We describe three species of large scaphitid ammonites (Ammonoidea: Ancyloceratina) from the Upper Cretaceous (upper Campanian–lower Maastrichtian) of the Western Interior of North America. Each species occurs as two dimorphs, referred to as macroconch and microconch. All three species share a similar pattern of ornamentation consisting of long, thin, nonbifurcating ribs on the adoral part of the phragmocone, suggesting that they constitute a single monophyletic clade. Macroconchs of Hoploscaphites crassus (Coryell and Salmon, 1934) are characterized by a globose whorl section, with closely spaced ventrolateral tubercles on the body chamber, usually persisting to the aperture. Macroconchs of Hoploscaphites plenus (Meek and Hayden, 1860) differ from those of H. crassus in having a more subquadrate whorl section with flatter flanks, and fewer, larger, and more widely spaced ventrolateral tubercles. Macroconchs of Hoploscaphites peterseni, n. sp., closely resemble those of H. crassus, but differ in being nearly circular in side view with a more compressed whorl section. All three species lived at approximately the same time in the same general area and depositional environment. They are abundant in the Baculites baculus Zone but also occasionally occur in the B. eliasi Zone and possibly lower part of the B. grandis Zone. They are present in the Pierre Shale of east-central Montana and east-central Wyoming, the Lewis Shale of south-central Wyoming, and the Bearpaw Shale of northeast Montana. It is possible that these three species represent subspecies within a single species or a “flock” of very closely related species, similar to the “species flocks” observed in modern cichlid fishes.
INTRODUCTION
Heteromorph ammonites of the genus Hoploscaphites Nowak, 1911, are important biostratigraphic markers in Upper Cretaceous (middle Campanian to Maastrichtian) rocks in the Western Interior of North America. They first appear in the Baculites asperiformis Zone and extend to the H. nebrascensis Zone. All of the species are endemic to North America, although they have occasionally been reported from Western Europe, but only as fragments (Machalski et al., 2007). In this paper, we describe three species of Hoploscaphites, one of them new, from the upper Campanian to lower Maastrichtian of North America.
In general, the species of Hoploscaphites from the Western Interior of North America are abundant and well preserved. Indeed, some of the species in our study are represented by hundreds of specimens derived from single horizons. Their excellent preservation is due to rapid burial after death and fossilization in early diagenetic carbonate concretions. As a result, these ammonites are well suited for taxonomic study. They permit a detailed examination of morphology, including jaws and muscle scars. They also lend themselves to an investigation of the range of variation within and between species and how these considerations affect the definition of a species. This is an active area of investigation in ammonite systematics (for a review of this subject, see deBaets et al., 2015).
Geologic Setting
The Western Interior Seaway (WIS) was a broad epicontinental seaway that extended from western Canada to the proto-Gulf of Mexico during the Late Cretaceous (Cobban and Reeside, 1952; Williams and Stelck, 1975). The western margin of the WIS was bordered by a north-south trending unstable cordillera; the eastern margin was formed by the low-lying platform of the conterminous United States and Canada (Shurr et al., 1994). The position of the western margin of the WIS during the Late Cretaceous has been inferred based on the meticulous mapping studies of Gill and Cobban (1966) and Cobban et al. (1994). Figure 1A illustrates the position of the shoreline during the late Campanian and early Maastrichtian, the focus of our study. At the time, the shoreline formed a broad embayment in Montana (called the Mosby Embayment) separated from the rest of the WIS by a peninsula in the southeastern corner of the state (called the Sheridan Delta; Reiskind, 1975). The shoreline then cut to the southwest as a series of embayments as far as south-central Wyoming, and then cut southeastward across the middle of Colorado.
