 1975a: 8) because that question is unrelated to the problem of homologizing character-states and inferring transformation events (Grant and Kluge, 2003, 2004).

7. Finger Disc I: unexpanded  =  0; weakly expanded  =  1; moderately expanded  =  2. Additive.

8. Finger Disc II: unexpanded  =  0; weakly expanded  =  1; moderately expanded  =  2; greatly expanded  =  3. Additive.

9. Finger Disc III: unexpanded  =  0; weakly expanded  =  1; moderately expanded  =  2; greatly expanded  =  3. Additive.

10. Finger Disc IV: unexpanded  =  0; weakly expanded  =  1; moderately expanded  =  2; greatly expanded  =  3. Additive.

11–18. Finger Fringes (Fig. 26)

The occurrence and extent of lateral keels and/or fringes on fingers and toes has been cited in most alpha taxonomic studies of dendrobatids for the past several decades at least (e.g., Edwards, 1971). Duellman and Simmons (1988: 116) noted that “the development of fringes on the fingers is variable, so standard comparison is made with the second finger.” Nevertheless, as discussed above in reference to expansion of digital discs, because the fringes on each edge of each finger vary independently we coded them as separate characters.

Although lateral dermal expansions of the digits are commonly described in the dendrobatid literature, explicit delimitations of character-states are generally lacking, which has led to considerable confusion. They are generally referred to as either keels or fringes. As noted by Lynch and Duellman (1997: 33) for species of Eleutherodactylus, “there is a continuum from keels to fringes, and in some cases the distinction is arbitrary.” Although such arbitrariness is relatively harmless in descriptive taxonomic studies, the cumulative effect of arbitrary delimitations can be disastrous in phylogenetic analyses. Coloma (1995: 6–7) noted that fringes may be absent, poorly developed, or well developed. He further clarified that “[w]hen it was difficult to distinguish between a real fringe and a preservation artifact, I describe the dermal modification as a ‘keel’ ”, which, although explicit, actually engenders greater confusion because keels are generally considered to be real dermal modifications (e.g., Lynch and Duellman, 1997).

The strength of keeling (extent of dermal thickening) varies extensively, leading La Marca (1996 “1994”: 6) to differentiate between keels and fringes as “very low” and “conspicuous but not folding around the toes”, respectively. However, although we agree that these descriptors encompass the observed variation, and despite numerous dissections, we were unable to individuate character-states objectively. Any attempt to subdivide state 0 into multiple character-states must overcome two difficulties: (1) apparently continuous variation (as suggested by external examination and gross dissections) and (2) the fact that these dermal expansions are highly prone to postmortem modification, either due to desiccation (as indicated by Coloma, 1995) or simply as an artifact of preservation (and variation in preservation techniques). It is likely that the greater precision attained through histological study could overcome both of these problems, but that was beyond the scope of the present study. For the purpose of phylogenetic analysis, we individuated only two character-states: fringes absent (state 0) and fringes present (state 1).

In state 0, the extent of lateral dermal expansion varies from absent (i.e., the side of the digit is smoothly rounded and there is no detectable dermal thickening along the lateral margin) to conspicuously keeled. In state 1, the skin that extends from the dorsal surface extends ventrad and appears to fold over the side of the digit, which we refer to as a fringe (see fig. 26). In ventral (palmar) view the folding over can be seen to create a deep longitudinal crease or groove. We have not detected evidence that the folding over varies as an artifact of preservation, providing a basis to distinguish this state objectively. This state is approximately equivalent to La Marca's (1996 “1994”: 6) “flaps”, which he diagnosed as “folding around the toes”. The strength of fringes varies from a weak flap (e.g., toes of degranvillei) to a strong flap that wraps around much of the ventral surface of the digit (the latter condition found only on toes; see below), but we were unable to delimit distinct states.

Figure 26

Characters 11–18, finger fringes.

In Megaelosia goeldii (AMNH 103949) fringes are present on pre- and postaxial edges of all fingers.

Webbing between the fingers does not occur in any dendrobatid we examined. Donoso-Barros (1965 “1964”: 486) described “rudimentary web between 2^nd and 3^rd fingers” in riveroi, but finger webbing was not reported by La Marca (1996 “1994”) and is absent in the specimens we examined. Similarly, Coloma (1995) described and illustrated webbing between the fingers in an undescribed species (as Colostethus chocoensis; see Grant et al., 1997: 24, footnote 13), and Grant et al. (1997: 25) mentioned the possible occurrence of webbing on the hands of atopoglossus. However, closer examination of the same specimens of “Colostethus chocoensis” and atopoglossus revealed that the apparent webbing is due to flattening of the loose skin of the hand, as considered by Grant et al. (1997). Lynch (1971: 30) reported similar mistaken reports among “leptodactyloids”.

11. Finger Fringe: I preaxial: absent  =  0; present  =  1.

12. Finger Fringe: I postaxial: absent  =  0; present  =  1.

13. Finger Fringe: II preaxial: absent  =  0; present  =  1.

14. Finger Fringe: II postaxial: absent  =  0; present  =  1.

15. Finger Fringe: III preaxial: absent  =  0; present  =  1.

16. Finger Fringe: III postaxial: absent  =  0; present  =  1.

17. Finger Fringe: IV preaxial: absent  =  0; present  =  1.

18. Finger Fringe: IV postaxial: absent  =  0; present  =  1.

19. Metacarpal Ridge (fig. 27): absent  =  0; weak  =  1.

Figure 27

Character 19, metacarpal ridge.

State 1, present (abditaurantius, ICN 9853).

The metacarpal ridge or fold is a dermal thickening running from the postaxial edge of the base of finger IV along the outer edge of the palm toward the palmar tubercle. In most species an edge is formed where the relatively flattened palm meets the rounded side of the hand, but we did not consider this to be a metacarpal ridge unless dermal thickening could be detected, either by gross inspection or by making a transverse incision. Although there is some variation among species in the degree of expression of the metacarpal ridge, it was minor and we were unable to delimit discrete states. As with other dermal characters, the metacarpal ridge may be exaggerated or lost as an artifact of preservation.

20–21. Finger III Swelling

Reproductively active males of numerous dendrobatids present swollen third fingers, a condition that is unknown in nondendrobatids. The “swelling” is due to the occurrence of extensive glandular tissue, the large granules often being evident in gross dissection or even through the skin. In light of the important role this character has played in recent discussions of dendrobatid systematics (e.g., Myers et al., 1991; but see Myers, 1991), we review its usage here.

Although a number of species possessing a distinctly enlarged third finger in males had been described previously (e.g., trilineatus, the holotype of which is a male), the first worker to describe and illustrate the swollen third finger was Dunn (1924: 7–8) for nubicola. Descriptions of “digital dilatations” or “enlargements” in the earlier literature referred to the expanded digital disc apparatus (e.g., Cope, 1867: 130, 1887: 55). When Dunn (1931) named flotator, he grouped it with nubicola based in part on the shared occurrence of the swollen third finger in males. Dunn (1933) noted that males of panamensis possess a swollen third finger, but he did not attribute any phylogenetic significance to the observation.

Over the 50 years following Dunn's first report of the swollen third finger in males, the state of the third finger was mentioned sporadically in diagnoses and descriptions (e.g., among papers that deal with species with swollen third fingers in males, it was mentioned by Dunn, 1931, 1957; Funkhouser, 1956; Savage, 1968; Cochran and Goin, 1970: 60 [only for their Phyllobates inguinalis, as “flanges” on the third finger of males]; Edwards, 1971; and Silverstone, 1971, 1976; but not by Cochran and Goin, 1964; Cochran, 1966; or Silverstone, 1975b), but was not illustrated again until 1974, when Edwards provided a schematic representation in his unpublished (but widely distributed; see Myers et al., 1991: 30, footnote 14) dissertation (Edwards, 1974a).

The character has been mentioned fairly consistently since 1974, but miscoding is common, probably due in part at least to the inadequacy of Dunn's (1924) and Edwards's (1974a) illustrations, both of which depicted (1) roughly equal expansion on both sides (preaxial and postaxial) of the digit and (2) distally exaggerated swelling, neither of which is found in all (or even most) of the species with swollen third fingers. Similarly, although accurate for a few species, Duellman and Simmons's (1988: 117) description that “the basal segment of the third finger is distinctly swollen in males” does not apply to most of the species with clearly swollen third fingers in males (and none of the species they addressed in their paper). The expansion of the third finger can be much more subtle than Dunn's (1924) and Edwards's (1974a) illustrations suggest, and significant variation occurs in the extent and location of the swelling.

Silverstone (1976: 33) noted in his account of tricolor that not all adult males of a given sample may express the swollen third finger, a finding that was corroborated more generally by Myers et al. (1991), who speculated that expression is likely under hormonal control. This and additional difficulties related to the coding of this character were discussed by Myers et al. (1991, 1998, see especially fig. 4), Myers (1991), Myers and Donnelly (1997), and Grant and Rodríguez (2001).

20. Finger III Swelling in Adult Males: absent  =  0; present  =  1.

This character was scored for awa from Coloma (1995) because no adult males were included in the series we examined.

21. Morphology of Swollen Third Finger in Males (fig. 28): pre- and postaxial swelling  =  0; weak preaxial swelling  =  1; strong preaxial swelling  =  2; swelling extending from wrist, mainly preaxial on digit  =  3. Nonadditive.

Figure 28

Character 21, morphology of swollen third finger in males.

A: State 0, pre- and postaxial swelling (mertensi, ICN 43698). B: State 1, weak preaxial swelling (insperatus, KU 149676). C: State 2, strong preaxial swelling (nubicola, AMNH 114574). D: State 3, swelling extending from wrist, mainly preaxial on digit (baeobatrachus, AMNH 140650).

22. Carpal Pad (fig. 29): absent  =  0; present  =  1.

Figure 29

Character 22, male supracarpal pad (undulatus, AMNH 159134).

Myers and Donnelly (2001) discovered the carpal pad in undulatus. It consists of a conspicuous nonglandular thickening and heavy melanosis of the skin above the wrist of males. We did not find this character to be present in any other species, but we include it here in anticipation of future discoveries.

23. Male Excrescences on Thumb: absent  =  0; present  =  1.

Although nuptial excrescences are common among outgroup taxa, most dendrobatids lack nuptial excrescences (state 0), the sole exception being oblitterata, which was reported as possessing nuptial excrescences (state 1) by La Marca (1995: 66).

We coded Telmatobius jahuira for this character following Lavilla and Ergueta (1995).

24. Morphology of Male Excrescences on Thumb: large, cornified spines  =  0; small, uncornified spines  =  1; nonspinous asperities  =  2. Additive.

Lavilla and Ergueta (1995: 49, translated freely from the Spanish) described the nuptial excrescences of Telmatobius jahuira as “few cornified spines separated by large, unkeratinized spaces”.

25. Female Excrescences on Thumb: absent  =  0; present (large, cornified spines)  =  1.

See Noble (1931: 122, 126) for illustrations and comments on the large, cornified spines on the thumb of females of species of Crossodactylus.

26. Thenar Tubercle (fig. 30): absent or small, inconspicuous swelling  =  0; large, conspicuous, well-defined tubercle  =  1.

Figure 30

Character 26, thenar tubercle.

A, B: State 0, absent or small, inconspicuous swelling (pumilio, AMNH 102262). In this specimen, the thenar tubercle appears absent in both palmar aspect and profile. C, D: Another specimen of the same species (pumilio, AMNH 102263). In this specimen, the thenar tubercle is inconspicuous but clearly seen in profile (also scored as state 0). E, F: State 1, large, conspicuous, protuberant tubercle (nubicola, AMNH 114574).

Most dendrobatids have a conspicuous, protuberant, elliptical thenar (inner metacarpal) tubercle (state 1). Silverstone (1975a) noted that the thenar tubercle is inconspicuous or absent in leucomelas (state 0). Likewise, Caldwell and Myers (1990) illustrated and discussed the absence of the thenar tubercle in castaneoticus and quinquevittatus, which they interpreted as a synapomorphy uniting these two species in an exclusive clade (they did not make comparisons with leucomelas). Other species also exhibit the same morphology (e.g., pumilio).

Caldwell and Myers (1990: 16) noted some variation in the expression of the thenar tubercle in quinquevittatus; in some specimens it is altogether undetectable, whereas in others “possible vestiges of it” were detected as “possibly represented by slight epidermal thickening”. Our observations concur with theirs. Given the propensity for such subtle dermal features to be lost as an artifact of preservation (due to skin sloughing, desiccation, or inadequate fixation, among other causes), we combined the apparent complete absence and inconspicuous epidermal thickening as state 0. Expression of the thenar tubercle is not dependent on overall body size; leucomelas is quite large, and the thenar tubercles of the small species nubicola and stepheni (roughly the same snout-vent length as pumilio) are large and well defined.

27. Black Arm Gland in Adult Males: absent  =  0; present  =  1.

This character was identified, discussed, and illustrated photographically by Grant and Castro-Herrera (1998; see also Grant and Ardila-Robayo, 2002) and used to delimit the ramosi group. It remains unclear if this patch of black, thickened tissue on the ventral and medial surfaces of the distal extreme of the upper arm and often extending onto the inner surface of the lower arm is glandular, but its absence in females and juveniles and exaggeration in sexually active males suggests it is involved in amplexus and probably under hormonal control. In addition to the species listed by Grant and Ardila-Robayo (2002), this character is also present in anthracinus and the undescribed species referred to herein as “Ibagué”.

28. Tarsal Keel: absent  =  0; present  =  1.

The tarsal keel is a dermal structure that extends obliquely along the plantar surface of the tarsus. Regardless of its point of origin (see Character 29), it always terminates medially, not on the margin of the tarsus (see Character 30). Silverstone (1975a, 1976) used variation in this structure to diagnose species groups in Dendrobates and Phyllobates, and Lynch (1982) cited the loss of the tarsal keel in edwardsi and ruizi to delimit the edwardsi group of Colostethus.

Silverstone (1975a: 8) treated the “tarsal fold” and “tarsal tubercle (at the proximal end of the tarsal fold)” as separate characters. He considered the tarsal fold to be present in all Dendrobates and the tarsal tubercle to be both present and absent in Dendrobates. However, the tarsal fold and tarsal tubercle form a single structure, the tubercle simply being an increased thickening of the proximal portion of the keel. This is especially clear in many nonaposematic dendrobatids (which were not the focus of Silverstone's work) in which the proximal end of the keel is conspicuously enlarged and may be described as tubercle-like, but is sharply curved to run across the tarsus and does not conform to the rounded structures usually referred to as tubercles.

29. Morphology of Tarsal Keel (fig. 31): straight or very weakly curved, extending proximolaterad from preaxial edge of inner metatarsal tubercle  =  0; tubercle-like (i.e., enlarged) and strongly curved at proximal end, extending from metatarsal tubercle  =  1; short, tubercle-like, curved or directed transversely across tarsus, not extending from metatarsal tubercle  =  2; weak, short dermal thickening, not extending from metatarsal tubercle  =  3. Additive.

Figure 31

Character 29, morphology of tarsal keel.

A: State 0, straight or very weakly curved, extending proximolaterad from preaxial edge of inner metatarsal tubercle (imbricolus, AMNH 102082). B: State 1, tuberclelike and strongly curved at proximal end, extending from metatarsal tubercle (degranvillei, AMNH 90876). C: State 2, short, tuberclelike, curved or directed transversely across tarsus, not extending from metatarsal tubercle (“Neblina species”, AMNH 118657). D: State 3, weak, short dermal thickening, not extending from metatarsal tubercle (pumilio, AMNH 102261). The hind limb is rotated to view the inconspicuous tarsal keel in profile.

30. Tarsal Fringe (fig. 32): absent  =  0; present  =  1.

Figure 32

Character 30, tarsal fringe.

State 1, present (Megaelosia goeldii, AMNH 103950).

The tarsal fringe consists of a conspicuous dermal flap that runs along the entire length of the preaxial edge of the tarsus; it is continuous with the fringe on toe I. The tarsal fringe differs from the tarsal keel (characters 28, 29) in that the latter extends proximolaterad across the tarsus to terminate at roughly the middle of the tarsus on the plantar surface, whereas the former never crosses the tarsus and extends along its entire length.

31–35. Expansion of Toe Discs

Like finger discs, dendrobatid literature generally treats the degree of expansion of toe discs as a single character. However, as discussed above under finger discs, toe discs vary independently of one another and are defensibly treated as separate characters. Toe discs exhibit three of the four character-states found in fingers; the greatest expansion found in finger discs (finger disc state 3) does not occur in toe discs. (Character-states are figured schematically in fig. 25, above.)

31. Toe Disc I: unexpanded  =  0; weakly expanded  =  1; moderately expanded  =  2. Additive.

32. Toe Disc II: unexpanded  =  0; weakly expanded  =  1; moderately expanded  =  2. Additive.

33. Toe Disc III: unexpanded  =  0; weakly expanded  =  1; moderately expanded  =  2. Additive.

34. Toe Disc IV: unexpanded  =  0; weakly expanded  =  1; moderately expanded  =  2. Additive.

35. Toe Disc V: unexpanded  =  0; weakly expanded  =  1; moderately expanded  =  2. Additive.

36–45. Toe Webbing

Webbing has been used consistently in dendrobatid systematics since Noble (1923, 1926) diagnosed Phyllobates from Hyloxalus on the basis of reduced webbing. Although webbing can be argued to form a single, integrated functional unit (as can the entire organism), functional independence is at most secondary to historical independence in phylogenetic inference (Grant and Kluge, 2004), and there is ample evidence that the extent of webbing along each edge of each digit varies independently. Coding follows the nomenclature proposed by Savage and Heyer (1967) and subsequently modified by Myers and Duellman (1982), which quantifies webbing in terms of the number of free phalanges, assessed in relation to subarticular tubercles (e.g., in Character 40, state 6, the two distal phalanges are free of webbing). We consider toe fringes (defined as for fingers, above) to be homologous with webs. We do not consider lateral fringes that meet between the toes to constitute a web unless it is expanded relative to lateral fringes, that is, if the continuous lateral fringes are broader at the base than along the sides of the digits, we construe this as being a web.

Among the sampled outgroup taxa, McDiarmid (1971: 33) noted that the interdigital webbing of Atelopus and Dendrophryniscus “is not a membrane, as defined by Peters (1964) but rather a thickened integumentary connection between digits, similar to the webbing encountered in many of the more terrestrial anurans, such as toads of the genus Bufo.” This suggests that the interdigital webbing of these species may not be homologous with that of other anurans. Nevertheless, although the distinction is clear in Dendrophryniscus minutus, it is less so in the sampled species of Atelopus, and we have therefore treated webbing as a single transformation series and allowed character congruence to be the ultimate arbiter (although much more extensive sampling of relevant taxa will be required to fully resolve the question).

