The dorid nudibranchs Peltodoris lentiginosa and Archidoris odhneri were found on glass sponges (Porifera, Hexactinellida) during remotely operated vehicle surveys of three reefs in the Strait of Georgia, British Columbia, Canada. Eight nudibranchs were sampled from 2009 to 2011. Identification of sponge spicules found in their gut and fecal contents confirmed the nudibranchs to be predators of the reef-forming hexactinellids Aphrocallistes vastus and Heterochone calyx, as well as of the demosponge Desmacella austini, which encrusts skeletons of the glass sponges. Four of five nudibranchs dissected for gut content analysis had stomachs containing sponge spicules. Counts from high-definition video footage taken during systematic surveys done in 2009 showed that nudibranchs were found in only two of the three glass sponge reefs. These data provide the first quantitative evidence of a molluscan predator on glass sponges found outside of Antarctica, and establish the first trophic link between glass sponges and their associated community of animals in a sponge reef ecosystem on the western Canadian continental shelf.

Experimental manipulations of the energy content of marine invertebrate embryos have been useful in testing key assumptions of life history theory, especially those concerning relationships between egg size, length of the planktonic period, and juvenile size and quality. However, methods for such “allometric engineering” experiments have been available for only a limited set of taxa (those with regulative early development, e.g., cnidarians and echinoderms). Here, we describe a method for the reduction of embryo energy content in the spirally cleaving embryos of a marine annelid, Capitella teleta, by targeted deletion of endodermal precursor cells. Embryos of C. teleta in which up to three cells (the macromeres 3A, 3B, and 3C) were deleted formed morphologically normal lecithotrophic larvae that were much smaller than larvae developing from control embryos. Experimental larvae metamorphosed at high rates, forming juveniles that were smaller than control juveniles. Juveniles derived from treated embryos had functional midguts, ingested and digested food, and grew into sexually mature adults. These results are consistent with those from previous allometric engineering studies of echinoid echinoderms, which suggest that in facultatively planktotrophic or lecithotrophic species, little maternally derived energy is used for construction of the larval body; instead, the majority is allocated to the formation of a large, high-quality juvenile. Cleavage programs are highly conserved among divergent spiralian taxa (e.g., molluscs, nemerteans, and platyhelminths), so this method will likely be applicable to a diverse set of embryos. Similar experiments carried out in these diverse taxa will be extremely useful for evaluating inferences on relationships between egg size, length of the planktonic period, and juvenile size and quality previously based only on experiments on echinoid echinoderms.

Many aspects of barnacle body form are known to be developmentally plastic. Perhaps the most striking examples of such plasticity occur in their feeding legs and unusually long penises, the sizes and shapes of which can change dramatically and adaptively with changes in conspecific density and local water flow conditions. However, whether variation in overall appendage form is mirrored by structural responses in cuticle and muscle is not known. In order to determine how structural variation underlies phenotypic plasticity in barnacle appendages, we examined barnacles occurring at low and high population densities from one wave-protected and one wave-exposed site. We used histological sectioning and fluorescence microscopy of feeding legs and penises to compare cuticle thickness, muscle thickness, and muscle organization, and artificial penis inflation to compare penis extensibility. We observed striking differences in cuticle thickness, muscle thickness, and muscle organization between sites that differed in water velocity, but we found no clear differences associated with variation in conspecific density. Penis extensibility also did not differ consistently between sites. These results are consistent with an adaptive explanation for much of the remarkable and complex variation in barnacle feeding leg and penis morphology among sites that differ in water velocity.

To analyze the stable isotope ratios of small-bodied invertebrates, the entire animal is typically sacrificed and processed, which is problematic for threatened or endangered species. Appendages which are regenerated could be used to infer whole-body isotope ratios, but differences in turnover rates and isotopic signatures among tissues may confound such an approach. We tested the hypothesis that the Δ¹³C and Δ¹⁵N of whole-body tissue for freshwater amphipods could be predicted from the Δ¹³C and Δ¹⁵N of walking legs, with the goal of estimating body Δ¹³C and Δ¹⁵N of Gammarus acherondytes, a United States federally endangered species. To test this, we analyzed the Δ¹³C and Δ¹⁵N of walking legs and bodies of five species of amphipods from geographically distant areas (Idaho, Illinois, and Washington) in the United States. The general relationships of whole-body isotope ratios of C and N as a function of leg isotope ratios were linear and had slopes of one. In the range of the data, leg Δ¹³C was slightly lower than body Δ¹³C, indicating some tissue-specific fractionation, while Δ¹⁵N was similar for legs and bodies. Our data suggest that legs can be used to predict body isotope ratios in freshwater amphipods. This approach provides an additional tool to help researchers understand the biology of small, endangered invertebrates without sacrificing individuals. This is especially useful in cave ecosystems where populations are naturally sparse.