We utilize the biostratigraphy of the Upper Cretaceous Western Interior established by Cobban et al. (2006) based on ammonites and inoceramids. Accordingly, the upper part of the upper Campanian comprises the Baculites jenseni and B. eliasi zones (fig. 1B). The lower part of the lower Maastrichtian comprises the B. baculus and B. grandis zones. The lower part of the B. baculus Zone coincides with the Endocostea typica inoceramid Zone and the upper part of the B. baculus Zone coincides with the “Inoceramus” incurvus inoceramid Zone; the B. grandis Zone coincides with the Trochoceramus radiosus inoceramid Zone (fig. 1B). The Campanian-Maastrichtian boundary is placed at the base of the B. baculus Zone coincident with the base of the E. typica Zone (Walaszczyk et al., 2001; Cobban et al., 2006). The ages of these zones are based on radiometric dating of bentonites (fig. 1B) and are published in Cobban et al. (2006) and updated in Lynds and Slattery (2017) and this report (see below).
The localities referred to in this study are located in Montana and Wyoming within 200 km of the western shoreline of the WIS, depending on the time (fig. 1A). With the retreat of the WIS during the late Campanian and early Maastrichtian, the shoreline prograded eastward in association with the development of the Sheridan Delta, reflecting the shedding of sediments from regional uplifts in the area of the Big Horn and Granite Mountains (Krystinik and DeJarnett, 1995). Most studies suggest that the WIS at the time was less than 100 m deep (Gill and Cobban, 1966; Kauffman and Caldwell, 1993). However, the depth at each locality depends on the particular time slice under consideration. For example, the depth of the WIS on the Cedar Creek Anticline in east-central Montana during the deposition of the upper part of the Baculites baculus Zone was probably less than 50 m (Landman et al., 2019).
We describe three species of Hoploscaphites: H. crassus (Coryell and Salmon, 1934), H. plenus (Meek and Hayden, 1860), and H. peterseni, n. sp. These species are abundant in the B. baculus Zone but also occasionally occur in the B. eliasi Zone and possibly lower part of the B. grandis Zone. They are present in the Pierre Shale of east-central Montana and east-central Wyoming, the Lewis Shale of south-central Wyoming, and the Bearpaw Shale of northeast Montana. Hoploscaphites crassus and H. plenus also occur in the B. eliasi and B. baculus zones of the Bearpaw Shale of Saskatchewan and Alberta (Riccardi, 1983). Three other species of Hoploscaphites were previously described from the same general area: H. macer Landman et al., 2019, and H. criptonodosus Riccardi (1983) from the upper part of the B. baculus and lower part of the B. grandis zones, and H. sargklofak Landman et al., 2015a, from the B. grandis Zone. In the following discussion, we describe three stratigraphic sections (the Bearpaw Shale, Garfield County, Montana; the Pierre Shale, Nobrara County, Wyoming; and the Pierre Shale, east-central Montana) in detail because they form an integral part of our study.
REGIONS
Pierre Shale, East-Central Wyoming
Many of the specimens in our study are derived from the Pierre Shale in east-central Wyoming. The upper Campanian and lower Maastrichtian section at Red Bird, Niobrara County, Wyoming, is nearly complete, and as such, was designated as the informal reference section for the Pierre Shale by Gill and Cobban (1966). It has inspired much research (e.g., Hicks et al., 1999; Slattery et al., 2018; Landman, in press), and we briefly review some stratigraphic details pertinent to the present study (fig. 2).
The Baculites eliasi Zone occupies the upper part of the lower unnamed shale member, the Kara Bentonitic Member, and the lower part of the upper unnamed shale member. The lower unnamed shale member is 720 ft (219 m) thick and consists of alternating bands of dark, medium, and light-gray weathering shale. It contains abundant fossiliferous limestone concretions that yield specimens of Hoploscaphites plenus (USGS loc. D1636). The Kara Bentonitic Member is 36 ft (11 m) thick at Red Bird and consists of gray weathering shale and bentonitic shale with a 6 ft (1.8 m) thick bentonite bed at its base. It is capped with a ridge-forming concretionary limestone bed that yields specimens of H. crassus (USGS loc. D1967). The upper unnamed shale member is 680 ft (207 m) thick at Red Bird and consists of sandy and silty shale representing dark and light-gray bands. According to Gill and Cobban (1966), the base of the B. baculus Zone is 61 ft (19 m) above the top of the Kara Bentonitic Member. We have identified specimens of H. crassus and H. peterseni from limestone concretions in the lower part of this zone (USGS locs. D1975, D1976, and D1981). The known occurrence of each species of Hoploscaphites in the section is indicated by a solid vertical line in figure 2, although it is likely that all three species range throughout the stratigraphic interval from USGS loc. D1636 to D1981 (dashed vertical lines in fig. 2).