36. Webbing: Toe I Preaxial: absent  =  0; fringe  =  1.

37. Webbing: Toe I Postaxial: absent  =  0; fringe  =  1; 2  =  2; 1.5  =  3; 1  =  4; 0  =  5. Additive.

Coloma (1995: 51) reported basal webbing (I2–3.5II) for talamancae and toachi, but there is no trace of webbing in the specimens we examined in this study.

38. Webbing: Toe II Preaxial: absent  =  0; 2.5  =  1; 2  =  2; 1  =  3; 0  =  4. Additive.

Coloma (1995: 51) reported basal webbing (I2–3.5II) for talamancae and toachi, but there is no trace of webbing in the specimens we examined.

39. Webbing: Toe II Postaxial: absent  =  0; 2 (without fringe)  =  1; 2 (with fringe)  =  2; 1.5  =  3; 1  =  4; 0  =  5. Additive.

40. Webbing: Toe III Preaxial: absent  =  0; fringe  =  1; 3.5 (without fringe)  =  2; 3.5 (with fringe)  =  3; 3  =  4; 2.5  =  5; 2  =  6; 1.5  =  7; 1  =  8. Additive.

Coloma (1995: 51) reported more extensive webbing (equivalent to state 4) for talamancae than we observed (state 2).

41. Webbing: Toe III Postaxial: absent  =  0; 3 without fringe  =  1; 3 with fringe  =  2; 2.5  =  3; 2  =  4; 1.5  =  5; 1  =  6. Additive.

42. Webbing: Toe IV Preaxial: absent  =  0; 4 without fringe  =  1; 4 with fringe  =  2; 3.5  =  3; 3  =  4; 2.5  =  5; 2  =  6; 1  =  7. Additive.

43. Webbing: Toe IV Postaxial: absent  =  0; fringe  =  1; 4  =  2; 3.5  =  3; 3  =  4; 2.5  =  5; 2  =  6; 1  =  7. Additive.

Coloma (1995: 51) reported basal webbing (IV4.5–3V) in talamancae, but there is no trace of webbing in the specimens we examined.

44. Webbing: Toe V Preaxial: absent  =  0; fringe  =  1; 2.5 (with fringe)  =  2; 2  =  3; 1.5  =  4; 1  =  5. Additive.

45. Webbing: Toe V Postaxial: absent  =  0; fringe  =  1.

This character was coded for insulatus, pulcherrimus, and sylvaticus Barbour and Noble from Duellman (2004), who reported it as absent in them all.

46. Metatarsal Fold (fig. 33): absent  =  0; weak  =  1; strong  =  2. Additive.

Figure 33

Character 46, metatarsal fold.

A: State 1, weak (“Neblina species”, AMNH 118657). B: State 2, strong (degranvillei, AMNH 90876).

The metatarsal fold is a dermal thickening running from the postaxial edge of the base of toe V (often coextensive with the fringe, if present) along the outer edge of the sole toward the outer metatarsal tubercle. In most species an edge is formed where the relatively flattened sole meets the rounded side of the foot, but we did not consider this to be a metatarsal ridge or fold unless actual dermal thickening could be detected, either by gross inspection or by dissection. A weak metatarsal fold (state 1) is a ridge; strong dermal folds (state 2) are often folded over or angled relative to the surface of the sole.

47. Cloacal Tubercles: absent  =  0; present  =  1.

Grant et al. (1997) identified and figured this pair of tubercles adjacent to the cloaca near the base of the thighs. They also discussed difficulties in scoring this character due to postmortem artifacts.

48–66. External Coloration

Much of the diversity of dendrobatids involves variation in external color and color pattern. Among species referred to Colostethus, for example, variation in the pattern of lateral stripes and ventral color serves as one of the main tools for diagnosis. However, color and color pattern are perhaps the most confounding–and therefore undersampled in this study–sources of variation. Several aposematic dendrobatids (e.g., pumilio, histrionicus, and tinctorius) are renowned for their astonishing intra- and interpopulational variation in color and color pattern, and the difficulties posed by this immense and often continuous and overlapping variation can be immediately appreciated by glancing at a few pages of Myers et al.'s (1976b) account of histrionicus. Practically speaking, the three main difficulties are (1) detection of objective boundaries between different characters and character-states, (2) requirement of many states per character, and (3) distinguishing between color and color pattern. We made every effort to incorporate as much of the variation as possible, but much of it was overwhelming. Also, for ease of coding (especially preserved specimens) we focused more on color pattern than color, but by doing so we undoubtedly conflated characters and character-states. For example, we scored both auratus and reticulatus as having the thighs pale with dark spots, even though the thighs are different colors. Future studies will undoubtedly advance considerably beyond the current project by scoring more of this diversity of color and color pattern.

48. Iridescent Orange or Golden Spot at Dorsal Limb Insertions: absent  =  0; present  =  1.

Note that the photo of quinquevittatus in Caldwell and Myers (1990: 11) shows that this character is not redundant with or nonindependent of the thigh coloration characters.

49. Pale Paracloacal Mark (fig. 34): absent  =  0; present  =  1.

Figure 34

Character 49, pale paracloacal mark.

State 1, present (degranvillei, AMNH 90880).

This is a pale, elongate mark at the base of the thigh. The shape of the spot varies from a straight vertical line to a sickle extending as a pale longitudinal stripe along the posterior surface of the thigh. The paracloacal mark originates adjacent to the vent at the base of the thigh, not in the groin or on the top the thigh (as does the pale mark in femoralis, for example; see character 50).

50. Thigh Dorsal Color Pattern (fig. 35): pale with dark spots (forming reticulum when spots are close together)  =  0; solid dark  =  1; dark with pale spots/bands  =  2; solid pale  =  3; brown with dark brown bands/blotches  =  4; dark with pale longitudinal stripe  =  5. Nonadditive.

Figure 35

Character 50, dorsal thigh color pattern.

A: State 0, pale with dark spots (quinquivittatus, AMNH 124069). B: State 1, solid dark (petersi, AMNH 111000). Note that the pale spot is confined to the inguinal regions and does not extend onto the dorsal surface of the thigh. C: State 2, dark with pale spots/bands (aurotaenia, AMNH live exhibit). D: State 3, solid pale (terribilis, AMNH live exhibit). E: State 4, brown with dark brown bands/blotches (inguinalis, LACM 42409). F: State 5, dark with pale longitudinal stripe (flavopictus, AMNH 88642).

51. Discrete Pale Proximoventral Calf Spot (fig. 36): absent  =  0; present  =  1.

Figure 36

Character 51, discrete pale proximoventral calf spot.

State 1, present (imbricolus, AMNH 102082).

Silverstone (1975a, 1975b) used the absence (state 0) and presence (state 1) of a discrete, pale spot on the proximal portion of the concealed surface of the shank to diagnose species and species groups. In life it is a bright flash mark. A number of species (e.g., fraterdanieli) have bright flash coloration on the concealed surface of the shank, but it does not form a discrete spot and we therefore follow Silverstone in scoring this character as absent for those species.

52–57. Pale Lateral Stripes

Edwards (1974a) used the combinations of pale lateral stripes (or lines) to diagnose species of Colostethus, identifying dorsolateral, oblique lateral, and ventrolateral stripes. Previous workers (e.g., Savage, 1968) had drawn attention to these characteristics as well, but Edwards standardized the distinction between the three stripes and has been followed by most authors. Nevertheless, caution must be employed when consulting the literature, as terminology varies. For example, what is referred to here as the oblique lateral stripe was referred to as a dorsolateral stripe by Edwards (1971) and Haddad and Martins (1994), and consistently as the inguinal stripe by La Marca (e.g., 1985, 1996 “1994”, 1998 “1996”; see also Myers and Donnelly, 2001). Duellman and Simmons (1988) discussed these characters as “pale longitudinal stripes”, and Coloma (1995) followed their usage. Duellman (2004) distinguished between the oblique lateral and dorsolateral stripes in his Summary of Taxonomic Characters but used them interchangeably in the text (e.g., idiomelus and sylvaticus are diagnosed as lacking oblique lateral stripes and possessing dorsolateral stripes, but the converse is true for both species; e.g., see Duellman's figs. 5F and 6F).

Edwards (1974a) was concerned only with the mostly cryptically colored dendrobatids then referred to Colostethus and not the more conspicuously colored species referred to Dendrobates and Phyllobates. The broader sample of the present study showed that there are (at least) two distinct “dorsolateral” stripes, which we have designated A (Character 52) and B (Character 53), the latter also having been confused previously with the oblique lateral stripe.

52. Dorsolateral Stripe A (Does Not Drop to Thigh; fig. 37): absent  =  0; present in juveniles only (i.e., lost ontogenetically)  =  1; anterior, narrow, faint  =  2; complete  =  3. Nonadditive.

Figure 37

Character 52, dorsolateral stripe A.

A, B: State 1, present in juveniles (A), absent in adults (B) (terribilis, A: captive-raised specimen; B: AMNH live exhibit). C: State 2, anterior, narrow, faint (atopoglossus, holotype UVC 12068). D: State 3, complete (aurotaenia, AMNH live exhibit).

This dorsolateral stripe runs posteriad from the eyelid toward the tip of the urostyle. It does not cross the flank toward the groin (oblique lateral stripe), nor does it drop to the top of the thigh (dorsolateral stripe B). Myers et al. (1978) reported that in bicolor and terribilis the dorsolateral stripe is present in juveniles and lost ontogenetically (state 1). This “loss” is peculiar, however, as it is due to the hypertrophy of the bright dorsolateral stripes that expand ontogenetically to cover the entire dorsum, thus creating a uniformly colored, stripeless color pattern.5 In state 2, the dorsolateral stripe is short, narrow, and inconspicuous (often more conspicuous in juveniles than adults), running from the posterior edge of the eye to a point just past the insertion of the arm. When present, the dorsolateral stripe of most species is complete, reaching or surpassing the level of the sacrum, and persists in adults (state 3).

The ontogenetic loss of the dorsolateral stripe is suggestive of additivity (i.e., absent ↔ present in juveniles only ↔ present throughout ontogeny); however, given the peculiarity of this particular “loss” through expansion, the additivity absent ↔ present throughout ontogeny ↔ present in juveniles only may be more appropriate. Regardless, it is unclear where state 2 would fit into this series, as there is no evidence that the dorsolateral stripe extends posteriorly through development, nor that state 2 is the result of reduction from a complete dorsolateral stripe. We therefore did not specify the additivity of this transformation series.

53. Dorsolateral Stripe B (Drops to Top of Thigh, Not Groin; fig. 38): absent  =  0; present  =  1.

Figure 38

Character 53, dorsolateral stripe B.

State 1, present (femoralis, AMNH 140646).

This dorsolateral stripe extends posteriad from the eyelid along the dorsolateral edge of the body and turns abruptly ventrad at a position immediately anterior to the thigh. This stripe was considered to be dorsolateral by Silverstone (1975a) and Caldwell and Myers (1990) for quinquevittatus, but oblique lateral (“lateral”) by Silverstone (1976) for femoralis. The confusion is understandable, as its path is intermediate between these two characters. Unlike the oblique lateral stripe, it does not run diagonally along the flanks but remains dorsal until almost the level of the thigh, but unlike dorsolateral stripe A, it drops toward the thigh posteriorly.

54. Ventrolateral Stripe (fig. 39): absent  =  0; wavy series of elongate spots  =  1; straight  =  2. Nonadditive.

Figure 39

Character 54, ventrolateral stripe.

A: State 1, wavy series of elongate, interconnected spots (espinosai, AMNH 104875). In this specimen the spotting forms a fairly contiguous wavy stripe, but it is common for the elongate spots to be separated, forming a broken stripe. B: State 2, straight (talamancae, AMNH 69829, photo by R. Zweifel). Note also that the pale dorsolateral stripe does not drop toward the thigh posteriorly (Character 52, state 3).

The ventrolateral stripe (VLS) runs along the ventral edge of the flank between the belly and the usually dark coloration of the flank. It may be present as a wavy series of elongate, often interconnected spots (state 1) or as a straight line (state 2). The ventrolateral stripe can be difficult to detect in preserved specimens, even those in which the ventrolateral stripe was prominent in life, because of the degradation of iridophores, especially in taxa with fairly pale ventral surfaces. In some of these cases the ventrolateral stripe can be detected as a lack of melanophores. However, the iridophores break down fairly quickly in preservative, often revealing a deeper layer of underlying melanophores invisible in living or freshly preserved specimens.

Coloma (1995: 47–48) reported that some specimens of pulchellus have “an interrupted white ventrolateral line”, but we did not observe this in the specimens examined. Caldwell and Lima (2003) reported the ventrolateral stripe as absent and described the holotype of nidicola as having “irregular white blotches, not forming a stripe”. However, a wavy VLS is evident in the photograph shown in their figure 3B (gravid female). Among the trivittatus specimens examined, the ventrolateral stripe is present in all specimens from Suriname but absent in all but one of the specimens from Peru (AMNH 43204, in which it is a series of small elongate spots on the left and a single, large elongate spot on the right).

55. Oblique Lateral Stripe: absent  =  0; present  =  1.

The pale oblique lateral stripe extends from the groin diagonally across the flanks toward the eye.

56. Oblique Lateral Stripe Length (fig. 40): partial  =  0; complete  =  1.

Figure 40

Character 56, oblique lateral stripe length.

A: State 0, partial (panamensis, AMNH 69836, photo by R. Zweifel). B: State 1, complete (fraterdanieli, MHNUC 364).

Edwards (1974b) distinguished oblique lateral stripes (OLS) that extend from the groin part-way to the eye (partial, state 0) or all the way to the eye (complete, state 1). There is some individual variation in the anterior extension of the partial OLS, but it usually terminates prior to and does not extend past the level of the insertion of the arm. There is no evidence that the stripe develops from one end to the other, which is why we did not combine length with presence/absence as an additive multistate character (i.e., absent ↔ partial ↔ complete).

Edwards (1974b: 10) described the OLS of sauli as incomplete, which is supported by both his painting (p. 6) and the color plate of the same specimen in Coloma (1995: plate 1A). However, Coloma (1995) explicitly compared sauli only to those species having a complete oblique lateral stripe, and we have also observed it to be complete. We therefore scored this character as polymorphic.

57. Oblique Lateral Stripe Structure (fig. 41): solid  =  0; series of spots  =  1; diffuse  =  2. Nonadditive.

Figure 41

Character 57, oblique lateral stripe structure.

A: State 0, solid (pulchripectus, AMNH 137290). B: State 1, series of spots (mertensi, ICN 43698). C: State 2, diffuse (trilineatus, AMNH 171974).

The oblique lateral stripe (OLS) of most species consists of a solid line of pale pigmentation (e.g., nubicola; state 0). Lynch and Ruiz-Carranza (1985) identified state 1 (series of well-defined spots) in agilis, and Myers et al. (1991: 2, 3, figs. 1, 3) illustrated it photographically for nocturnus. Grant and Rodríguez (2001) discussed variation in this character and described and illustrated photographically state 2. As shown in Grant and Rodríguez (2001: 9, fig. 6), state 2 may also include spots, but they are smaller, less distinct, and arranged irregularly (not in a line).

58. Gular–Chest Markings (fig. 42): absent  =  0; present  =  1.

Figure 42

Character 58, markings on gular–chest region, state 1 (present).

A: Diffuse, white-spotted blotches (awa, AMNH 111542). B: Discrete, small dark spots (vertebralis, USNM 28232). Despite their differing shapes and patterns, we treated the occurrence of these markings as a single character-state.

A number of species from the Andes of southern Colombia, Ecuador, and Peru possess highly variable dark spots or blotches on the posterolateral portion of the gular–chest region. Myers et al. (1991) compared these markings with the collars of several Venezuelan species and considered the possibility that they may be homologous. We code them as different transformations series here, the difference being that the gular–chest markings are always separated medially and do not form a continuous transverse band.

Coloma (1995: 10) reported several variants in the shape and pattern of the gular–chest markings. Much of this variation is intraspecific, and Coloma reported ontogenetic changes. Consequently, until this variation is better understood, we treated all of these variants as homologous and subsumed their occurrence within a single character-state. Although Coloma (1995: 10) discussed them in the same context, the markings on the mental region and the pair of spots on the posterior chest do not occur in the same region, and we did not treat them as part of this transformation series.

Coloma (1995) reported the presence of diffuse bandlike markings in bocagei, but it was absent from all the specimens we examined.

59. Dark Dermal Collar (fig. 43): absent  =  0; present  =  1.

Figure 43

Character 59, dermal collar, state 1 (present) in trinitatis.

A: Male (UMMZ 167474). B: Female (UMMZ 167471). In this species, the dermal collar of males is diffuse and broad, but is clearly distinguished from the fainter gray stippling of the adjacent surfaces.

The dermal collar (“chest markings” of La Marca, 1995) is a continuous transverse band of dark pigmentation that extends across the posterior throat, anterior to the arms. Although La Marca (1996 “1994”) reported sexual variation in its occurrence, we observed it to be present in adults of both sexes of all species that possess the dermal collar (although we did observe polymorphism in males of neblina), so we did not code males and females as separate semaphoronts.

Rivero (1978 “1976”: 330; translated from the Spanish) noted that “[i]n almost all specimens [of leopardalis] a faint dark collar may be detected, never as clear and well defined as in C. collaris, and generally confined to the sides of the throat.” Similarly, Myers et al. (1991) noted the occurrence of faint collarlike pigmentation on the throat of many specimens of nocturnus. Closer examination and dissection revealed that these dark collars are not caused by melanophores in the skin, as they are in other collared species (e.g., collaris), but instead by melanophores in the epimysium of the m. interhyoideus and connective tissue in the hyomandibular sinus (i.e., anterior to the pectoral apparatus) that are visible through the semitranslucent skin (fig. 44). The density of melanophores varies among individuals, with males having greater density (and therefore a more prominent collar) than females. Dense subdermal pigmentation may also occur in species with dark dermal pigmentation (e.g., galactonotus; see fig. 44), and individuals with dermal collars may (or may not) also present extensive subdermal pigmentation. In leopardalis (e.g., UMMZ 17170) the subdermal pigmentation is not as concentrated but still accounts for the faint collar reported by Rivero. Some degree of melanosis of the collar region is widespread among dendrobatids. However, as observed in pigmentation of the flesh generally, variation is continuous from a few melanophores scattered across the throat to a solid subdermal collar. As discussed above, we suspect there are valid transformation series here, but we were unable to delimit them objectively for the present study.

Figure 44

Extensive subdermal melanosis of the collar region.

A, B: nocturnus (AMNH 130008). C, D: galactonotus (AMNH 128233). Note also the irregular (clumped) stippling or faint, diffuse spotting in A (character 61, state 6; see below).

60. Dark Lower Labial Stripe (fig. 45): absent  =  0; present  =  1.

Figure 45

Character 60, dark lower lip line.

State 1, present (fraterdanieli, MHNUC 364).

In fraterdanieli Grant and Castro-Herrera (1998) indicated the occurrence of a distinctive dark (black or brown) line along the lower lip and contrasting with the pale adjacent coloration.