Lithobius forficatus (Myriapoda, Chilopoda, Lithobiidae) is a widespread species of centipede that is common across Europe. Its midgut epithelial cells are an important line of defense against toxic substances that originate in food, such as pathogens and metals. Despite this important role, the biology of the midgut epithelium is not well known. Here we describe the ultrastructure of the midgut epithelium, as well as the replacement of degeerated midgut epithelial cells. The midgut epithelium of L. forficatus is composed of digestive, secretory, and regenerative cells. The cytoplasm of digestive cells shows regionalization in organelle distribution, which is consistent with the role of these cells in secretion of enzymes, absorption of nutrients, and accumulation of lipids and glycogen. Secretory cells, which do not reach the luminal surface of the midgut epithelium, possess numerous electrondense and electronlucent granules and may have an endocrine function. Hemidesmosomes anchor secretory cells to the basal lamina. Regenerative cells play the role of midgut stem cells, as they are able to proliferate and differentiate. Their proliferation occurs in a continuous manner, and their progeny differentiate only into digestive cells. The regeneration of secretory cells was not observed. Mitotic divisions of regenerative cells were confirmed using immunolabeling against BrdU and phosphohistone H3. Hemocytes associate with the midgut epithelium, accumulating between the visceral muscles and beneath the basal lamina of the midgut epithelium. Hemocytes also occur among the digestive cells of the midgut epithelium in animals infected with Rickettsia-like microorganisms. These hemocytes presumably have an immunoprotective function in the midgut.

Evania appendigaster is a cosmopolitan wasp that deposits eggs in the oothecae of some species of cockroaches; its larvae then consume the cockroach eggs and embryos. It is a candidate for the biological control of cockroaches, but little is known about its basic biology. Here we describe the external morphology of all immature stages of E. appendigaster and compare them with the larvae of related species. The life cycle of E. appendigaster includes three larval instars, each with 13 body segments. Their mouthparts were generally reduced, except for the mandibles, which were always sclerotized and toothed, and were especially robust in second-instar larvae. Antennal and mouthpart sensilla were basiconic and difficult to observe. Larvae of E. appendigaster are similar in form to other described evaniid larvae, but quite different from the two available descriptions of larvae of gasteruptiid and aulacid wasps. Further descriptions of evaniid larvae will be useful in determining how widespread this morphology is within the family, and in understanding phylogenetic relationships within Hymenoptera.

The potential for short-range sex pheromone communication by the egg parasitoid wasp Trissolcus brochymenae (Hymenoptera: Platygastridae) was investigated in closed arena bioassays. Males of this parasitoid showed more antennal drumming and more frequent mounting behaviour on 1- to 2-d-old virgin females compared with 8-d-old virgin females. Male copulation attempts were fewer with previously mated females than with virgin females. Males courted and made copulation attempts with 1- to 2-d-old female cadavers, but not with male cadavers or with female cadavers rinsed in organic solvents of different polarities. Male attraction to female cadavers was re-established by treating cadavers with acetone extracts of females, but not with ether or hexane extracts. In experiments using female cadavers dissected into head, mesosoma, and gaster, and then reassembled using one unwashed body section and two body sections washed in acetone, males were attracted only to the reassembled cadavers with an unwashed mesosoma. These findings suggest that (1) courtship behaviour in males of T. brochymenae is triggered by a short-range sex pheromone produced by females; (2) the age and the physiological condition of females (virgin/mated) influence pheromone release or production; (3) the female's mesosoma is the source of the sex pheromone; and (4) polar components of the sex pheromone play a major role in influencing male behaviour. Our results suggest that quasi-gregarious egg parasitoids are selected for short-range rather than long-range sex pheromones.