Bearpaw Shale, Northeast Montana
The Bearpaw Shale in northeast Montana is the source of several specimens in our study (fig. 3). The formation was named and described by Stanton and Hatcher (1905) for exposures north, east, and south of the Bearpaw Mountains in central Montana. It was further described by Jensen and Varnes (1964) in Garfield, McCone, and Valley counties, Montana. It is approximately 1440 ft (439 m) thick in this area and lies between the Judith River Formation below and the Fox Hills Formation above. It consists of dark gray clayey and silty shale, with intermittent bentonites. Most fossils occur in small to medium size concretions, although a few occur in larger septarian concretions. In the stratigraphic section prepared by W.A. Cobban et al. (personal com-mun., 1948) reproduced here (fig. 3), the Baculites compressus, B. jenseni, B. eliasi, B. baculus, and B. grandis zones are present. We have identified specimens of Hoploscaphites peterseni from limestone concretions at USGS loc. 22142.
Pierre Shale, East-Central Montana
Background: Most of the specimens in our study are from the Cedar Creek Anticline, which represents a major structural feature demarcating the southwestern flank of the Williston Basin, Montana (Clement, 1986; Peterson and Maccary, 1987). The anticline extends southeast approximately 235 km from northwest of Glendive, Montana, to just west of Buffalo in northwestern South Dakota. According to Clement (1986: 236), “the present Cedar Creek axis was breached during epeirogenic uplift of middle Tertiary time that removed at least 460 m of Paleocene and Upper Cretaceous strata.” The soft Pierre Shale is exposed along the axis of the anticline and the more resistant Fox Hills, Hell Creek, and Fort Union formations are exposed on the flanks (Linn, 2010: Grier et al., 2019).
This is one of the classic Cretaceous localities first explored by Ferdinand V. Hayden in the 1850's (frontispiece). Hayden, along with Fielding B. Meek, both young assistants of New York State Geologist James Hall, began their joint field trips in the area of the present-day Black Hills, South Dakota, in 1853. Later, under partial support from the Smithsonian Institution, Hayden spent the summer of 1854 in the region around Fort Union (located in Williams and McKenzie counties, North Dakota, and Roosevelt and Richland counties, Montana), collecting fossils on the Cedar Creek Anticline along the Yellowstone River and at the mouths of the Powder, Tongue, and Bighorn rivers. After returning home to Rochester, New York, he later spent the summer of 1855 around Fort Benton, Montana, collecting fossils along the Missouri River and its tributaries under the aegis of Alexander Culbertson, the agent in charge of all the forts in the Upper Missouri and Yellowstone rivers.
In January, 1856, Hayden stopped in St. Louis, bringing with him his fossil haul from the previous two years. According to Foster (1994: 66), the collection presented “an extraordinary harvest: six tons of specimens accumulated over two years, including more than a thousand pounds of fossils he wanted to work up with Meek, which he expected would occupy them for five years.” Meek saw some of the specimens in early February 1856, pronouncing them “grand—magnificent. All of them as perfect as recent shells. There are not less than 50 species most of which are new” (quoted in Foster, 1994: 67).
Meek and Hayden published checklists and descriptions of these fossils in installments starting in 1856, culminating in Meek's massive monograph of 1876, containing the full description of Hoploscaphites plenus. Although Hayden made additional field trips out west in the intervening years, Meek's monograph was based on material collected in 1854–1855. According to Hayden (in Meek, 1876: iii, iv), “The accumulation of the materials which compose this volume was commenced in the spring of 1854, and the greater number of the new species of fossils were discovered by the writer of this letter during that and the succeeding year.”