61–64. Male and Female Throat and Abdominal Coloration

The color and color pattern of the throat and abdominal regions of adult males and females provide some of the most useful characters for discriminating among species of dendrobatids. Sexual dimorphism is common, especially in throat color and color pattern, but most states occur in both sexes.

In a series of field experiments, Narins et al. (2003) showed that both vocalization and pulsation of the dark vocal sac of femoralis are necessary to elicit aggressive responses, and they have experimented with this system to reveal the extent of temporal and spatial integration of these stimuli required for an aggressive response (Narins et al., 2005). Given the extent of species- and sex-specific variation in throat coloration in many dendrobatids, it is likely that integration of visual and vocal cues will be found to be widespread. To date Narins et al.'s investigations have only examined aggressive male–male interactions in this single species, but application of their procedures more generally promises to reveal fascinating insights into the role of throat coloration in aggresive and other interactions between males, females, and juveniles across multiple species.

A few points apply to the coding of all the following characters. First, as discussed above, we emphasized color pattern over color. Second, spotting, marbling, and reticulation form a continuous gradient that, though unambiguous in the extremes, we were unable to delimit objectively. We therefore treated these as a single character-state, although we undoubtedly overlooked additional transformations by doing so. Third, it may be difficult to discriminate between pale spotting/reticulation/marbling on a dark background versus dark spotting/reticulation/marbling on a pale background, as the distinction has to do with adjacent coloration and the relative concentration of pale and dark pigmentation. Many species are unambiguously one or the other, but others were either ambiguous or exhibited both states and were therefore coded as polymorphic. Fourth, we also treated irregular stippling (i.e., clumped stippling) and the occurrence of diffuse dark spotting as a single state because we were unable to discriminate two states objectively. Finally, the collar and gular–chest markings (characters 58, 59) are independent of the region referred to as the throat. For our purposes, throat refers to the region of the central gular region, that is, the area of the vocal sac in males.

61. Male Throat Color (figs. 44A, 46): pale, free or almost free of melanophores  =  0; dark due to absence of iridophores  =  1; evenly stippled  =  2; pale with discrete dark spotting/reticulation/marbling  =  3; solid dark  =  4; dark with discrete pale spotting/reticulation/marbling  =  5; irregular (clumped) stippling or faint, diffuse spotting  =  6. Nonadditive.

Figure 46

Character 61, male throat color.

A: State 0, pale, free or almost free of melanophores (“Neblina species”, AMNH 118689). B: State 1, dark due to absence of iridophores (abditaurantius, ICN 9853). This character-state is inconspicuous in preserved specimens but obvious in living or recently prepared specimens. C: State 2, evenly stippled gray (infraguttatus, AMNH 104846). Note that the gular–chest markings (character 58) of infraguttatus do not interfere with the even stippling of the throat. D: State 3, pale with dark spots (“nubicola-spC”, MHNUC 321). E: State 4, solid dark (inguinalis, LACM 42329). F: State 5, dark with discrete pale spotting/reticulation/marbling (tricolor, USNM 286082).

In state 0 (pale, free or almost free of melanophores) the throat appears immaculate, but closer inspection may reveal sparse, inconspicuous melanophores. State 1 (dark due to absence of iridophores) is conspicuous in life but may easily be overlooked in preserved specimens. See Grant and Castro-Herrera (1998) for this character-state in life. The spotting/reticulation/marbling of the vocal sac is often irregular. State 6 (dark with pale medial stripe) is restricted to only boulengeri and espinosai. In both species the medial “stripe” varies from one or more elongate spots to a solid stripe. Also, the adjacent dark surfaces sometimes include scattered pale spots. States 0–5 are shown in figure 46; state 6 is shown in figure 44A.

62. Female Throat Color (fig. 47): pale, free or almost free of melanophores  =  0; irregular (clumped) stippling or faint, diffuse spotting  =  1; solid dark  =  2; dark with discrete pale spotting/reticulation/marbling  =  3; pale with discrete dark spotting/reticulation/marbling  =  4; dark with pale medial longitudinal stripe  =  5. Nonadditive.

Figure 47

Character 62, female throat color.

A: State 0, pale, free or almost free of melanophores (undulatus, AMNH 159128). B: State 1, irregular (clumped) stippling or faint, diffuse spotting (nocturnus, AMNH 130018). C: State 2, solid dark (hahneli, AMNH 96190). D: State 3, dark with discrete pale spotting/reticulation/marbling (imbricolus, AMNH 102083). E: State 4, pale with discrete dark spotting/reticulation/marbling (fraterdanieli, AMNH 148021). F: State 5, dark with pale medial longitudinal stripe (boulengeri, USNM 145281).

63. Male Abdomen Color (fig. 48): pale, free or almost free of melanophores  =  0; pale with discrete dark spotting/reticulation/marbling  =  1; evenly stippled  =  2; dark with discrete pale spotting/reticulation/marbling  =  3; irregular (clumped) stippling or faint, diffuse spotting  =  4; solid dark  =  5. Nonadditive.

Figure 48

Character 63, male abdomen color.

A: State 0, pale, free or almost free of melanophores (“Neblina species”, AMNH 118689). B: State 1, pale with discrete dark spotting/reticulation/marbling (quinquevittatus, AMNH 124069). C: State 2, evenly stippled (talamancae, AMNH 113893). D: State 3, dark with discrete pale spotting/reticulation/marbling (infraguttatus, AMNH 104846). E: State 4, irregular (clumped) stippling or faint, diffuse spotting (nocturnus, AMNH 130012). F: State 5, solid dark (inguinalis, LACM 42329).

64. Female Abdomen Color (fig. 49): pale, free or almost free of melanophores  =  0; pale with discrete dark spotting/reticulation/marbling  =  1; solid dark  =  2; dark with discrete pale spotting/reticulation/marbling  =  3; irregular (clumped) stippling or faint, diffuse spotting  =  4; evenly stippled  =  5. Nonadditive.

Figure 49

Character 64, female abdomen color.

A: State 0, pale, free or almost free of melanophores (undulatus, AMNH 159128). B: State 1, pale with dark spotting/reticulation/marbling (fraterdanieli, AMNH 39360). C: State 2, solid dark (silverstonei, AMNH 91845). D: State 3, dark with discrete pale spotting/reticulation/marbling (infraguttatus, AMNH 104849). E: State 4, irregular (clumped) stippling or faint, diffuse spotting (nocturnus, AMNH 130018). F: State 5, evenly stippled (riveroi, AMNH 134141).

Coloma (1995: 54) described vertebralis as having “dark stippling on abdomen in females, darker in males”; however, none of the females in the series AMNH 17458, 17604–08, 140977–141011 possesses any stippling on the abdomen (but all males do). Although we coded riveroi as having the abdominal region evenly stippled, in life it is posteriorly orange (Donoso-Barros, 1965 “1964”).

65. Iris Coloration (fig. 50): lacking metallic pigmentation and pupil ring  =  0; possessing metallic pigmentation and pupil ring  =  1.

Figure 50

Character 65, iris coloration.

A: State 0, lacking metallic pigmentation and pupil ring (bicolor, AMNH live exhibit). B: State 1, with metallic pigmentation and pupil ring (subpunctatus, uncataloged MUJ specimen from Colombia: Bogotá, D.C., campus of Universidad Nacional de Colombia).

Silverstone (1975a: 8) noted that in life the iris of the species he included in Dendrobates is “black (or rarely dark brown) and is never reticulated”. Similarly Silverstone (1976: 3) stated that in the species he included in Phyllobates “the iris is black or brown (rarely bronze) and never reticulated”. We diagnose this character somewhat more precisely, but we believe our intentions are the same.

The iris coloration of most dendrobatids includes metallic pigmentation (bronze, copper, gold, silver) producing a metallic iris with a black reticulated pattern or a black iris with metallic flecks. Additionally, a distinct metallic ring around the pupil invariably occurs in irises with metallic pigmentation. A number of the aposematic dendrobatids lack all metallic pigmentation in the iris, giving rise to the solid black or brown iris mentioned by Silverstone.

This character can only be coded from living specimens. We dissected the eyes of preserved specimens of several species but failed to detect differences between pigmented and unpigmented irises. We therefore relied on explicit field notes, personal observations, and high-quality photographs. In addition to personal observations and unpublished field notes and photographs, this character was scored from the following published accounts: arboreus (Myers et al., 1984); aurotaenia (Silverstone, 1976; Lötters et al., 1997a); azureiventris (Kneller and Henle, 1985; Lötters et al., 2000); awa (Coloma, 1995); baeobatrachus (Lescure and Marty, 2000); bicolor (Myers et al., 1978; Lötters et al., 1997a); bocagei (Coloma, 1995); boulengeri (Silverstone, 1976); caeruleodactylus (Lima and Caldwell, 2001); claudiae (Jungfer et al., 2000); delatorreae (Coloma, 1995); degranvillei (Boistel and de Massary, 1999; Lescure and Marty, 2000); elachyhistus (Coloma, 1995; Duellman, 2004); flotator (Savage, 2002), Eupsophus roseus ([for E. calcaratus] Nuñez et al., 1999); granuliferus (Myers et al., 1995; Savage, 2002); herminae (La Marca, 1996 “1994”); Hylodes phyllodes (Heyer et al., 1990); ideomelus (Duellman, 2004); imitator (Symula et al., 2001); infraguttatus (Coloma, 1995); insperatus (Coloma, 1995); insulatus (Duellman, 2004); kingsburyi (Coloma, 1995); lehmanni Myers and Daly (Myers and Daly, 1976b); lugubris (Silverstone, 1976; Savage, 2002); macero (Rodríguez and Myers, 1993; Myers et al., 1998); machalilla (Coloma, 1995); molinarii (La Marca, 1985); nexipus (Frost, 1986; Hoff et al., 1999); nidicola (Caldwell and Lima, 2003); nocturnus (Myers et al., 1991); nubicola (Savage, 2002), parvulus (Silverstone, 1976); pictus (Köhler, 2000); petersi (Rodríguez and Myers, 1993; Myers et al., 1998); pulchellus (Coloma, 1995); pulchripectus (Silverstone, 1975a); pulcherrimus (Duellman, 2004); pumilio (Myers et al., 1995; Savage, 2002); quinquevittatus (Caldwell and Myers, 1990); reticulatus (Myers and Daly, 1983); rubriventris (cover of Herpetofauna 19(110); see also Lötters et al., 1997b); sauli (Coloma, 1995); silverstonei (Myers and Daly, 1979); speciosus (Jungfer, 1985); sylvaticus Barbour and Noble (Duellman, 2004); sylvaticus Funkhouser (Myers and Daly, 1976b [as histrionicus]; Lötters et al., 1999); talamancae (Coloma, 1995); terribilis (Myers et al., 1978); toachi (Coloma, 1995); trinitatis (Wells, 1980c; La Marca, 1996 “1994”); trivittatus (Myers and Daly, 1979); undulatus (Myers and Donnelly, 2001); vanzolinii (Myers, 1982); ventrimaculatus (Lötters, 1988 [as quinquevittatus]; Lescure and Bechter, 1982 [as quinquevittatus]); vertebralis (Coloma, 1995); vicentei (Jungfer et al., 1996b); vittatus (Silverstone, 1976; Savage, 2002); zaparo (Silverstone, 1976).

66. Large Intestine Color (fig. 51): unpigmented  =  0; pigmented anteriorly  =  1; pigmented extensively  =  2. Additive.

Figure 51

Character 66, large intestine color.

A: State 0, unpigmented (“Neblina species”, AMNH 118679). Note that the distended tissue is translucent. B: State 1, anteriorly pigmented (pratti, SIUC 07654). C: State 2, extensively pigmented (beebei, ROM 39631).

The large intestine of most species is unpigmented (state 0), being either white or (when distended) translucent. In some species, heavy melanosis forms a solid black coloration extending posteriad from the front of the large intestine. In state 1 the melanosis is confined to the anterior quarter of the large intestine; in state 2 it extends beyond the midlevel of the large intestine. The ontogeny of this character invariably progresses from state 0 through state 1 to state 2, which we interpret as evidence for the additivity of this transformation series.

67. Adult Testis (Mesorchium) Color (fig. 52): unpigmented  =  0; pigmented medially only  =  1; entirely pigmented  =  2. Additive.

Figure 52

Character 67, adult testis (mesorchium) color.

State 2, entirely pigmented testes (claudiae, AMNH 124257) in ventral view.

Testis color is scored from adults only. In all dendrobatids we have examined, testis pigmentation increases ontogenetically, with the mesorchia of juveniles being invariably entirely unpigmented white (state 0) and melanosis beginning medially (state 1) and eventually covering the testis entirely (state 2), forming either a dark reticulum or a solid dark color. Ontogenetic series show this character to develop from state 0 to state 1 to state 2, which we interpret as evidence of additivity.

Polymorphism among adults is rare. Grant (2004) found that of 40 specimens of panamensis scored, the left testes of two were unpigmented whereas the right testes were pigmented brown. Grant (2004) also documented unusual variation in the testis pigmentation of inguinalis. Testes of all adults had some degree of dark pigmentation, but it varied from being confined to medial and anterior surfaces to engulfing the entire testis; this variation was not correlated with adult size, extent of dark ventral pigmentation, or maturity. It is likely that such variation is hormonally controlled and related to sexual activity, but no evidence exists to support this conjecture. Among the included outgroup taxa, Lötters (1996) reported that, although most species of Atelopus possess permanently unpigmented testes, in some species the testes become pigmented with the onset of the breeding season.

68. Color of Mature Oocytes (fig. 53): unpigmented (uniformly white or creamy yellow)  =  0; pigmented (animal pole brown or black)  =  1.

Figure 53

Character 68, mature ova color.

A: State 0, white or yellowish (Atelopus spurrelli, AMNH 50983). B: State 1, pigmented (brown) (“Neblina species”, AMNH 118679).

The entire oocyte may be white or creamy yellow (state 0) or differential localization of pigment granules in the animal cortex may give rise to a dark (brown or black) animal hemisphere and white or creamy yellow vegetal hemisphere (state 1).

Duellman and Trueb (1986) explained egg pigmentation as an adaptation to exposure to sunlight, and they listed a number of anuran groups in support of that hypothesis. However, it is unclear if that adaptive explanation holds among dendrobatids, given that many species with pigmented eggs lay clutches that are not exposed to sunlight. For example, Myers and Daly (1979) found “a clutch of 30 eggs … on a curled dry leaf that was completely concealed by another leaf of the cut-over forest floor”, yet that species has pigmented eggs. It has also been conjectured (e.g., Duellman and Trueb, 1986) that this melanosis either raises egg temperature by better absorbing ambient heat or provides protection from exposure to ultraviolet radiation. Missing from previous discussions is an evaluation of the polarity of the transformations. Until this is evaluated through phylogenetic analysis, it is impossible to know if a particular instance of pigmentation (or lack of pigmentation) is apomorphic (and therefore a candidate for an explanation of adaptation) or symplesiomorphic.

Duellman and Trueb (1986: 535) reported that Rhinoderma darwinii possesses unpigmented ova, but specimens examined had pigmented ova.

69. M. Semitendinosus Insertion (figs. 54, 55): “bufonid type” (ventrad)  =  0; “ranid type” (dorsad)  =  1.

Figure 54

Character 69, m. semitendinosus insertion.

Photograph (left) and outline drawing (right) of ventral view of distal thigh of Thoropa miliaris (AMNH 17044), showing state 0, ventrad “bufonid” path of insertion. Arrow indicates the m. semitendinosus tendon of insertion.

Figure 55

Character 70, m. semitendinosus binding tendon.

State 1, present (aurotaenia, AMNH 161109), photograph (left) and outline drawing (right) showing view of the concealed surface of the knee. The mm. gracilis complex is deflected ventrally to reveal the dorsad “ranid” path of the m. semitendinosus and the secondary binding tendon that straps it to the outer edge of the mm. gracilis complex.

Noble's (1922) seminal work brought thigh musculature to the forefront of studies of anuran relationships, and since then the path of insertion of the distal tendon of the m. semitendinosus has played an important role in discussions of dendrobatid relationships (reviewed by Grant et al., 1997). Noble identified two predominant morphologies: (1) the putatively primitive “bufonid type” in which the tendon of the m. semitendinosus inserts ventrad to the tendon of insertion of the mm. gracilis complex, and (2) the putatively derived “ranid type” in which it inserts dorsad to the mm. gracilis.

Noble also reported a number of “intermediate” morphologies, including that of dendrobatids. However, the m. semitendinosus of dendrobatids clearly inserts dorsal to the mm. gracilis, the apparent intermediacy owing to a secondary binding tendon (see Character 70, below). Similarly, Noble interpreted intermediate morphologies as providing evidence for the “inward migration” of the tendon of insertion of the m. semitendinosus from the presumptively primitive “bufonid” position to the derived “ranid” position. However, he relied on phylogenetic evidence to establish character additivity, not ontogenetic (or other) evidence. The groups Noble considered most primitive had “bufonid type” insertion, those he thought were most derived had “ranid type”, and variants were treated as intermediate between the two. Such reasoning is obviously fallacious, as it conflates the premises of analysis with the conclusions. We are unaware of developmental evidence of inward migration of the m. semitendinosus tendon of insertion from the “bufonid” to the “ranid” position.

70. M. Semitendinosus Binding Tendon (fig. 55): absent  =  0; present  =  1.

As first described and illustrated by Noble (1922: 41 and plate XV, fig. 6)6, the dendrobatid thigh has a well-defined binding tendon7 that straps the m. semitendinosus distal tendon to the dorsal edge of the inner surface of the mm. gracilis complex (state 1; fig. 55). In some large species, such as palmatus and nocturnus, this binding tendon is robust and conspicuous, giving the impression that the distal tendon of the m. semitendinosus actually pierces or penetrates the distal mm. gracilis tendon (e.g., Dunlap, 1960: 66). However, even in these species the m. semitendinosus tendon does not pass through the tendinous tissue, but rather between the binding tendon and the gracilis muscle (therefore differing from myobatrachids; Noble, 1922; Parker, 1940). This tendinous tissue also forms a secondary tendon that inserts on the inner (posterior) surface of the proximal head of the tibiofibula. Another secondary tendon is often present, arising near the ventral edge of the inner surface of the m. gracilis and leading to the thick sheet of connective tissue that wraps around the knee. Distal to the binding tendon, the m. semitendinosus tendon expands to insert along the long axis of the ventral surface of the tibiofibula.