By the late 1800's, the Cedar Creek Anticline was a popular destination for fossil collecting. Interestingly, many of the specimens in U.S. museums that date from that era cite the locality as Mingusville, Montana. This name does not appear on any map today. According to Landman et al. (2018), the name originated as a contraction of two names: Gus Grisy and his wife, Minnie, who ran a cattle ranch at the time (hence the name Min-gus). In 1893, the name was officially changed to Wibaux in recognition of another rancher, Pierre Wibaux. A statue of Wibaux stands a short distance west of the town, which lies on the northern edge of the anticline in Wibaux County, Montana.
Litho- and biostratigraphy: The litho- and biostratigraphy of the Upper Cretaceous part of the Cedar Creek Anticline has been recently reviewed by Landman et al. (2018a, 2019) and Grier et al. (2019). The Pierre Shale consists of light to dark gray, fissile, silty or sandy shale 60–65 m thick, interbedded with bentonites and bentonitic shale. It contains iron manganese (Fe-Mn), limestone, and sandstone concretions, some of which are abundantly fossiliferous. The Pierre Shale becomes progressively siltier near the top and is overlain by the Fox Hills Formation. The Pierre Shale is late Campanian to early Maastrichtian in age and contains the upper part of the Baculites eliasi, B. baculus, and lower part of the B. grandis zones (fig. 4).
The Baculites eliasi Zone is approximately 38 m thick, representing slightly more than one-half the thickness of the Pierre Shale in the area (fig. 5E, F). The age of this zone is 72.50 ± 0.31 Ma (fig. 1B). Specimens of B. eliasi Cobban, 1958, are present in iron manganese (Fe-Mn) and limestone concretions, and occasionally loose in the sediment as body chamber casts. The abundance of B. eliasi diminishes toward the top of the zone to the point where specimens are very rare. Gill and Cobban (1966) and Slattery et al. (2018) observed a similar reduction in the number of specimens of B. eliasi toward the top of the zone in east-central Wyoming. In fact, the rarity or near-absence of B. eliasi, and B. baculus Meek and Hayden, 1861, from the overlying zone, has led to uncertainty in the precise placement of the Campanian/Maastrichtian boundary, a problem in the Western Interior in general (Gill and Cobban, 1966; Riccardi, 1983). The Campanian/Maastrichtian boundary appears to be linked to an interval of global cooling, based on studies of sections from the U.S. Gulf Coastal Plain and elsewhere (see Linnert et al., 2018, and references therein).
In the northwestern part of the Cedar Creek Anticline, Bishop (1967, 1973) documented a discontinuous layer of brownish-tan to yellowish weathering, horizontally laminated sandstone concretions that he referred to as the “bedded concretions.” They are associated with small (15–20 cm in maximum length), whitish-gray weathering, round to flat carbonate concretions (figs. 4, 5B-D). Both the bedded concretions and the small whitish-gray concretions occur in a light-gray sandy shale. A few specimens of Baculites eliasi are present less than 1 m below the layer of bedded sandstone concretions. Fossils are rare in the bedded concretions themselves, but a few specimens of B. baculus, Endocostea typica (Whitfield, 1877), Nostoceras sp., and Hoploscaphites sp., are present (fig. 4D). The co-occurrence of B. baculus and E. typica marks the base of the B. baculus and E. typica zones, respectively, indicating the base of the Maastrichtian.
We studied the sedimentology of the bedded sandstone concretions using petrologic thin sections of a single concretion collected in situ. The concretion shows stratigraphic variation in grain size, mineral composition, and degree of lithification from bottom to top. The lower part of the concretion is very fissile and soft, and does not display any primary sedimentary structures in hand samples or thin section. Ferruginous grains are visible and stand out from the surrounding muddy matrix (fig. 6E, F). The middle part of the concretion exhibits the highest degree of lithification and breaks into parallel laminations that may reflect remnant bedding planes. This part of the concretion consists of well-sorted, fine sand-sized quartz grains associated with iron-manganese and ferruginous grains, which are larger than those in the lower part of the concretion (fig. 6B, C). The quartz grains show sutured boundaries (edges of the grains are pressed together with no cement between). Fecal pellets and longer filaments of unknown origin are rare (fig. 6B, C). The upper part of the concretion breaks into thin (∼1 cm thick), friable laminations. Ferruginous grains are present and similar in size and composition to those in the middle part of the concretion, but much less abundant (fig. 6A). This variation in grain size, amount of quartz, and degree of lithification in the concretion may reflect the temporal change in the composition of the sediments on the sea floor as well as diagenetic overgrowths associated with concretion formation.
Methane seep deposits occur in close association with the bedded sandstone concretions, as described in Landman et al. (2019) and Grier et al. (2019). We have documented more than five such deposits, each of which is limited in extent, ranging from 1 to 3 m in diameter (fig. 5A). The deposits consist of hard, vuggy limestone, weathering out from the surrounding darker shale. Ryan et al. (in press) examined one of these deposits in detail and analyzed the paleoecologic composition of the fossil assemblage. They reported that most of the species consist of infaunal suspension feeders dominated by lucinid bivalves. Specimens of Hoploscaphites are present, albeit rare, but specimens of Baculites are absent altogether.
Approximately 3 m above the bedded sandstone concretions is a layer of richly fossiliferous limestone concretions that Bishop (1967, 1973) called the “scaphite concretions,” which are the source of many of the scaphites used in this study. The scaphite concretions are overlain by a 2 m thick interval of “bentonitic shale” capped by a 7–12 cm thick bentonite. This layer of bentonitic shale is a prominent feature of the landscape on the Cedar Creek Anticline. It has been referred to as a “bentonitic shale” due to the fact that the outcrop is covered with bentonite weathering down from above (Bishop, 1967, 1973; Linn 2010; Landman et al., 2019; Grier et al., 2019). It is also possible that the shale itself contains traces of ash, but this requires further study.
The lowest layer of concretions above the bentonite contains “Inoceramus” incurvus Meek and Hayden, 1856, which marks the base of the “I.” incurvus Zone (= base of the upper part of the Baculites baculus Zone) (figs. 4, 5A). The sediments coarsen upward toward the top of the Pierre Shale, which consists of a 3 m thick interval of silty shale. Gray limestone concretions contain specimens of Baculites grandis Hall and Meek, 1855, and, more rarely, Trochoceramus radiosus (Quaas, 1902), marking the base of the B. grandis and T. radiosus zones, respectively.
As noted above, most of the specimens of Hoploscaphites in our study are from the scaphite concretions in the lower part of the Baculites baculus Zone. We tabulated the biostratigraphic distribution of a subsample of 53 specimens from the Cedar Creek Anticline that were collected with tight stratigraphic control (fig. 4). We divided them into the B. eliasi, lower B. baculus, upper B. baculus, and lower B. grandis zones. Of 21 specimens of H. crassus, 1 occurs in the B. eliasi Zone and 20 in the lower B. baculus Zone. Of 20 specimens of H. plenus, 12 occur in the lower B. baculus Zone, 7 in the upper B. baculus Zone, and possibly 1 in the lower B. grandis Zone. Of 12 specimens of H. peterseni, 7 occur in the lower B. baculus Zone, 4 in the upper B. baculus Zone, and possibly 1 in the lower B. grandis Zone. Whether these numbers are an indication of actual abundance or simply a reflection of taphonomic bias is unknown, but probably a bit of both.
Age of the Baculites baculus Zone: The bentonite at the top of the “bentonitic shale” occurs at the boundary between the lower and upper parts of the Baculites baculus Zone (figs. 4, 5B). One of us (TL) excavated the outcrop to expose fresh material, which was bagged immediately for later analysis. Sanidine was isolated from the bentonite using standard magnetic and density separation techniques and verified using a variable pressure scanning electron microscope. Sanidine separates were irradiated along with the 28.201 Ma Fish Canyon sanidine standard (Kuiper et al., 2008) at the Oregon State University TRIGA reactor in the cadmium-lined in-core irradiation tube (CLICIT). Single crystal fusion experiments were performed with a 50 W CO2 laser in the WiscAr laboratory at the University of Wisconsin-Madison. Gas was analyzed using a Noblesse multi-collector mass spectrometer following the procedures in Jicha et al. (2016). Weighted mean ages were calculated using the decay constants of Min et al. (2000), and are reported with analytical uncertainties at the 95% confidence level.