71. M. Levator Mandibulae Externus Division: undivided (“s”)  =  0; divided (“s + e”)  =  1.

In her dissertation, Starrett (19688) found that the jaw adduction musculature of dendrobatids includes a single muscle originating from the zygomatic ramus of the squamosal that lies deep (internal, medial) to the mandibular ramus of the trigeminal nerve (V₃), which she interpreted as the presence of the m. adductor posterior mandibulae subexternus and absence of the m. adductor mandibulae externus superficialis, or condition “s” in her system (state 0). Silverstone (1975a) found this in all 41 species he examined, and other workers (Myers et al., 1978, 1991; Myers and Daly, 1979; Myers and Ford, 1986; Grant et al., 1997; Grant, 1998) have found this in almost all dendrobatids (see below). Our observations conform with the accounts of previous workers, with the exception that fibers generally originate on the anterior edge of the annulus tympanicus as well. In addition to the “s” morphology, among other frogs Starrett (1968) reported the presence of both muscles, or “s + e” in her system (state 1), as well as the absence of the m. adductor posterior mandibulae subexternus and presence of the m. adductor mandibulae externus superficialis, “e” (not observed in the present study).

Haas (2001) reevaluated the homology of these muscles based on detailed developmental studies across the diversity of amphibians. He concluded that the “subexternus” and “externus” muscles are actually different portions of the same muscle (slips, in our terminology; see Materials and Methods, above)—the m. levator mandibulae externus profundus and m. levator mandibulae externus superficialis, respectively. As such, Starrett's (1968) three conditions (“s”, “e”, and “s + e”) involve two distinct transformation series: (1) the m. levator externus is constant in both “s” and “e” and the transformation series is formed by changes in the position of V₃, deep (internal, medial) in the “s” and superficial (external, lateral) in the “e”; (2) “s + e” is formed by the division of the m. levator mandibulae externus into profundus and superficialis slips, with V₃ lying between them. Because we did not observe the “e” condition in any of the species coded for morphology in the present study, we scored only the latter transformation series.

The sole published exception to the undivided m. levator mandibulae externus (“s”; state 0) morphology in dendrobatids is nocturnus, in which Myers et al. (1991) found the m. levator externus of some specimens (or one side) to form two distinct slips (“s + e”; state 1). Myers et al. (1991) interpreted this observation as possibly indicative of both the ranoid origin of dendrobatids and the primitiveness of nocturnus within the dendrobatid clade. The only other exception we observed was a specimen of vanzolinii (AMNH 108332) in which V₃ pierces the m. levator mandibulae externus. However, we did not code the superficial and medial fibers as different slips (i.e., “s + e”) because the fibers are tightly bound both dorsal and ventral to the nerve and are not segregated by connective tissue septa (as they are in nocturnus, for example) and therefore do not form distinct slips (for similar individual variation, see Lynch, 1986). That said, only a single specimen was available for dissection, and the symmetry of this morphology suggests that further study may reveal a phylogenetically relevant change in the path of V₃.

Additional intraspecific variation was observed in Hylodes phyllodes. Of the 11 frogs in the series AMNH 103885–95, in 2 (AMNH 103888, 103890) V₃ runs medial to a distinct m. levator mandibulae externus superficialis (“s + e”; state 1) on both sides of the head, whereas the remaining 9 specimens all lack that slip (“s”; state 0). As in nocturnus, and in contrast to vanzolinii, the lateral fibers form a distinct slip. Indeed, in H. phyllodes all of the lateral fibers appear to originate on the rim of the annulus tympanicus, whereas the medial slip originates from the squamosal. Although this latter consideration is suggestive of nonhomology of the m. levator mandibulae externus superficialis in these taxa, we coded them as the same state and subjected that hypothesis to the test of character congruence.

72–75. M. Depressor Mandibulae

Starrett (1968) identified three distinct slips of the m. depressor mandibulae of dendrobatids: a massive, superficial slip originating from the dorsal fascia overlying the scapula and m. levator posterior longus, a deeper slip originating from the otic ramus of the squamosal, and an additional slip of fibers originating on the tympanic annulus. The combined morphology was codified as DFSQ_dAT. Lynch (1993: 37) refined the delimitation of this condition as “one in which some number of superficial fibers of the squamosal portion of the m. depressor mandibulae extend medial to the crest of the otic ramus of the squamosal and overlie the fibers of the m. levator posterior longus.” Silverstone (1975a) confirmed that all 41 species of dendrobatids he examined have this morphology, and this was further confirmed in additional species by Myers and coworkers (e.g., Myers et al., 1978, 1991; Myers and Daly, 1979; Myers and Ford, 1986).

Lynch (1993) rejected the anatomical findings of Starrett (1968), at least as they applied to Eleutherodactylus. Of greatest relevance to dendrobatids is his finding (pp. 37–38) that the superficial “DF” fibers actually are “bound tightly to deeper fibers … that originate on the lateral face of the otic ramus of the squamosal”. That is, the fibers from the two origins are not segregated by connective tissue septa and therefore do not constitute distinct slips. Our dissections confirm Lynch's observations in dendrobatids and the sampled outgroup taxa as well, leading us to follow him in discarding Starrett's terminology.

Nevertheless, regardless of whether the depressor muscle is divided into distinct slips or not, the variation in fiber origins constitutes a valid transformation series. In all specimens examined, some fibers originate from the otic ramus of the squamosal. In all dendrobatids examined, the vast majority of fibers originates form the dorsal fasciae. Lynch (1993) referred to the portion of the m. depressor mandibulae that originates medial to the crest of the squamosal on the m. temporalis as a “dorsal flap”, and we follow his terminology here (Character 73). We scored as Character 74 the origin of fibers posterior to the crest of the squamosal. The occurrence of fibers originating on the posterior edge of the annulus tympanicus is coded in Character 75.

Manzano et al. (2003) presented an extensive survey of the m. depressor mandibulae in anurans. Among dendrobatids, they examined auratus, pictus, and subpunctatus. Our observations and coding conform generally with theirs, with the following exceptions: (1) Manzano et al. did not recognize the dorsal flap as a separate character. (2) Manzano et al. reported that the superficial “slip” of auratus is divided into anterior and posterior “slips”, whereas that of pictus and subpunctatus consists of a single, wide, fan-shaped muscle. We examined 20 uncataloged AMNH skinned carcasses of auratus from Isla Tobago, Panama, constituting 40 depressor muscles. In that series, variation is continuous between an uninterrupted fan-shaped muscle, the occurrence of a slight division across the thoracic sinus, and well-defined separate branches, with conspicuous bilateral asymmetry in some specimens. Given the continuous variation, we were unable to delimit states objectively. Moreover, the degree of individual variation suggests that the differences are likely nongenetic, although we cannot offer any direct evidence to that effect. (3) Manzano et al. reported fibers originating from the annulus tympanicus in Rhinoderma darwinii. However, although we observed fibers to extend toward the annulus, in the specimens we examined (AMNH 37849, 58082), the fibers invariably run along the cartilage and ultimately attach to the squamosal.

72. M. Depressor Mandibulae Dorsal Flap: absent  =  0; present  =  1.

73. M. Depressor Mandibulae Origin Posterior to Squamosal: absent  =  0; present  =  1.

74. M. Depressor Mandibulae Origin on Annulus Tympanicus: no fibers originating from annulus tympanicus  =  0; some fibers originating from annulus tympanicus  =  1.

Among dendrobatids, the fibers that attach to the annulus tympanicus are generally deep and easily overlooked, but careful dissection showed them to be present in all dendrobatids examined.

75. Tympanum and m. Depressor mandibulae relation: tympanum superficial to m. depressor mandibulae  =  0; tympanum concealed superficially by m. depressor mandibulae  =  1.

Myers and Daly (1979: 8) pointed out that in dendrobatids “the large superficial slip of the depressor mandibulae muscle tends to slightly overlap the tympanic ring and, in any case, holds the skin away from the rear part of the tympanum, thus accounting for the fact that the tympanum is only partially indicated externally” (see also Myers and Ford, 1986; Myers et al., 1991). Daly et al. (1996) further discussed this character and compared conditions found in Mantella.

76. Vocal Sac Structure: absent  =  0; median, subgular  =  1; paired lateral  =  2. Nonadditive.

This character was coded following Liu (1935). Although we coded the vocal sac for the sampled species Megaelosia goeldii, in which males lack vocal sacs and slits and presumably do not call (Giaretta et al., 1993), other species of Megaelosia possess paired lateral vocal sacs (e.g., M. lutzae; Izecksohn and Gouvêa, 1987 “1985”). Lynch (1971) reported the state for Eupsophus roseus (coded for E. calcaratus).

77–78. M. Intermandibularis Supplementary Element (Fig. 56)

Tyler (1971) described variation in superficial throat musculature of hylids and other anurans, reporting the differentiation of the m. intermandibularis to form a supplementary element in two species of Colostethus [as Calostethus], two species of Dendrobates, and two species of Phyllobates. He did not list the species of dendrobatids he examined or describe the dendrobatid condition in any detail. La Marca (1995: 45) noted the occurrence of “supplementary elements of the anterolateral type attached to the ventral surface of the m. submentalis”. Of relevance to the current study, Burton (1998b) also reviewed the occurrence and variation in supplementary elements of numerous Neotropical hyloid groups.

The treatment of the supplementary element in phylogenetic analysis is somewhat problematic, as the homology of the elements in different taxa is debatable. Following Tyler's (1971) terminology, dendrobatids possess an anterolateral element: Fibers originate on the lingual surface of the anterior portion of the mandible and run anteriomediad to insert on the ventral surface of the m. submentalis, with the more posterior fibers underlying (superficial to) the deeper fibers of the m. intermandibularis. Tyler also identified apical and posterolateral elements in other groups of anurans, and these conditions have been largely supported by subsequent workers. Tyler (1971) effectively treated each of the morphologies as nonhomologous (i.e., the differences in morphologies was treated as evidence that each of the supplementary elements was independently derived), but other workers have treated them as a homologous entity with subsequent variation (e.g., Burton, 1998b; Mendelson et al., 2000).

The shared origin of the supplementary element on the lingual surface of the mandible superficial to the deeper primary sheet of the m. intermandibularis and the fact that the different morphologies never co-occur are sufficient evidence to treat the supplementary elements of different anurans as a homologous structure. We therefore submitted the hypothesis of supplementary slip homology to the simultaneous test of character congruence by coding its occurrence as one character and the variation in the element as a second character.

77. M. Intermandibularis Supplementary Element Occurrence: absent  =  0; present  =  1.

78. M. Intermandibularis Supplementary Element Orientation: 0  =  anterolateral; 1  =  anteromedial.

Among the sampled species that possess the supplementary element, we observed two patterns. In the first (state 0), the fibers radiate anterolaterally from a sagittal raphe. In the second, the fibers extend anteromedially from the mandible. Burton (1998b) reported both of these morphologies for a variety of Neotropical “leptodactylids”. However, our coding deviates from Burton's (1998b) in that he treated species with anterolateral supplementary slips (e.g., Hylodes spp.) and without supplementary slips but having all fibers directed mediad or anterolaterad (e.g., Thoropa miliaris) as “variants of the same general pattern” (pp. 67–68). Burton based this decision on “the fact that two of these variants may occur within the same genus (e.g., Cycloramphus), or within the same species (C[audiverbera]. caudiverbera)” (p. 67). Co-occurrence of this nature does not constitute evidence of character-state identity (if it did, polymorphism would be conceptually impossible), and we scored Hylodes phyllodes and Thoropa miliaris differently.

Manzano and Lavilla (1995) reported an apical supplementary element in Rhinoderma darwinii; according to the terminology employed herein, it is anterolateral (state 0).

79–86. Median Lingual Process (Figs. 57, 58)

Grant et al. (1997) discovered the median lingual process (MLP; fig. 57) in dendrobatids and documented its occurrence and variation throughout Anura (for additional dendrobatid records, see Myers and Donnelly, 1997; Grant and Rodríguez, 2001). Of greatest interest was the finding that an apparently homologous modification of the tongue occurs in dendrobatids and several Old World ranoids (including the putative sister group postulated by Griffiths, 1959) but is entirely lacking among all hyloid taxa. The functional significance of the MLP remains unknown. Variation in the MLP has been illustrated extensively by Grant et al. (1997) and Myers and Donnelly (1997); here we provide illustrations for novel characters.

Figure 57

Anterior view of the open mouth of the dendrobatid praderioi (CPI 10203) showing the short, tapered median lingual process (MLP).

As a first effort to understand the distribution and diversity of the MLP, Grant et al. (1997) allocated the observed variation to four “types”. For phylogenetic analysis it was necessary to decompose those types into their component transformation series. Given the relevance of this anatomical structure to the placement of Dendrobatidae, we examined the histology of the tongues of eight species to gain a better understanding of its structure. Additional data were gathered through gross dissection. Although several of the characters we observed do not vary among the MLP-possessing taxa sampled in the present study, they vary independently in the broader context of the evolution of the MLP in anurans, and we therefore score all of these characters here.

To discover differences between the type C processes of Old World and New World taxa, we examined the histology of two species of the dendrobatids tepuyensis and baeobatrachus, and we compared them to Phrynobatrachus natalensis and Phrynobatrachus petropedetoides. These two species of Phrynobatrachus have retractile type C processes, which we hoped would maximize the morphological differences between them and the nonretractile type C processes of the dendrobatids. To gain insight into the mechanism of retraction and protrusion, one of the specimens of Phrynobatrachus petropedetoides had the MLP fully protruded, whereas the other one had it retracted below the surface of the tongue. We also examined the type A processes of Arthroleptis variabilis, Mantidactylus femoralis, Platymantis dorsalis, and Staurois natator (the latter two species were included only for comparative purposes to delimit transformation series more rigorously and were not coded for phylogenetic analysis). Due to lack of specimens, we did not examine any type B or D processes.

The MLP of all examined taxa (i.e., types A and C, retractile and nonretractile) is formed through the same modification of the basal portion of the m. genioglossus, supporting the hypothesis that they are homologous structures. As seen in sagittal and transverse section of baeobatrachus (fig. 58) the m. genioglossus basalis is extended dorsally to protrude above the lingual surface as the median lingual process. In all taxa, muscle fibers are replaced distally by loose, presumably collagenous connective tissue, with elastic fibers forming the walls of the process. Although we did not stain specifically for nervous tissue, no major nerves were detected within the MLP. Additional histological findings are discussed below under the relevant characters.

Figure 58

Longitudinal histological section of the tongue of baeobatrachus (AMNH 140672) showing that the median lingual process (MLP) is an extension of the m. genioglossus.

Note lack of muscle fibers toward the tip of the MLP.

79. MLP Occurrence: absent  =  0; present  =  1.

To count the origin of the MLP as a single event (and not as multiple origins of each of the nested characters), we scored the occurrence of the MLP as a separate character. That is, species that lack the MLP were scored as state 0 for this character and missing (“–“) for the remaining MLP characters.

80. MLP Shape: short, bumplike  =  0; elongate  =  1.

We considered the MLP to be short and bumplike if it its length (height) was no greater than its width at the base and elongate if its length was greater than its width at the base.

81. MLP Tip: blunt  =  0; tapering to point  =  1.

82. MLP Texture: smooth  =  0; rugose  =  1.

Grant et al. (1997) found most MLPs to be smooth relative to the lingual surface (state 0) but that in some species the MLP is rugose, textured like the adjacent surfaces of the tongue.

83. MLP Orientation when Protruded: upright  =  0; posteriorly reclined  =  1.

When protruded, Grant et al. (1997) reported upright MLPs pointing straight dorsad (state 0) and posteriorly reclined MLPs (state 1).

84. MLP Retractility (fig. 59): nonretractile  =  0; retractile  =  1.

Figure 59

Character 84, median lingual process (MLP) retractility, state 1 (retractile).

A: Transverse section of a protruded MLP in Phrynobatrachus natalensis (AMNH 129714). B: Transverse section of a retracted MLP in Phrynobatrachus petropedetoides (AMNH 129626).

Following the reasoning of Grant et al. (1997), retractility was inferred from the position of the MLP in preserved specimens. We were unable to detect any histological differences between retractile and nonretractile processes. However, the fact that even very small series of some species show the MLP in various stages of retraction whereas very large samples of others do not include a single retracted lingual process suggests that this is not merely an artifact of preservation.

Comparison of retracted and protruded processes provides some clues as to the mechanism involved in retractility. As seen in figure 59A of the protruded process of Phrynobatrachus natalensis in transverse view, the connective tissue that extends to the tip of the MLP is very loose, with large spaces between the fibers and fibroblasts. In contrast, in a specimen of Phrynobatrachus petropedetoides with the MLP completely retracted below the surface of the tongue (fig. 59B), the loose connective tissue is much denser with no spaces between the fibers and fibroblasts, reminiscent of a squeezed sponge. This is characteristic of hydrostatic organs such as the feet of mollusks and suggests that protrusion and retraction of the MLP is achieved by the displacement of some sort of fluid.

85. MLP-Associated Pit: absent  =  0; present  =  1.

Grant et al. (1997) noted the absence (state 0) and presence (state 1) of a pit immediately posterior to the MLP into which fits the posteriorly reclined MLP of some species. Although all of the species with posteriorly reclined MLPs sampled in the present study also have an associated pit, the observations of Grant et al. (1997) establish the transformational independence of the two characters.

86. MLP Epithelium (fig. 60): glandular  =  0; nonglandular  =  1.

Figure 60

Character 86, median lingual process (MLP) epithelium.

A: State 0, glandular (Phrynobatrachus petropedetoides, AMNH 129593). The surface of the MLP is pitted with invaginations of the epithelium that form alveolar glands. B: State 1, nonglandular (Phrynobatrachus natalensis, AMNH 129732). The alveolar glands are absent, and the surface of the MLP consists of unmodified stratified epithelium.

In state 0 the surface of the MLP is pitted with invaginations of the epithelium that form alveolar glands, as occur over the rest of the surface of the tongue. In state 1, these glandular invaginations do not occur, and the MLP is covered in unmodified, stratified epithelium.

87–98. Larvae

In addition to specimens examined, larval data were taken from Ruthven and Gaige (1915), Fernández (1926), Funkhouser (1956), Donoso-Barros (1965 “1964”), Savage (1968), Duellman and Lynch (1969), Hoogmoed (1969), Edwards (1971, 1974b), Lynch (1971), McDiarmid (1971), Silverstone (1975a; 1976), Lescure (1976), Duellman (1978, 2004), Myers and Daly (1979), Cei (1980), Lescure and Bechter (1982), Heyer (1983), La Marca (1985), Lavilla (1987), Formas (1989), Caldwell and Myers (1990), Donnelly et al. (1990), Heyer et al. (1990), Mijares-Urrutia (1991), Myers et al. (1991), van Wijngaarden and Bolaños (1992), Rodríguez and Myers (1993), Haddad and Martins (1994), Juncá et al. (1994), Coloma (1995), Ibáñez and Smith (1995), La Marca (1996 “1994”), Mijares-Urrutia and La Marca (1997), Kaplan (1997), Lötters et al. (1997b), Grant and Castro-Herrera (1998), Faivovich (1998), Lindquist and Hetherington (1998), Lötters et al. (2000), Caldwell et al. (2002a), Caldwell and Lima (2003), Nuin (2003), and Castillo-Trenn (2004).

87. Larval Caudal Coloration: vertically striped  =  0; scattered melanophores clumped to form irregular blotches  =  1; evenly pigmented  =  2. Additive.

Caldwell et al. (2002a) figured the larvae of caeruleodactylus and marchesianus, the tails of which possess conspicuous, dark, broad, vertical stripes (state 0). The larval tails of the majority of species possess variable amounts of irregular, scattered melanophores clumped to form diffuse blotches, ranging from inconspicuous reticulation to large blotches (state 1). There is extensive ontogenetic and individual variation in the amount and intensity of this diffuse spotting, as documented for kingsburyi by Castillo-Trenn (2004), which prevented dividing the variation observed within this character-state into additional states. In some species, the larval tails are evenly pigmented brown, gray, or black (state 2).

88. Larval Oral Disc (fig. 61): “normal”  =  0; umbelliform  =  1; absent  =  2; suctorial  =  3. Nonadditive.

Figure 61

Character 88, larval oral disc.

A, B: Ventral (A) and lateral (B) views of State 0, “normal” (“Neblina species”, AMNH 118673). C, D: Ventral (C) and lateral (D) views of State 1, umbelliform disc (nubicola, AMNH 94849). Note also the submarginal papillae scattered over the surface of the oral disc (character 91).

As described by Haas (2003: 54), “[t]he oral disk is formed by the upper and lower lips, i.e., flat, more or less expansive flaps of skin set off from the mouth and jaws and commonly bearing labial ridges with keratodonts.” What is here referred to as the “normal” larval oral disc (state 0) consists of a thick, fleshy upper lip that is fully attached medially and lacks marginal papillae and a lower lip that is entirely free but relatively narrow and bears marginal papillae. The umbelliform (funnel-shaped) oral disc (state 1; fig. 61) is greatly enlarged relative to state 0. The upper lip is free and the marginal papillae extend around the entire circumference of the disc. Among dendrobatids, state 1 is known only in flotator, nubicola, and two unnamed species not included in this study. Dendrobatids that lack the oral disc (state 2) are endotrophic. The suctorial oral disc (state 3) is confined to the outgroup.

89. Lateral Indentation of Larval Oral Disc: absent (not emarginate)  =  0; present (emarginate)  =  1.

90. Marginal Papillae of Larval Oral Disc: short  =  0; enlarged  =  1; greatly enlarged  =  2. Additive.

The marginal papillae of most dendrobatids (e.g., boulengeri) are numerous (>50 in late stages) and relatively small (state 0).9 The marginal papillae of some species (e.g., pumilio) are fewer (<30 in late stages) and uniformly larger (state 1). For illustrations exemplifying this state, see Silverstone (1975a) and Haddad and Martins (1994). The remarkable larvae of caeruleodactylus and marchesianus possess only 12–18 (in late stages) greatly and irregularly enlarged marginal papillae (state 2). For illustrations of this state, see Caldwell et al. (2002a).

91. Submarginal Papillae of Larval Oral Disc (fig. 61): absent  =  0; present  =  1.

Among dendrobatids, submarginal papillae (see Altig and McDiarmid, 1999a) are known to occur only in larvae with umbelliform oral discs (e.g., nubicola). However, nondendrobatids that lack umbelliform discs also possess submarginal papillae (e.g., Duellmanohyla uranochroa; see Altig and McDiarmid, 1999b), demonstrating the transformational independence of these two characters.

92. Median Gap in Marginal Papillae of Lower Labium: absent  =  0; present  =  1.

Among dendrobatids, the median gap in the marginal papillae of the lower labium was illustrated and discussed by Myers and Daly (1980; see also 1987) and was claimed by them to be a synapomorphy for abditus, bombetes, and opisthomelas; Ruiz-Carranza and Ramírez-Pinilla (1992) added virolinensis to the group.

93. Anterior Larval keratodont Rows: 0  =  0; 1  =  1; 2  =  2. Additive.

Haddad and Martins (1994) reported the absence of anterior keratodont rows in hahneli, and we confirmed their observations in tadpoles of early stages. However, tadpoles of later stages possess a single anterior keratodont row, and we therefore coded this species as state 1. The unusual shape of the mouth, illustrated by Haddad and Martins, is retained until metamorphosis.

94. Posterior Larval keratodont Rows: 0  =  0; 1  =  1; 2  =  2; 3  =  3. Additive.

Haddad and Martins (1994) reported the absence of posterior keratodont rows in hahneli, and we confirmed their observations in small (e.g., stages 25 or 26) tadpoles. However, tadpoles of later stages possess two posterior keratodont rows, and we therefore coded this species as state 2.

95. Larval Jaw Sheath: absent  =  0; lower jaw only, not keratinized  =  1; entire, keratinized  =  2. Additive.

96. Larval Vent Tube Position: dextral  =  0; median  =  1.

Myers (1987) claimed the position of the larval vent tube among the differences between Minyobates and Dendrobates, with the former possessing the putatively primitive dextral position (state 0) and the latter being medial (state 1). Myers and Daly (1979) reported ontogenetic variation from dextral to median in silverstonei, and Donnelly et al. (1990) later reported that the vent tube of aurotaenia, lugubris, terribilis, and vittatus migrates from medial at Gosner (1960) stages 24 and 25 to dextral by stage 37 (or earlier). Caldwell and Myers (1990: 8) reported the frequency of dextral, sinistral, and median vent tubes in castaneoticus and summarized variation in this character and noted that “the rare sinistral condition [is] so far known only in the variation of the Dendrobates quinquevittatus complex.” Similar intraspecific variation has been reported in other anurans as well (e.g., Altig and McDiarmid, 1999a). Because ontogenetic series were unavailable for most dendrobatids, we coded the position of the larval vent tube as observed in the most developed larvae examined. As such, for example, we coded the vent tube of aurotaenia, lugubris, terribilis, and vittatus as dextral.

97. Spiracle: absent  =  0; present  =  1.

Among the coded dendrobatids, the unusual condition of the absence of the spiracle has been reported for only degranvillei (Lescure, 1984) and nidicola (Caldwell and Lima, 2003), both of which possess endotrophic larvae.

98. Lateral Line Stitches: absent  =  0; present  =  1.

The lateral line system is composed of receptor organs (mechanoreceptive neuromasts and electroreceptive ampullary organs) and the nerves that innervate them, both of which develop from the lateral line placodes (Schlosser, 2002a). Insofar as is known, the lateral line system is entirely lacking only in direct developing anurans, but the accessory organs (stitches) derived from the primary neuromasts fail to develop in some species of multiple families of anurans (Schlosser, 2002b). That is, the apparent absence of the lateral line system in these taxa is due to the absence of the stitches. The occurrence of stitches varies among dendrobatids, and we coded their absence (state 0) and presence (state 1). Only transverse stitches have been reported for anurans (Schlosser, 2002b), and dendrobatids are no exception.

Stitches have been reported (as the lateral line system), described, and/or illustrated by several authors (e.g., Mijares-Urrutia, 1991; La Marca, 1996 “1994”; Myers and Donnelly, 1997, 2001; Castillo-Trenn, 2004), but they are frequently overlooked, and their absence is usually not reported (e.g., Duellman, 2004). Although stitches are large and conspicuous in some species, they are barely detectable in others, owing to their small size and the pigmentation of the surrounding areas, so it is not safe to assume that failure to mention the lateral line stitches signifies their absence. As such, when coding character-states from the literature, we scored the lateral line stitches as absent when the authors were explicit or provided adequate illustrations or unusually thorough descriptions that (we assume) would have noted stitches had they been visible.

In addition to the presence and absence of stitches, we observed variation in the system of rami they form. However, as also observed by Castillo-Trenn (2004) in kingsburyi and R. W. McDiarmid (personal commun.) in other anurans, we found that the pattern of rami varies extensively within species, and too little is known about ramus ontogeny and other variation to allow transformation series to be delimited at present.

99–116. Behavior

The behavior of a number of dendrobatids has been documented and, beginning with Noble (1927), interpreted phylogenetically by several authors (e.g., Myers and Daly, 1976b; Weygoldt, 1987; Zimmermann and Zimmermann, 1988; Summers et al., 1999b). However, although behavior is unquestionably a valid source of evidence of phylogenetic relationships, its interpretation as phylogenetic characters requires special attention because particular behaviors are context dependent. Certain aspects of the behavioral repertory of a given species may be stereotyped and consistent across populations, but behavioral differences among populations have been documented (e.g., Myers and Daly, 1976b), and variation among individuals and over time (especially under different conditions) in the same individual are well known (especially in vocalizations; e.g., Juncá, 1998; Grant and Rodríguez, 2001), and the (external and/or internal) causes of this variation are, for the most part, a complete mystery. Even highly stereotyped responses may be context dependent, which casts some degree of doubt on the significance of observations made on captive specimens and the validity of comparisons to wild individuals. In light of these potential problems, we proposed hypotheses of homology of behaviors judiciously.

An example of overinterpretation of behavioral observations is Zimmermann and Zimmermann (1988), who performed a phenetic analysis of 62 variables (including vocalizations and larval morphology) for 32 species. We disregarded some of their “characters” because they are invariable in the ingroup and most of the outgroup (e.g., pulsation of flanks and/or throat; upright posture; female follows male; inflate body), defined too subjectively or arbitrarily to allow comparison (e.g., oviposition near a stream; male defends large territory, male defends small territory), demonstrably nonindependent (e.g., larvae carnivorous and/or herbivorous and larvae mostly herbivorous, microphagous), or are otherwise problematic. For example, their character “larvae carried singularly or in group” is problematic because, although differences almost certainly exist among species (bombetes has only been observed to carry up to three tadpoles [T. Grant, personal obs.; A. Suárez-Mayorga, personal commun.], whereas fraterdanieli carries up to at least 12 [T. Grant, personal obs.], and palmatus nurse frogs transport up to 31 tadpoles [Lüddecke, 2000 “1999”]), the number of dorsal tadpoles observed is highly variable (e.g., Myers and Daly, 1979: 326, reported a male silverstonei found carrying a single larva and two others carrying nine larvae; see also Lüddecke, 2000 “1999”: 315, table 3) due, potentially at least, to differences in clutch size, egg survivorship, rate of development, and the fact that a single load of tadpoles may be deposited all at once or one or a few at a time (Ruthven and Gaige, 1915). Clearly there are legitimate transformation series hidden in these observations, but more information is needed before characters can be delimited.

There is extensive missing data for behavioral characters, which necessarily limits the impact of these characters on the present analysis. However, one of our motivations for coding it nonetheless is that standardized codification facilitates future work. One of the most difficult aspects of individuating and scoring transformation series for phylogenetic analysis is that the behaviors are often complex and the ways they may be described by different observers may vary greatly. By delimiting and scoring these characters, we hope to draw attention to them for use in future comparative behavioral studies. Especially problematic are absences; for the present purposes, we coded conspicuous behaviors not reported in detailed studies as absent, but it is possible that they were simply not noticed. A similar problem is that even detailed notes may fail to mention expected observations, such as diurnal activity in dendrobatids. We did not make assumptions regarding the latter characters and only scored them from personal observation or explicit statements.

In addition to personal observations and unpublished field notes, behavioral data (not including vocalizations) were taken from the following published sources: Dunn (1933, 1941, 1944), Eaton (1941), Trapido (1953), Test (1954, 1956), Funkhouser (1956), Stebbins and Hendrickson (1959), Sexton (1960), Savage (1968, 2002), Duellman and Lynch (1969, 1988), Hoogmoed (1969), Mudrack (1969), Myers (1969, 1982, 1987), Edwards (1971), Lynch (1971), Crump (1972), Silverstone (1973, 1975a, 1975b,1976), Polder (1974), Durant and Dole (1975), Lescure (1975, 1976, 1991), Lüddecke (1976, 2000 “1999”), Wells (1978, 1980a, 1980b, 1980c), Myers et al. (1978, 1984), Myers and Daly (1976a, 1979, 1980, 1983), Cei (1980), Limerick (1980), Weygoldt (1980, 1987), Vigle and Miyata (1980), Zimmermann and Zimmermann (1981, 1984, 1985, 1988), Kneller (1982), Hardy (1983), Heyer (1983), Dixon and Rivero-Blanco (1985), Jungfer (1985, 1989), Frost (1986), Formas (1989), Summers (1989, 1990, 1992, 1999, 2000), Caldwell and Myers (1990), Praderio and Robinson (1990); Aichinger (1991), Morales (1992), van Wijngaarden and Bolaños (1992), Brust (1993), Duellman and Wild (1993), Giaretta et al. (1993), Rodríguez and Myers (1993), Juncá et al. (1994), Kaiser and Altig (1994), Coloma (1995), Cummins and Swan (1995), Jungfer et al. (1996a), La Marca (1996 “1994”, 1998 “1996”), Caldwell (1997), Fandiño et al. (1997), Grant et al. (1997), Caldwell and de Araújo (1998, 2004, 2005), Juncá (1998), Grant and Castro-Herrera (1998), Morales and Velazco (1998), Boistel and de Massary (1999), Caldwell and de Oliveira (1999), Haddad and Giaretta (1999), Hoff et al. (1999), Summers et al. (1999b), Köhler (2000), Kok (2000), Lescure and Marty (2000), Lötters et al. (2000), Bourne et al. (2001), Downie et al. (2001), Hödl and Amézquita (2001), Lima et al. (2001, 2002), Myers and Donnelly (2001), Summers and Symula, (2001), Caldwell and Lima (2003), Giaretta and Facure (2003, 2004), Lima and Keller (2003), Grant (2004), Lehtinen et al. (2004), Toledo et al. (2004), and Summers and McKeon (2004).

99. Advertisement Calls: buzz  =  0; chirp  =  1; trill  =  2; retarded trill  =  3. Nonadditive.

Male advertisement calls played an important role in the systematics studies of Myers and Daly (e.g., 1976b). For example, the histrionicus group of Myers et al. (1984) is delimited, in part, by a synapomorphic “chirp” call. Data are available for numerous species (for partial review, see Lötters et al., 2003b), but their use in systematics has been predicated on their identification as a buzz (Myers and Daly, 1976b: 225), chirp (Myers and Daly, 1976b: 226), trill (Myers et al., 1978: 325), retarded trill (Myers and Daly, 1979: 18), or retarded chirp (Myers and Burrowes, 1987: 16), and the diversity of dendrobatid calls extends far beyond these few types. Although Lötters et al. (2003b) aimed to expand and standardize the definitions of these calls, they were aware that known calls of most species of dendrobatids do not correspond to any of these types, and additional characterizations such as peeps, cricketlike chirps, croaks, whistled trills, or harsh peep train (e.g., Rodríguez and Myers, 1993; Grant and Castro-Herrera, 1998; Bourne et al., 2001) have been employed, although none of these is defined precisely.

It is clear that these call types are composites of temporal and spectral transformation series that should be decomposed into independent characters for phylogenetic analysis. Unfortunately, the necessary analysis of advertisement call variation was outside the scope of the present study, and we scored advertisement calls according to the published scheme in order to test prior hypotheses (e.g., the buzz call as a synapomorphy of the histrionicus group). This is highly suboptimal, mainly because (1) many species were scored as unknown simply because their calls did not fit within the current classification and not because data were unavailable, and (2) extensive information on spectral and temporal modulation could not be incorporated. We hope this may be rectified in future studies. Species were coded according to Lötters et al. (2003b).

100. Male Courtship: Stereotyped Strut: absent  =  0; present  =  1.

Dole and Durant (1974), Wells (1980a), and Lüddecke (2000 “1999”) reported the occurrence of this behavior (state 1) in collaris, panamensis (as inguinalis; see Grant, 2004), and palmatus, respectively. Lüddecke (2000 “1999”: 309, see also p. 210 for illustration) described it as “a stereotyped rigid-looking strut [the male] performs in the silent intervals between advertisement calls”.

101. Male Courtship: Jumping Up and Down: Absent  =  0; present  =  1.

Wells (1980c: 195) described this character as follows:

102. Female Courtship: Crouching: absent  =  0; present  =  1.

According to Lüddecke (2000 “1999”: 309), in this behavior the female crouches in front of, but does not slide underneath, the male.

103. Female Courtship: Sliding under Male: absent  =  0; present  =  1.

Lüddecke (2000 “1999”: 309) reported for palmatus that the female crouches and then “slides completely under the male” as one of the final stages of courtship.

104. Timing of Sperm Deposition: after oviposition  =  0; prior to oviposition  =  1.

In 1980 both Limerick (1980) and Weygoldt (1980) reported that sperm deposition in pumilio appears to occur prior to oviposition (state 1). This unusual occurrence has since been reported for additional species by several authors (Jungfer, 1985; Weygoldt, 1987; Jungfer et al., 1996a, 2000; Lötters et al., 2000). Jungfer et al. (1996a) claimed this as a synapomorphy of Dendrobates and rationale for placing Minyobates in its synonymy, as done subsequently by Jungfer et al. (2000). Nevertheless, several species of Dendrobates sensu Jungfer et al. have been explicitly reported to have post-oviposition fertilization (e.g., histrionicus fide Zimmermann, 1990: 69; arboreus fide Myers et al., 1984: 15), which suggests that the phylogenetic interpretation of this character is not as straightforward as Jungfer et al. implied.

105. Reproductive Amplexus (fig. 62): absent  =  0; axillary  =  1; cephalic  =  2. Nonadditive.

Figure 62

Character 105, reproductive amplexus.

State 2, cephalic amplexus (anthonyi, AMNH live exhibit) shown in anterior (A) and lateral (B) aspects.

Myers et al. (1978: 324–325) first described and illustrated cephalic amplexus in tricolor. Although reproductive amplexus is absent in numerous dendrobatids (a variety of pseudo-amplectant positions–including cephalic grasping–may be employed in aggressive and/or courtship behavior), cephalic amplexus was cited by numerous authors (e.g., Duellman and Trueb, 1986; Myers and Ford, 1986; Myers et al., 1991) as a dendrobatid synapomorphy, with the absence in numerous dendrobatids explained as a derived loss. A similar amplectant position was reported for Hypsiboas faber by Martins and Haddad (1988), but the sampled outgroup species exhibit axillary amplexus.

106. Cloacal Apposition: absent  =  0; present  =  1.

Crump (1972: 197) first reported the occurrence of this character-state in granuliferus, in which the male and female face opposite directions and bring their cloacae into contact.

107. Egg Deposition Site: aquatic  =  0; terrestrial: leaf litter, soil, under stones  =  1; terrestrial: phytotelmata  =  2. Additive.

This character is coded additively to reflect the increasing or decreasing degree of association with ground-level standing or flowing water.

108. Egg Clutch Attendance: none  =  0; male  =  1; female  =  2; both  =  3. Nonadditive.

See discussion of sex of nurse frog (Character 110, below) for the rationale behind treating biparental care as a separate state instead of polymorphism.

109. Dorsal Tadpole Transport (fig. 63): absent  =  0; present  =  1.

Figure 63

Character 109, dorsal larval transport.

State 1, present (fraterdanieli, specimens at UVC). This male nurse frog was transporting 12 tadpoles.

Noble (1927: 103) noted that his grouping of dendrobatids on morphological grounds “receives an eloquent support from life history data” as well, pointing out that males of species of Dendrobates and Phyllobates transport tadpoles on their back to pools (state 1), and, further, that “[n]o other Salientia have breeding habits exactly like Dendrobates and Phyllobates” (p. 104). For the present purposes, we refer only to dorsal transport by genetic parents (see below), and we follow Ruthven and Gaige (1915: 3) in referring to the parent that performs larval transport as the nurse frog.

Among outgroup taxa, males of Rhinoderma darwinii transport larvae, which Laurent (1942: 18) claimed as evidence of close relationship to dendrobatids. However, male Rhinoderma transport young in their hypertrophied vocal sacs (see Noble, 1931: 71 for illustration), whereas dendrobatids transport tadpoles on their backs. Several other anurans transport their young on their backs (e.g., Hemiphractus, Stefania, Gastrotheca), but they do so beginning with the egg clutch, whereas in dendrobatids transport is exclusively post-hatching. Among Neotropical anurans, the only species reported to have terrestrial (nontransported) eggs and dorsally transported tadpoles is Cycloramphus stejnegeri (Heyer and Crombie, 1979). Tadpole transport is not known for the sampled species of Cycloramphus (C. boraceiensis), but Giaretta and Facure (2003) reported male egg attendance (also present in C. dubius and C. juimiria; C.F.B. Haddad, personal obs.), which leaves open the possibility of tadpole transport. Outside of the Neotropics, apparently identical parental care occurs in the dicroglossids Limnonectes finchi and L. palavanensis (Inger and Voris, 1988) and the sooglossid Sooglossus sechellensis (Lehtinen and Nussbaum, 2003). In the hemisotid Hemisus marmoratus, maternal tadpole transport may occur as the female digs a subterranean tunnel to a water body (Lehtinen and Nussbaum, 2003).

Dorsal tadpole transport by parents is here coded as a single transformation series, but even the extremely limited evidence available suggests this is much more complex and probably involves multiple characters. Stebbins and Hendrickson (1959: 509) reported in subpunctatus that “[t]he tadpoles are anchored to the back of the frog by a sticky mucus.” Myers and Daly (1980: 19) further noted that

To this we add only that it is common for tadpoles to wriggle around freely on the nurse frog's back without being prodded (especially if few tadpoles are being transported by a large frog, such as bicolor), giving the impression that they adjust themselves to the nurse frog's movements.

Ruiz-Carranza and Ramírez-Pinilla (1992) studied the histology of the contact surfaces of nurse frogs and transported tadpoles in virolinensis and found numerous modifications in both the dorsal integument of the nurse frog and the ventral integument of the larvae. Lüddecke (2000 “1999”) found experimentally that recently hatched larvae of palmatus did not mount a rubber model moistened with water, mounted but immediately abandoned a rubber model treated with either male or female skin secretions, and would only mount and settle on a live frog, with no sexual discrimination. In a less controlled experiment with hatching anthonyi T. Grant found that gently touching the jelly capsule with a finger was sufficient to stimulate hatching, immediate mounting, settling, and attachment (i.e., the tadpoles remained attached to the finger submerged in water for >1 min until they were forcibly dislodged); however, the male nurse frog had already removed most of the tadpoles from the clutch, which may have “primed” the remaining embryos for hatching and transport. As coded in Character 110, the sex of the nurse frog varies among species, and little is known about the biology of this kind of sex role reversal. Much more research is required to understand the evolution of dorsal tadpole transport in dendrobatids.

110. Sex of Nurse Frog: male  =  0; female  =  1; both  =  2. Nonadditive.

Among species that transport larvae, the role of the nurse frog is typically assumed by one sex (Wells, 1978, 1980a, 1980b, 1980c). However, in some species, both sexes have been observed carrying tadpoles. Myers and Daly (1983) found experimentally that in anthonyi (as tricolor) the father was normally responsible for tadpole transport and would actively prevent the mother from approaching the developing clutch, but that removal of the male shortly after breeding led to female brood care and larval transport. They suggested that parental care is competitive, that is, the sexes compete to care for the offspring. This is at least consistent with Aichinger's (1991) observation of 38 male nurse frogs and only a single female nurse frog. Caldwell and de Araújo (2005) reported that in brunneus and femoralis males usually transport larvae but females will occasionally perform this role, and Silverstone (1976: 38) reported nurse frogs of both sexes for petersi. It is unknown how widespread this behavior is (i.e., if both sexes are usually potential carriers, even though one sex predominantly assumes this role, as in tricolor), but it is not universal. It is unknown how widespread this behavior is (i.e., if both sexes are usually potential carriers, even though one sex predominantly assumes this role, as in tricolor), but it is not universal. Host Lüddecke (in litt., 08/31/00) found experimentally that palmatus does not exhibit this behavior; in his experiments, Lüddecke found that mothers ate their eggs when the fathers were removed. As noted for Character 108, Lüddecke (2000 “1999”) also found that tadpoles mounted males or females indiscriminately, which suggests that a potential for female transport may be primitive.

Given the paucity of experimental data, it is unclear if all cases of both sexes transporting tadpoles are the result of the same mechanism and/or a transformation event. For the time being, we coded each species based on available information. We have therefore scored species as having males (state 0), females (state 1), or both sexes (state 2) assume the role of nurse frog. This character individuation will undoubtedly require modification as more data are obtained on this behavior.

We coded biparental transport as a separate state rather than an ambiguous polymorphism because the behavioral modifications required to achieve biparental care do not apply to male or female care alone, that is, it involves more than just the co-occurrence of states 1 and 2. Also, we did not specify any particular additivity for this transformation series, as there is no evidence that the shift between sexes requires a cooperative (or competitive) intermediate biparental stage (although this could be indicated by phylogenetic analysis).

Savage (2002) reported male nurse frogs in talamancae, and Summers and McKeon (2004: 62, fig. 3) scored femoralis, hahneli (as “hahnei”), talamancae, and trilineatus (as “trilieatus”) as having exclusively male parental care. However, nurse frogs of both sexes have been reported for femoralis (Silverstone, 1976; Lescure, 1976; for a recent report see Caldwell and de Araújo, 2005), hahneli (as pictus; Aichinger, 1991) and trilineatus (Aichinger, 1991), and exclusively female nurse frogs have been reported for talamancae (Grant, 2004 and references therein). Insofar as Savage and Summers and McKeon did not dispute those reports or provide specimen documentation for confirmation, we dismiss their reports as erroneous.

Adding to the behavioral complexity and the difficulty in coding this character, Weygoldt (1980) found in pumilio that mothers transport their larvae to water, whereas males may perform nonparental infanticide by transporting unelated tadpoles and not depositing them in water, thus achieving sexual interference. As noted above, we did not score nonparental transport as part of this transformation series.

111. Larval Habitat: ground level pool or slow-flowing stream or other body of water  =  0; phytotelmata  =  1; nidicolous  =  2. Nonadditive.

Note that there is a logical dependency between larval habitat and dorsal tadpole transport (Character 108) in that nidicolous larvae are, by definition (Altig and Johnston, 1989; McDiarmid and Altig, 1999), not transported. Nevertheless, the two characters are not coextensive and are clearly independent: Lack of transport may also be associated with either state, and nurse frogs may transport larvae to either a ground level body of water or phytotelm.

Although “phytotelm” often refers to chambers above ground (e.g., bromeliads), technically the term applies to any chambers in a plant. Moreover, whether on or above the ground, these phytotelmata are expected to be biologically equivalent (e.g., both microhabitats offer limited space, nutrients, and other resources, and have a potentially high risk of predation), and we therefore did not discriminate between ground-level and higher phytotelmata. For example, we followed Caldwell and de Araújo (1998; 2004) in scoring castaneoticus as a phytotelm breeder because it uses Brazil nut husks.

112. Larval Diet: detritivorous  =  0; predaceous  =  1; oophagous  =  2; endotrophic  =  3. Nonadditive.

The vast majority of anurans have detritivorous tadpoles (state 0). We assumed that larvae found in ground level pools or streams or other large bodies of water (i.e., state 0 of Character 111) are detritivorous; unless diet is actually known, larvae of other habitats were coded as unknown (“?”) for this character. Numerous species of dendrobatids are aggressive predators that consume con- and heterospecific tadpoles and arthropod larvae as an important component of their diet (Caldwell and de Araújo, 1998; state 1). Several species consume sibling oocytes (oophagous, state 2), either exclusively (histrionicus group; Limerick, 1980) or as part of a predaceous diet (state 1; e.g., vanzolinii; Caldwell and de Oliveira, 1999). We coded the latter taxa as polymorphic (see also Character 113, provisioning of oocytes for larval oophagy).

Four species with endotrophic larvae (state 3) have been described: chalcopis (not included in this study), degranvillei, nidicola, and stepheni (for review and description of nidicola see Caldwell and Lima, 2003). Some amount of larval growth prior to deposition (e.g., during transport; Wells, 1980b) is probably widespread, but complete endotrophy is much more limited and tends to be correlated with a variably reduced morphology. Nevertheless, the unmodified larva of chalcopis (Kaiser and Altig, 1994) demonstrates the transformational independence of endotrophy and the various morphological reductions (see also Altig and Johnston, 1989). Likewise, the occurrence of endotrophy is independent of tadpole habitat: degranvillei is transported (Lescure and Marty, 2000; tadpole transport was also predicted for chalcopis by Juncá et al., 1994), whereas the remaining endotrophic tadpoles are nidicolous.

113. Provisioning of Oocytes for Larval Oophagy: biparental  =  0; female only  =  1.

Caldwell and de Oliveira (1999) reported provisioning of eggs for consumption by sibling tadpoles in vanzolinii, as did Bourne et al. (2001) in beebei. In these species, egg provisioning is stimulated by male courtship behavior and is therefore biparental (state 0), and larval diets include a variety of foods (for additional records, see Lehtinen et al., 2004). In other oophagous species (e.g., histrionicus) tadpole care is undertaken exclusively by the female. An alternative way to delimit state 1 is as obligate oophagy, as it appears that tadpoles of these species feed only on eggs (obligate oophagy demonstrated experimentally for pumilio by Brust, 1993; Pramuk and Hiler, 1999), whereas the others are predaceous (Caldwell and de Araújo, 1998).

Zimmermann and Zimmermann (1988) reported biparental provision of oocytes in ventrimaculatus (as quinquevittatus) in captivity, but Summers et al. (1999b) reported exclusively male care in Peruvian ventrimaculatus. Caldwell and Myers (1990) hypothesized that ventrimaculatus is a complex of cryptic species, which is supported by this behavioral variation.

114. Adult Association with Water: aquatic  =  0; riparian (<3 m from water)  =  1; independent of water (up to ca. 30 m from water)  =  2. Additive.

Myers et al. (1991) characterized nocturnus as aquatic, which they contrasted with species such as panamensis (as inguinalis; see Grant, 2004) and latinasus, which are riparian and independent of streams, respectively. Postmetamorphic frogs of any species may be found in or near water, and environmental variation must be taken into account (i.e., during dry seasons or at drier localities frogs that are otherwise found well into the forest will congregate near sources of water), but the degree of commitment to or dependency on an aquatic environment segregates dendrobatids into at least three groups. Among dendrobatids, nocturnus appears to be the only aquatic species, that is, individuals are generally found immersed in water (state 0). A much greater number of dendrobatids are riparian (state 1). These species are almost entirely confined to the areas immediately adjacent to streams, where they establish and defend streamside territories (e.g., Wells, 1980a, 1980c). When disturbed these species seek refuge in water and not in leaf litter or debris beside the stream. The third group of species is effectively independent of water (state 3). As noted by Funkhouser (1956: 78) for espinosai, these species “scurry under debris for safety; they do not take to water even when it is close by”, and territorial and courtship behaviors occur well away from ground water. Despite their relative independence from water, the density of these frogs may be greater nearer to streams, even in extremely wet environments such as the Colombian Chocó (T. Grant, personal obs.) where general moisture requirements are unlikely to be a limiting factor. This is probably due to reproductive factors: Many of these species are known to transport larvae from terrestrial nests to streams or ground-level pools, and it is predictable that selection would favor preference for sites closer to more permanent, larger bodies of water.

A potential fourth character-state is arboreality. For example, Myers et al. (1984) named arboreus in recognition of that species' arboreal habitat preference, whereas other species (e.g., fraterdanieli) are active exclusively on the ground and only climb into vegetation (never more than 1 m) to sleep. However, between these two extremes lie variations that defy simple codification. For example, bombetes is a leaf-litter frog that climbs up to 30 m above ground to deposit larvae in bromeliads (T. Grant, personal obs.; A. Suárez-Mayorga, personal commun.). Similarly, histrionicus forages in leaf litter on the ground but calls from perches in vegetation above ground (Silverstone, 1973; Myers and Daly, 1976b). Clearly there are evolutionary transformation events embedded in these behavioral variations, but the extent to which variation is obligate or facultative is unclear, and we have chosen to group putatively arboreal and terrestrial species as state 2. Assuming the additivity of this transformation series, the transformation from state 1 to state 2 applies to all of these species (as coded), and we have failed to recognize the additional transformation(s) from state 2a (terrestrial) to state 2b (arboreal).

115. Diel Activity: nocturnal  =  0; diurnal  =  1.

Myers et al. (1991) cited the transformation from nocturnal to diurnal activity as evidence for the monophyly of all dendrobatids minus nocturnus. As has been noted by several authors (e.g., Myers et al., 1991; Coloma, 1995; Duellman, 2004), some other species (e.g., riveroi, bocagei, nexipus) exhibit crepuscular or limited nocturnal activity, at least facultatively (e.g., on brightly moonlit nights). Although the conditions that surround this behavior are unclear, we coded these species as polymorphic.

116. Toe Trembling: absent  =  0; present  =  1.

We have observed several species to exhibit toe trembling or toe tapping, whereby usually the fourth toe (sometimes also the third) trembles or twitches rapidly up and down. Little is known about this behavior. Most observations derive from captive individuals, and there is no known function. It does not appear to be involved in intraspecific visual communication, as individuals do not alter their behavior notably when an individual begins toe trembling, and toe trembling may be observed in individuals that are isolated or in groups. Toe trembling is not continuous and only occurs in active frogs. However, although quantitative data are lacking, onset and/or vigor of toe trembling in dendrobatids does not seem to correlate with any particular stimulus and does not obviously originate as an epiphenomenon (Hödl and Amézquita, 2001). Toe trembling may (or may not) occur while foraging and during inter- and intraspecific interactions with individuals of the same or opposite sex. Hartmann et al. (2005) reported toe (and finger) trembling for the hylid Hyspiboas albomarginatus, which they interpreted to be visual signaling.

117. Hyale Anterior Process: absent  =  0; present  =  1.

All dendrobatids examined possess a single anterior process on each hyale (state 1), and it is both present and absent (state 0) in the sampled outgroup species. Myers and Ford (1986) cited the occurrence of a second anterior process on the hyalia of Atopophrynus syntomopus as evidence that it is not a dendrobatid; we did not sample this taxon in the present study and therefore did not test their hypothesis.

118. Shape of Terminal Phalanges: T-shaped  =  0; knobbed  =  1.

Following Lynch's (1971) terminology, the species sampled in this study possess T-shaped and knobbed phalanges.

119–128. Epicoracoids

Pectoral girdle architecture has been key in all discussions of dendrobatid relationships since Boulenger (1882). Character-states have generally been delimited in terms of the overlap or fusion of the epicoracoids and/or the presence or absence of epicoracoid horns (for historical usages, see Kaplan, 2004), with the epicoracoids of dendrobatids characterized as entirely fused and nonoverlapping and lacking epicoracoid horns, as in “firmisternal” taxa.10 However, this is clearly an oversimplification (e.g., Noble, 1926; Kaplan, 1994, 1995, 2000, 2001, 2004). Recently, Kaplan (2004) divided girdle architecture variants into separate transformation series relating to degree of fusion (freedom) and overlap (nonoverlap), and he proposed explicit character-states, which we employ here.

Of most relevance to the problem of dendrobatid phylogeny, Noble (1926) claimed that the entirely fused epicoracoids of subpunctatus overlap during ontogeny, a finding that was challenged by Griffiths (1959), Lynch (1971a), and Ford (1989), but ultimately vindicated by Kaplan (1995). However, Kaplan (1995) interpreted differences between the overlap in subpunctatus and “arciferal” taxa (e.g., Bufo) as evidence that the overlap is nonhomologous and therefore not evidence of common ancestry (contra Noble, 1926).

To date, the only dendrobatid in which overlap has been detected is subpunctatus. Kaplan (1995: 302) also examined abditaurantius (adult), palmatus (adult), and virolinensis (Gosner, 1960, stages 42–43) and “did not find any evidence of overlap”, and Griffiths (1959) reported that overlap is absent in trinitatis (not trivittatus, as reported by Kaplan, 1995).

Although we did not perform the detailed histology necesary to score these characters precisely, epicoracoid morphology has played an important role in all previous discussions of dendrobatid phylogeny and we believe it would be inappropriate to exclude it altogether. Therefore, although we are cognizant of the potential errors that may be incorporated into the analysis, we coded degree of fusion and overlap in adults (or near adults) as precisely as possible through examination of cleared and stained whole specimens. Although Kaplan (1995: 301) stated that in subpunctatus “the girdle halves overlap in adults except for a small area of ventral fusion”, this was not visible in cleared and stained specimens, and so for consistency we coded this species as lacking overlap. Insofar as we did not detect overlap in any other dendrobatid, and Kaplan (1995) argued that overlap in subpunctatus is nonhomologous with the overlap of “arciferal” taxa, coding the occurrence of overlap in this taxon would result in an autapomorphy and therefore would not affect the results of the present analysis.

119. Epicoracoid Fusion: fused from anterior tips to posterior tips  =  0; fused from anterior tips of epicoracoids to level midway between the posterior levels of the procoracoids and the anterior ends of the coracoids, free posteriorly  =  1; fused from anterior tips to a level slightly posterior to medial ends of clavicles, free posteriorly  =  2. Additive.

States 0, 1, and 2 correspond to states E, C, and A, respectively, of Kaplan (2004: 94). State 1 is intermediate in the degree of fusion, which we considered to be evidence for the hypothesis of 0 ↔ 1 ↔ 2 additivity for this transformation series.

120. Epicoracoid Overlap: nonoverlapping  =  0; overlapping from level slightly posterior to level of procoracoids to anterior level of sternum  =  1; overlapping from level between posterior level of procoracoids and anterior ends of coracoids to posterior level of coracoids  =  2; overlapping from level slightly posterior to medial ends of clavicle to level slightly posterior to anterior level of sternum  =  3. Nonadditive.

States 0, 1, 2, and 3 correspond to states B, E, C, and A, respectively, of Kaplan (2004: 94). Because variation in overlap involves complex changes in epicoracoid structure, we were unable to find evidence to select one hypothesis of additivity over another; we therefore treated this character nonadditively.

121. Angle of Clavicles (fig. 64): directed laterally  =  0; directed posteriorly  =  1; directed anteriorly  =  2. Nonadditive.

Figure 64

Character 121, angle of clavicles.

A: State 0, directed laterad (steyermarki, AMNH 118572). B: State 1, directed anteriad, approximately parallel to the posterior margin of the coracoid (opisthomelas, AMNH 102582). C: State 2, directed anteriad (Eupsophus roseus, KU 207501).

In most dendrobatids each clavicle runs laterad, perpendicular to the sagittal plane (state 0). In some species, the clavicles are directed posteriad, running approximately parallel to the posterior margin of the coracoid (state 1). Clavicles directed anteriad (state 2) are confined to certain species in the outgroup. The intermediacy of the laterally directed clavicles is suggestive of additivity; however, pectoral girdle ontogeny does not proceed in this way, and we therefore scored this transformation series nonadditively.

122. Acromion Process: cartilaginous, distinct  =  0; fully calcified (or ossified), continuous with clavicle and scapula  =  1.

The acromion processes of some taxa are cartilaginous (state 0) in mature specimens, whereas in others they are extensively calcified or ossified (state 1). We did not distinguish between extensive calcification and ossification. As with other osteological characters that vary ontogenetically (characters 127, 134–138), adult females are most extensively ossified.

123. Prezonal Element (Omosternum): absent  =  0; present  =  1.

124. Prezonal Element (Omosternum) Anterior Expansion: not expanded distally, tapering to tip  =  0; weakly expanded, to 2.5× style at base of cartilage or equivalent  =  1; extensively expanded distally, 3.5× style or greater  =  2. Additive.

125. Prezonal Element (Omosternum) Shape of Anterior Terminus: rounded or irregularly shaped  =  0; distinctly bifid  =  1.

126. Prezonal Element (Omosternum) Shape of Posterior Terminus: simple  =  0; notched, forming two struts  =  1; continuous with epicoracoid cartilage  =  2. Nonadditive.

127. Prezonal Element (Omosternun) Ossification: entirely cartilaginous  =  0; medially ossified (cartilaginous base and tip)  =  1; basally ossified (cartilaginous tip)  =  2; entirely ossified  =  3. Additive.

128. Suprascapula Anterior Projection: cartilaginous  =  0; heavily calcified  =  1.

129. Sternum Shape: simple (rounded, irregular)  =  0; medially divided  =  1.

The posterior termination of the sternum is either simple (rounded or irregularly shaped; state 0) or distinctly divided medially, forming either two prongs or two broad, rounded lobes. We also observed independent variation in the lateral expansion of the sternum. For example, even though the sternum of both species is medially divided, in panamensis (UMMZ 167459) it is broadly expanded, whereas in juanii (ICN 5097) the sternum is tapered. However, we also observed confounding intermediate and other variation and were unable to individuate states objectively for the current study.

130. Zygomatic Ramus of Squamosal (fig. 65): elongate, slender, pointed  =  0; very long and slender  =  1; robust, truncate, and elongate  =  2; shorter and less robust but still well defined  =  3; well defined, moderate length, abruptly directed ventrad  =  4; inconspicuous, poorly differentiated  =  5; very small, inconspicuous, hooklike  =  6; miniscule bump  =  7; robust, elongate, in broad contact with the maxilla  =  8. Nonadditive.

Figure 65

Character 130, zygomatic ramus of squamosal.

A: State 0 (Eupsophus roseus, KU 207501). B: State 1 (Cycloramphus fuliginosus, KU 92789). C: State 2 (nocturnus, AMNH 130041). D: State 2 shown in a dissected whole specimen (palmatus, AMNH 20436). E: State 3 (trinitatis, AMNH 118389). F: State 4 (trivittatus, AMNH 118428). G: State 5 (espinosai, AMNH 118417). H: State 6 (bocagei, UMMZ 182465). I: State 7 (Melanophryniscus stelzneri, AMNH 77710). J: State 8 (Megaelosia goeldii, AMNH 103952; squamosal colored red).

The zygomatic ramus of the squamosal varies extensively and forms a series of complex morphological transformations. In state 0, the zygomatic ramus is elongate (approximately half the length of the ascending ramus and extending well anterior past the tympanic ring), slender, gently curved, and pointed. State 1 is a very long and slender process. State 2 is robust, truncate, and elongate (extending anterior to the tympanic ring, but not as long as state 2). State 3 is shorter and less robust than state 2 but is still a conspicuous shaft that usually extends anterior to the tympanic ring. Like the processes of states 0, 1, and 2, the axis of state 3 is at most only weakly inclined toward the maxilla. The zygomatic ramus of state 4 is also well defined, but it is distinctly and abruptly directed ventrad, its axis pointing almost straight down at the maxilla, that is, a line from the zygomatic ramus would intersect the posterior extreme of maxilla, and it does not extend anterior to the tympanic ring. State 5 is an inconspicuous, poorly differentiated process. The zygomatic ramus of most of the sampled species is a very small, inconspicuous, hooklike process (state 6). McDiarmid (1971) considered the zygomatic ramus to be absent in Melanophryniscus; however, we detected a miniscule bump (state 7) in Melanophryniscus stelzneri, which we considered to be homologous with the zygomatic ramus. (Regardless, we did not observe this state in any other species included in the present analysis, so coding it as “absent” or “a miniscule bump” has no bearing on the outcome of analysis.) In Megaelosia goeldii, the robust zygomatic ramus extends anteroventrad to be in broad contact with the maxilla (state 8).

131. Orientation of Alary Process of Premaxilla: directed anterolaterally  =  0; directed dorsally  =  1; directed posterodorsally  =  2. Additive.

Myers and Ford (1986) claimed the anterolaterally tilted alary process as a synapomorphy of dendrobatids, although several other taxa also share this state (e.g., Lynch, 1971). We treated this transformation series additively (0 ↔ 1 ↔ 2) based on the argument that the rearrangement in skull architecture required to alter the orientation of the alary process would necessitate passing through the intermediate stage.

132. Palatines: absent  =  0; present  =  1.

Variation in the occurrence of the palatine bones among dendrobatids has been documented by numerous authors (e.g., Silverstone, 1975a; Myers and Ford, 1986), and Kaplan (1997) interpreted the character phylogenetically. Trueb (1993) considered the neobatrachian palatine to be nonhomologous with the palatine of other vertebrates, and she is almost certainly correct. Nevertheless, this bone would unquestionably be identified as a palatine if anurans were found to be rooted on a neobatrachian. As such, the validity of Trueb's distinction rests on the phylogenetic position of neobatrachians, that is, it is a conclusion of phylogenetic analysis, not a premise. We therefore follow Haas (2003) in referring to this bone as the palatine.

133. Quadratojugal–Maxilla Relation: overlapping  =  0; separated  =  1.

In dendrobatids, the quadratojugal and maxilla are never in contact or tightly bound but are instead loosely bound by ligamentous tissue. In some species, the two bones overlap (state 0), whereas in others the anterior tip of the quadratojugal does not reach the level of the posterior tip of the maxilla.

134. Nasal–Maxilla Relation (fig. 66): separated  =  0; in contact  =  1.

Figure 66

Character 134, nasal–maxilla relation.

A: State 0, nasal and maxilla broadly separated (silverstonei, AMNH 91847). B: State 1, greater magnification showing nasal and maxilla overlapping or fused (bassleri, AMNH 43402).

The nasal and maxilla may be separate (state 0) or contact each other. We did not distinguish between overlap and fusion because gross examination under a dissecting microscope proved inadequate to determine the status of many specimens and the necessary histological study was infeasible for the present study.

135. Nasal–Sphenethmoid Relation (fig. 67): free, separate  =  0; overlapping or fused  =  1.

Figure 67

Character 135, nasal–sphenethmoid relation.

A: State 0, separate (bassleri, AMNH 43402). B: State 1, overlapping or fused (nocturnus, AMNH 130014). In this case the nasals clearly overlap but are not fused with the sphenethmoid, but in other species the distinction between the bones is not as clear.

In state 0, the nasal and sphenethmoid do not overlap, whereas in state 1 those bones are either overlapping or fused. We did not distinguish between overlapping and fusion as the necessary histological analysis was infeasible for the present study.

136. Frontoparietal Fusion: entirely free  =  0; fused posteriorly  =  1; fused along entire length  =  2. Additive.

Ontogenetic variation in frontoparietal fusion suggests that it proceeds anteriorly. We therefore treated this character additively.

137. Frontoparietal–Otoccipital Relation: free  =  0; fused  =  1.

Among dendrobatids, there is variation in the relation of the frontoparietal and otoccipital (i.e., the fused prootic and exoccipital; Lynch, 1971: 52), being free (state 0) in some taxa and fused (state 1) in others. Lynch (1971) documented variation in this character in numerous outgroup taxa.

138. Exoccipitals: free, separate  =  0; fused sagittally  =  1.

The exoccipital portions of the fused otoccipital bones (see Lynch, 1971: 52) may be separated by cartilage (i.e., chondrocranial ossification may be incomplete; state 0) or may be fused sagittally (state 1). A further potential state is for them to abut but not fuse, but we did not observe this among the specimens examined.

139. Maxillary Teeth: absent  =  0; present  =  1.

Variation in the occurrence of teeth has been used consistently in dendrobatid systematics (see Grant et al., 1997 for discussion). In the more recent literature, Edwards (1971: 147) stated that dendrobatids “can be divided into two groups—those species lacking maxillary teeth (Dendrobates) and those having maxillary teeth (Phyllobates and Colostethus).” Silverstone (1975a) showed that the situation is more complicated due to character conflict and polymorphism. (See also Materials and Methods for uncoded variation in maxillary tooth size and shape.)

140. Maxillary Tooth Structure: pedicellate  =  0; nonpedicellate  =  1.

Most anurans have pedicellate teeth, whereby the tooth is divided into a pedicel and crown (Parsons and Williams, 1962). Parsons and Williams (1962: 377) examined the teeth of bocagei (as Phyllobates bocagii) and palmatus (as Phyllobates granuliventris) and found that “the division is certainly not marked in gross structure and is quite probably lacking.” Myers et al. (1991: 11) further pointed out that there is no “pattern of physical separation of crowns from pedicels (breakage is irregular)”, and that “the loss or significant obfuscation of the usual amphibian pedicellate condition warrants attention as a possible synapomorphy for the Dendrobatidae.” We coded tooth structure from gross examination of cleared and stained specimens only, although histological study is required to address this problem decisively.

141. Vomerine Teeth: absent  =  0; present  =  1.

142. Retroarticular Process of Mandible (fig. 68): absent  =  0; present  =  1.

Figure 68

Length variation in character 142, retroarticular process of the mandible.

A: nocturnus, AMNH 130041. B: riveroi, AMNH 134142. C: vittatus, AMNH 118386. D: lehmanni Myers and Daly, AMNH118442. E: pratti, AMNH118364. F: “Neblina species”, AMNH 118667.

Myers and Ford (1986) noted the occurrence of a retroarticular process on the mandible as a distinguishing characteristic of dendrobatids, and Ford and Cannatella (1993) listed it as one of two unique synapomorphies. Although many dendrobatids are characterized by conspicuously elongate retroarticular processes, Myers et al. (1991: 11) noted that in nocturnus the process is “present, but always short (compared with other dendrobatids) although somewhat variable in length.” As shown in figure 68, there is considerable interspecific variation in the length of the retroarticular process. However, we were unable to delimit states, in part because no clear choice for a standard reference point has been identified.

143. Expansion of Sacral Diapophyses (fig. 69): unexpanded  =  0; moderately expanded  =  1; strongly expanded  =  2. Additive.

Figure 69

Character 143, expansion of sacral diapophyses.

A: State 0, unexpanded (riveroi, AMNH 134143l). B: State 1, moderately expanded (pumilio, AMNH 118514). C: State 2, greatly expanded (Melanophryniscus stelzneri, AMNH 77710).

The shape of the sacral diapophyses has been used since Boulenger (1882). Ford (1989) mistakenly cited Duellman and Trueb (1986) as having placed Dendrobatidae among ranoids based in part on their sharing round-shaped sacral diapophyses (Duellman and Trueb did not include that character in their matrix), but it has, nonetheless, played an important role in anuran systematics.

The state found in dendrobatids has usually been referred to as round or cylindrical (e.g., Duellman and Trueb, 1986), but the sacral diapophyses are invariably elliptical in cross section. For this reason we refer instead to the degree of expansion of the sacral diapophyses. Emerson (1982) quantified expansion by measuring the angle formed by the expansion. Here we code this character as the ratio of the width of the tip of the diapophysis to the width of the base of the diapophysis. Variation is not continuous; all states are separated by gaps. Unexpanded diapophyses are subequal at the base and tip. Moderately expanded diapophyses are 1.5–2.5 times wider at the tip than at the base; greatly expanded diapophyses are at least 2.7 times greater at the tip. Sacral diapophyses often bear irregular flanges that we did not include in the measurement of width.

144–146. Vertebral Fusion

Noble (1922: 15) reported fusion of vertebrae 2 + 3 and 8 + 9 (i.e., 8 + sacrum) in two species of dendrobatids (pumilio [as Dendrobates typographicus] and probably histrionicus or sylvaticus Funkhouser [discussed under the tentative name Dendrobates tinctorius]). Silverstone (1975a: 5) summarized his observations of vertebral fusion in dendrobatids as “absent in the 17 specimens of Colostethus examined, present in only two of the 29 specimens of Phyllobates examined, and present in 28 of the 46 specimens of Dendrobates examined.” He also noted that vertebral fusion varies intraspecifically, and we also found intraspecific variation among equivalent semaphoronts.

144. Vertebra 8 and Sacrum: free  =  0; fused  =  1.

145. Vertebrae 1 and 2: free  =  0; fused  =  1.

Myers et al (1991:11) reported ventral fusion of vertebrae 1 and 2 in nocturnus (AMNH 130047); however, close examination showed that the vertebrae are tighly bound by ligamentous tissue but are not fused.

146. Vertebrae 2 and 3: free  =  0; fused  =  1.

147–172. Alkaloid Profiles

Dendrobatid frogs are known to possess a diverse array of over 450 alkaloids (Daly et al., 1999; J. W. Daly, in litt., 01/25/05). Use of alkaloid profiles as transformation series is complicated, in part, because it appears that “some, if not all … ‘dendrobatid alkaloids’ may have a dietary origin” (Daly et al., 1994a; see also Myers and Daly, 1976b: 194–197; Myers et al., 1995), which means that the occurrence of a given alkaloid may be determined not by the genotype but by availability of the dietary source in the environment (making this a nonheritable characteristic, i.e., not a character). Saporito et al. (2003) identified a species of siphonotid millipede as the likely dietary source of spiropyrrolizidine and Saporito et al. (2004) identified certain species of formicine ants as the natural dietary source of two pumiliotoxins found in pumilio. Dumbacher et al. (2004) identified melyrid beetles as the probable dietary source of batrachotoxins for the New Guinean passerine birds Pitohui and Ifrita and further conjectured that this is the likely source of the alkaloids in Phyllobates as well. There is often considerable variation in the alkaloid profiles of conspecifics from both the same and disjunct populations (e.g., Myers et al., 1995). Captive reared offspring of wild-caught, toxic frogs are nontoxic if fed crickets and fruit flies, but readily accumulate alkaloids if present in the diet (either as a pure supplement to a fruit fly diet or in leaf-litter arthropods; Daly et al., 1992, 1994a, 1994c).

Nevertheless, despite the environmental dependency, there is also clearly a heritable aspect to the alkaloid uptake system. It has been found experimentally that azureiventris, panamensis, and talamancae do not accumulate detectable amounts of alkaloids when ingested from the diet (Daly et al., 1994c; Daly, 1998). Furthermore, among sequestering species there is differential accumulation, as suggested indirectly by the occurrence of different alkaloid profiles among microsympatric species (Daly et al., 1987; Myers et al., 1995) and demonstrated directly by feeding experiments (Daly et al., 1994c, 2003; Garraffo et al., 2001), that is, the uptake systems of different species either (1) are capable of sequestering only a subset of the alkaloids ingested in the diet or (2) vary drastically in the efficacy of accumulation of different classes of alkaloids. Either way, this variation is heritable. Furthermore, Daly et al. (2003) demonstrated selective alkaloid modification by certain dendrobatid species and not others (see Character 171). As with all phenotypic characters, the expression of alkaloid characters is due to the combination of genotype plus environment (for a detailed discussion of the meaning of “genetic” see Sarkar, 1998). Hypotheses of homology can therefore be proposed defensibly, albeit cautiously, for alkaloid profiles.

Given that it is the capability to accumulate a class of toxin that is treated as the character, we coded alkaloid profiles as “any instance” (Campbell and Frost, 1993). That is, we treated the demonstrated occurrence of a given class of alkaloid in one or more populations of a species as evidence that the entire species is capable of accumulating that class of alkaloid (i.e., it is coded as present), even if that class of alkaloid was not detected in all samples. This is not intended as a general endorsement of that method of codifying polymorphism (for theoretical arguments, see Grant and Kluge, 2003, 2004), but rather as a consequence of this particular biological problem. Given current understanding of the alkaloid uptake system of these frogs, it is most likely that the absence of a class of alkaloid in some but not all individuals is due to dietary deficiency and not a character-state transformation. This assumption is testable, and it may be found that (1) this assumption is borne out (i.e., the alkaloid is sequestered when present in the diet), (2) such species are truly polymorphic (i.e., character history and species history do not track each other perfectly, either due to ancestral polymorphism, a character-state transformation event subsequent to the most recent cladogenetic event, or some other phenomenon), or (3) multiple species have been conflated. This is exemplified by lugubris:

It is also possible that a species is capable of accumulating an alkaloid not detected in any population because the dietary source of the precursor is absent at all sampled localities (i.e., failure to detect accumulation in wild-caught specimens does not decisively demonstrate that the species is incapable of sequestration). However, by coding these taxa as lacking the ability to accumulate the toxin we incorporated all available evidence. The hypothesis that a taxon is incapable of accumulating a class of toxin is falsifiable and can be tested both by examining more specimens and populations and through feeding experiments. For example, although no histrionicotoxin could be detected in wild lehmanni Myers and Daly (Myers and Daly, 1976b), Garraffo et al. (2001: 421) report that “[f]eeding experiments indicated that D. lehmanni readily accumulated histrionicotoxin into skin when fed alkaloid-dusted fruit flies.”

Although a dietary source is either known or assumed for dendrobatid alkaloids, the actual arthropod(s) responsible have yet to be discovered for the vast majority of these, that is, most of the alkaloids are unknown elsewhere in nature. Potential sources were reviewed by Daly et al. (1993: 226, 2005). For example, pyrrolizidines are known to occur in the ants Solenopsis xenovenenum, Monomorium spp. from New Zealand, and Megalomyrmex from Venezuela. Pyrrolidines (including 2,5-pyrrolidines, known among amphibians only in dendrobatids) occur in Solenopsis, Monomorium, and Megalomyrmex. Decahydroquinolines were detected in extracts of virgin queens of the thief ant Solenopsis (Diphorhoptrum) azteca from Puerto Rico. 3,5-Disubstituted indolizidines occur in ants of the genera Monomorium and Solenopsis. Coccinellines were first discovered in the ladybug beetles Coccinellidae. Monocyclic piperidines occur in Solenopsis. Spiropyrrolizidine is likely sequestered from a millipede (Saporito et al., 2003), two pumiliotoxins found in pumilio are obtained from formicine ants (Saporito et al., 2004), and scheloribatid mites are the probable source of a third pumiliotoxin in pumilio (Takada et al., 2005). The source of batrachotoxins in dendrobatids remains unknown, although melyrid beetles are likely (Dumbacher et al., 2004).

That the actual dietary source is unknown is an important consideration, given the discovery by Daly et al. (2003) that some species convert dietary pumiliotoxin to allopumiliotoxin via a specific hydroxylation event (see Character 171, below). Whereas prior to this discovery it was assumed that all of the over 450 alkaloids known in these frogs were incorporated without modification into the skin, one must consider the possibility that some portion of this diversity of alkaloids may result from the modification of precursors. Nevertheless, it is unclear how widespread metabolic conversion may be, as the following 12 alkaloid classes have been administered in feeding experiments with no evidence for any metabolism (J. W. Daly, in litt., 01/25/05): batrachotoxin, histrionicotoxins, allopumiliotoxins, decahydroquinolines, 3,5-pyrrolizidines, 3,5-indolizidine, 5,8-indolizidine, 5,6,8-indolizidine, pyrrolidine, piperidine, spiropyrrolizidine, and coccinelline-like tricyclics.

Given the dietary origin of the alkaloids and how little is known about the alkaloid uptake system, we were conservative in delimiting alkaloid characters for phylogenetic analysis. Instead of coding the occurrence of each of the over 450 dendrobatid alkaloids as a separate character, we scored the occurrence of the major and minor classes of alkaloids, following Daly et al. (1987, 1993) and incorporating more recent developments (e.g., Daly et al., 1994c, 2003, 2005; Daly, 1998; Garraffo et al., 1993, 1997, 2001; Daly et al., 1999; Mortari et al., 2004; J. W. Daly, in litt., 01/25/05). We followed Myers (1987) and Myers et al. (1995) in coding 3,5-indolizidines and 5,8-methylindolizidines as distinct characters. In only coding the occurrence of general classes of alkaloids, we consciously overlooked more refined, potentially phylogenetically informative data in an attempt to avoid introducing error due to the nature of alkaloid accumulation in these frogs. Furthermore, in the majority of species, numerous alkaloids of the same class co-occur, which suggests that sequestration acts at the level of the class of alkaloid, not individual alkaloids; that is, it appears that it is the ability to sequester alkaloids with certain chemical properties that evolves, not the ability to sequester a particular alkaloid.

We did not distinguish between major, minor, and trace occurrences of alkaloids (i.e., we treated all as “present”), but, following Daly's recommendation (J. W. Daly, in litt., 02/02/00), we did not consider “trace, trace” occurrences as evidence of presence of an alkaloid, as merely having recently consumed an alkaloid-containing prey item could give this result.11 We also did not discriminate based on uptake efficiency. For example, although uptake of piperidines is poor in most species (e.g., auratus, in which they are trace alkaloids), and uptake of piperidine 241D appears highly efficient in speciosus (in which this is a major or minor alkaloid), we coded piperidines identically (i.e., present). It should be clarified that, despite the fact that the trivial names of the classes of alkaloids are often derived from species that possess it (e.g., pumiliotoxin from pumilio), compounds are assigned to a class based on molecular structure and chemical properties, not taxonomic distribution.

It has been speculated that certain alkaloids could share common precursors, specifically a 2,6-disubstituted(dehydro)piperidine as a precursor in the biosynthesis of histrionicotoxins, gephyrotoxins, indolizidines, and decahydroquinolines (Daly et al., 1987: 1065), and more generally that the monocyclic piperidines are possible precursors for the more complex, piperidine-ring-containing alkaloids and the monocyclic pyrrolidines for the more complex, pyrrolidine-ring-containing dendrobatid alkaloids (Daly et al., 1993: 251). Nevertheless, with the exception of allopumiliotoxin 267A (see Character 171), there is no evidence that they share a common biosynthetic origin, and even if they do, this would pertain to the arthropods, not the frogs' uptake system. Historical independence is demonstrated by the fact that no classes of alkaloids share identical taxonomic distributions.

We coded unambiguously only those species whose alkaloid profiles have been examined; taxa whose profiles have not been examined were coded as unknown (“?”). The discovery that an untested species is embedded within a toxic clade would provide a strong prediction that the species may also sequester alkaloids and would therefore guide chemists in their search for novel, potentially useful toxins. Negative findings often are not explicitly reported in the literature; however, in cases where species have been examined using techniques that would detect a particular compound and the compound was not reported, we coded it as absent (e.g., epibatidine). If there was any doubt as to the tests samples were subjected to, we coded the character as unknown (“?”).

Data were taken from reviews (Daly et al., 1987, 1993, 1999), the primary literature (Tokuyama et al., 1992; Garraffo et al., 1993, 2001; Badio and Daly, 1994; Myers et al., 1995; Daly et al., 1997., 2003; Fitch et al., 2003; Saporito et al., 2003; Mortari et al., 2004; Darst et al., 2005), and an exhaustive summary of published and unpublished alkaloid profiles and corrections to previous accounts provided by John W. Daly (in litt., 01/25/05). To facilitate coding from the literature we list the individual nonsteroidal alkaloids for each class, following the convention of Daly et al. (1987). We did not include unclassified alkaloids, although they may provide relevant information once their structures are elucidated. We did not list unpublished alkaloids in the character descriptions (although we did code their presence in the matrix), and we only listed alkaloids that occur in the species sampled in the present study.

147. Ability to Sequester Alkaloids: absent  =  0; present  =  1.

We coded the general ability to sequester alkaloids separately from the individual classes of alkaloids sequestered in order to count the gain and loss as a single transformation event. We scored species that are incapable of sequestering any alkaloid as state 0 for this character and missing (“–“) for all other lipophilic alkaloid characters; we coded species that are able to sequester any alkaloid as state 1 for this character and present and absent for each of the particular alkaloid classes. That is, although the origin of the ability to sequester alkaloids necessarily entails the ability to sequester some particular class(es) of alkaloid(s) (i.e., there is a logical relation of nested dependency between these characters), the fact that no taxon possesses only a single class of alkaloid would mean that the alternative approach of treating each origin and loss as entirely unrelated events would count the origin of sequestration as multiple events. The biological assumption underlying this coding is that there exists a single genetic basis for the sequestration of all classes of lipophilic alkaloids and that modifications to it account for the differential ability to sequester distinct classes. This assumption is consistent with the limited understanding of the uptake mechanism but has not been subjected to critical test (i.e., no attempt has been made to isolate the genetic basis of sequestration).

Darst et al. (2005) reported the occurrence of alkaloids based on thin layer chromatography, which allowed us to score several additional species. Unfortunately, that method does not discriminate between or lead to the identification of different alkaloids, so this is the only character that can be coded from their results.

148. Batrachotoxins (BTX): absent  =  0; present  =  1.

The steroidal batrachotoxins are known to occur in only five species of frogs (aurotaenia, bicolor, lugubris, terribilis, and vittatus), and their shared occurrence was treated as evidence of the monophyly of those species in a restricted Phyllobates (Myers et al., 1978). Given the extreme toxicity of BTX relative to other dendrobatid alkaloids, the ability of these frogs (and the inability of other dendrobatids) to sequester BTX is likely related to their modified sodium channel that is insensitive to BTX (as demonstrated for aurotaenia and terribilis; Daly et al., 1980).

149. Histrionicotoxins (HTX): absent  =  0; present  =  1.

235A, 237F, 239H, 259A, 261A, 263C, 265E, 283A, 285A, 285B, 285C, 285E, 287A, 287B, 287D, 291^a.

Alkaloid 283A′ (found in sylvaticus Funkhouser) is closely related to and was treated as an HTX by Daly et al. (1987), but it was not included by Daly et al. (1993) or Daly et al. (2005).

150. Pumiliotoxin (PTX): absent  =  0; present  =  1.

207B, 209F, 225F, 237A, 251D, 253F, 265D, 265G 267C, 267D, 277B, 281A, 293E, 297B, 305B, 307A, 307B, 307D, 307F 307G, 307H, 309A, 309C, 321A, 323A, 325B, 353A.

151. Allopumiliotoxins (aPTX): absent  =  0; present  =  1.

225E, 237B, 241H, 251I, 253A, 267A, 297A, 305A, 307C, 309D, 321C, 323B, 325A, 339A, 339B, 341A, 341B, 357.

152. Homopumiliotoxins (hPTX): absent  =  0; present  =  1.

223G, 249F, 251L, 256R, 265N, 317, 319A, 319B, 321B.

153. Decahydroquinoline (DHQ): absent  =  0; present  =  1.

193D, 195A, 209A, 209J, 211A, 211K, 219A, 219C, 219D, 221C, 221D, 223F, 223Q, 223S, 231E, 243A, 245E, 249D, 249E, 251A, 253D, 267L, 269AB, 269A, 269B, 271D, 275B.

154. 3,5-Disubstituted Pyrrolizidines: absent  =  0; present  =  1.

167F, 195F, 209K, 223B, 223H, 237G, 251K, 253I, 265H, 265J, 267H.

167F and 209K were formerly classified as the 3,5-disubstituted indolizidines 167B and 209D.

155. 3,5-Disubstituted Indolizidines: absent  =  0; present  =  1.

195B, 211E, 223AB, 223R, 237E, 239AB, 239CD, 239E, 249A, 271F, 275C, 275F.

156. 5,8-Disubstituted Indolizidines: absent  =  0; present  =  1.

181B, 193E, 197C, 203A, 205A, 207A, 209B, 209I, 217B, 219F, 221A, 221K, 223D, 223J, 225D, 231C, 233D, 235B, 237D, 237H, 239A, 239B, 239C, 239D, 239F, 239G, 241C, 241F, 243B, 243C, 243D, 245B, 245C, 245D, 251B, 251U, 253B, 263F, 257C, 259B, 261D, 271A, 273B, 279D, 295A, 295B.

157. Dehydro-5,8-indolizidines: absent  =  0; present  =  1.

245F, 245H.

158. 5,6,8-Indolizidines: absent  =  0; present  =  1.

195G, 207Q, 223A, 231B, 233G, 237L, 249H, 251M, 253H, 259C, 263A, 263D, 265I, 265L, 267J, 273A, 275E, 277C, 277E, 279F, 293C.

159: 4,6-Quinolizidines: absent  = 0; present  =  1.

195C, 237I.

160. 1,4-Quinolizidines: absent  =  0; present  =  1.

207I, 217A, 231A, 233A, 235E', 247D, 257D.

161. Lehmizidines: absent  =  0; present  =  1.

275A.

162. Epiquinamide: absent  =  0; present  =  1.

196.

163. 2,5-Pyrrolidine (PYR): present  =  0; absent  =  1.

183B, 197B, 223N, 225C, 225H, 277D, 279G.

164. 2,6-Piperidines (PIP): absent  =  0; present  =  1.

197E, 211I, 211J, 213, 221L, 223K, 225B, 225I, 237J, 239I, 239L, 239O, 241D, 241G, 253J, 255A, 267K, 267C.

165. Gephyrotoxin (GTX): absent  =  0; present  =  1.

287C, 289B.

166. Coccinelline-like Tricyclics: absent  =  0; present  =  1.

191B, 193A, 193C, 201B, 205B, 205E, 207J, 207P, 207R, 219I, 221G, 221M, 235M, 235P.

167. Spiropyrrolizidines: absent  =  0; present  =  1.

Referred to as pyrrolizidine oximes by Daly et al. (1993).

222, 236, 252A, 254.

168. Indolic Alkaloids (Chimonanthine/Calycanthine): absent  =  0; present  =  1.

346B, 346C.

169. Epibatidines: absent  =  0; present  =  1.

208/210, 308/310.

170. Noranabasamine ( = Pyridyl-Piperidines): absent  =  0; present  =  1.

This pyridine alkaloid is known in nature only from aurotaenia, bicolor, and terribilis (Daly et al., 1993, 1999).

239J.

171. Pumiliotoxin 7-Hydroxylase: absent  =  0; present  =  1.

Feeding experiments by Daly et al. (2003) demonstrated the existence in several species of dendrobatids of an enantioselective mechanism that converts PTX (+)-251D to the more highly toxic allopumiliotoxin (aPTX) (+)-267A. That is, contrary to other alkaloid characters, which code the ability to sequester a class of alkaloid, this character applies to the occurrence of the 7-hydroxylase, as evidenced by the occurrence of the hydroxylated compound.

Coding this character is somewhat more complicated than coding the other alkaloid characters, because in this case occurrence of aPTX 267A may be due to either (1) the hydroxylation of PTX 251D or (2) the sequestration of aPTX 267A from a dietary source (aPTX is known to occur in some arthropods). This creates the potential for both false negatives and false positives. Direct evidence for the occurrence of 7-hydroxylase may only be obtained through feeding experiments. Further evidence on the distribution of the pumiliotoxin 7-hydroxylase obtained indirectly from the alkaloid profiles of wild-caught specimens (see Daly et al., 2003: 11095, table 1) requires the assumption that all aPTX 267A occurs through metabolism of ingested PTX 251D, which, at least in the case of anthonyi (reported as tricolor; for taxonomy of these species, see Graham et al., 2004), is false (assuming multiple species have not been conflated). Daly et al. (2003) reported wild-caught specimens as possessing trace amounts of aPTX 267A, but feeding experiments revealed that the species is incapable of hydroxylating PTX 251D and the occurrence of aPTX 267A represents a false positive for the presence of 7-hydroxylase. Nevertheless, in the absence of direct evidence from feeding experiments, such as is available for anthonyi, we coded all trace, minor, and major occurrences of aPTX 267A as the presence of the 7-hydroxylase, which allows the results of phylogenetic analysis to serve as a tool for designing future feeding experiments to test hypothesized occurrence of 7-hydroxylase (e.g., finding that a species that possesses aPTX 267A is embedded in a clade of species incapable of 7-hydroxylation would suggest the occurrence may be due to sequestration from a dietary source and not biosynthetic conversion).

Conversely, the absence of 7-hydroxylase can only be assured in the presence of PTX 251D. We coded the failure to detect aPTX 267A as “absent” (state 0) only when PTX 251D was detected. If PTX 251D was not detected (but other PTXs were), we coded this character as unknown (“?”) (e.g., truncatus). If available evidence indicates that a species is incapable of sequestering pumiliotoxins, we coded this character as missing (“–”) (e.g., trivittatus).

Direct evidence for the presence of the pumiliotoxin 7-hydroxylase through feeding experiments was found for auratus, galactonotus, and castaneoticus, and direct evidence for the absence of pumiliotoxin 7-hydroxylase through feeding experiments was found in tricolor and bicolor (Daly et al., 2003). Other species are coded on the basis of wild-caught specimens, with data derived from Daly et al. (1987, 1993, 2003).

172. Tetrodotoxin (TTX): absent  =  0; present  =  1.

Daly et al. (1994b) reported the occurrence of TTX in panamensis (as Colostethus inguinalis; see Grant, 2004). They also examined aqueous extracts of eight additional species referred to Colostethus (the “Colostethus species” reported as being “common, nr Villa María, Caldas, Colombia” is fraterdanieli), and nocturnus, pumilio, and bicolor. Daly et al. (1994b: 283) cautioned that the negative results for pumilio and bicolor were based on methanol extracts,

173. Chromosome Number: 18  =  0; 20  =  1; 22  =  2; 24  =  3; 26  =  4; 28  =  5; 30  =  5. Additive.

Karyological data have been reported for 35 of the dendrobatids included in the present study: panamensis and pumilio (Duellman, 1967), auratus and pumilio (León, 1970), trivittatus (Bogart, 1970, 1973, 1991), trinitatis (Rada de Martínez, 1976), auratus, granuliferus, histrionicus, lugubris, pumilio, and sylvaticus Funkhouser (as histrionicus from NW Ecuador) (Rasotto et al., 1987), conspicuus [as brunneus], femoralis, fraterdanieli, olfersioides, palmatus, pictus, subpunctatus, talamancae, trivittatus, truncatus, vanzolinii [as quinquevittatus], vertebralis, and an undescribed species referred to Colostethus (Bogart, 1991), caeruleodactylus, marchesianus (sensu stricto; see Caldwell et al., 2002b) and two undescribed species referred to Colostethus (Veiga-Menoncello et al., 2003a), nidicola and stepheni (Veiga-Menoncello et al., 2003b), chalcopis, leopardalis, herminae, neblina, olmonae, and trinitatis (Kaiser et al., 2003), flavopictus, femoralis, hahneli, and trivittatus (Aguiar et al., 2002). Thirty of those species are included in the present study.

For outgroup taxa, data were taken from Kuramoto's (1990) review. Data published subsequently were taken from Silva et al. (2001) for Cycloramphus boraceiensis, Rosa et al. (2003) for Megaelosia, Ramos et al. (2002) for Atelopus zeteki, and Aguiar et al. (2004) for Crossodactylus and Hylodes phyllodes.

Coding chromosome variation as transformation series is complicated by imprecision in determining chromosome homology. For the most part, chromosomes are simply arranged according to size and named (numbered) consecutively. That all variation in chromosome morphology is reported in relation to chromosome identity (which is a function of relative chromosome size) is a serious problem. Rarely, more detailed considerations are brought to bear (e.g., see Bogart, 1991, regarding the homology of chromosome 4 in pictus and chromosome 5 in trivittatus), but this is done so infrequently as to be of little use in the present study. A further limitation of available karyological data relates to the variation in techniques and kinds of data reported. For example, nucleolar organizing regions (NORs) are reported for only 11 of the dendrobatids included in this study, and in just those few species at least six NOR states are apparent. Likewise, in light of the confounding variation he observed, Bogart (1991: 245) cautioned that “[i]t is evident that analysis of chromosome arms would be of little value for understanding karyotype evolution in the family Dendrobatidae. It is also evident that dendrobatid chromosomes have undergone extensive restructuring via translocations and inversions.”

There are undoubtedly many additional transformation series in chromosome morphology, but we coded only chromosome number because (1) it is reported in all karyological studies, (2) it is less dependent on individual chromosome identity (see references above), and (3) it has been employed previously in studies of dendrobatid systematics. Nevertheless, inferring transformation series solely from chromosome number necessarily assumes that the same chromosome(s) are gained or lost in each change in total number of chromosomes, which future research will undoubtedly determine to have been an oversimplification.