Thirty single crystal fusion dates from the bentonite in the Baculites baculus Zone yielded a weighted mean 40Ar/39Ar age of 71.96 ± 0.08 Ma (supplementary fig.1; supplementary table 1: https://doi.org/10.5531/sd.sp.45). The nine youngest single crystal fusion dates from the B. eliasi Zone in Garfield County, Montana (Cobban et al., 2006), yielded a weighted mean 40Ar/39Ar age of 72.47 ± 0.07 Ma. Our new age for the B. eliasi Zone is indistinguishable from the age of 72.50 ± 0.31 Ma that was originally reported in Cobban et al. (2006) and subsequently recalculated in Landman et al. (2018b: fig. 1). These two new ages from the middle of the B. baculus Zone and the B. eliasi Zone bracket the Campanian/Maastrichtian boundary, and are consistent with its previously reported age of 72.1 ± 0.2 Ma (Lynds and Slattery, 2017).
Environment of Deposition: The environment of deposition of the scaphite concretionary horizon in the lower Baculites baculus Zone of the Pierre Shale on the Cedar Creek Anticline has recently been studied by Landman et al. (2015b). During the early Maastrichtian, the shoreline of the WIS was approximately 80 km to the south along the margin of the Sheridan Delta, as described by Reiskind (1975). The depth of the WIS at this site was approximately 50 m (Landman et al., 2018a). A high incidence of freshwater fungae was not reported from slightly older deposits (B. compressus Zone) of the Bearpaw Shale of north-central Montana, suggesting a source of riverine input in the area (Palamarczuk and Landman, 2011).
The sediments in the scaphite concretionary horizon consist of dark, silty mudstone indicative of a soft muddy bottom. The mudstone is finely bioturbated, suggesting that the sediments were well oxygenated. No primary sedimentary structures are visible, although they may have been destroyed by bioturbation. If they were not destroyed, their absence suggests a lack of currents on the bottom. The rate of sedimentation was probably high, based on the preservation of numerous cephalopod jaws (see below). The preservation of cephalopod jaws is usually interpreted as an indicator of rapid sedimentation and burial because, according to modern experiments, these structures begin to disintegrate after a few years on the sea floor (see Kear et al., 2015). In addition, most of the phragmocones of the ammonites are hollow or filled in with secondary calcite rather than sedimentary matrix. Equally, the apical whorls of gastropods are filled in with secondary calcite instead of matrix, suggesting that they were also rapidly buried before they could be filled in with resuspended sediment.
Landman et al. (2015b) investigated a single concretion from the scaphite concretionary horizon (cover photo). It contains both nekton and benthos. Among the nekton, are approximately 90 specimens of scaphites, most of which belong to Hoploscaphites crassus. The majority of these specimens are adults (see fig. 7), although a few smaller specimens are also present. Only 10 specimens of Baculites are present, all of which are fragments of juveniles. Landman et al. (2015b) also recorded a single coleoid gladius. In addition, the concretion contains 35 cephalopod jaws, nearly all of which are attributed to Hoploscaphites. The only other evidence of nekton is a couple of fish bones.
In terms of benthos, the scaphite horizon is dominated by molluscs. Not surprisingly, given the soft substrate, most of the bivalves are infaunal and include Nucula, Nuculana, and Yoldia. The epifauna include Pecten (Chlamys), Oxytoma, Anomia, and Endocostea. Gastropods are dominated by carnivores/scavengers and include Drepanochilus. Of the other fauna, scaphopods are represented by two species, both of which are semiinfaunal carnivores. Landman et al. (2015b) also noted the presence of a few echinoids, bryozoans, and corals.
Because several of the ammonite shells were very well preserved, they were utilized for isotopic analysis to infer the temperature of the bottom water. In the two best-preserved specimens of Hoploscaphites plenus, the average value of δ18O is -2.12‰ (Landman et al., 2015b: table 4). Assuming that the ammonites secreted their shells in isotopic equilibrium with seawater, as in modern nautilus (Landman et al., 1994), and that the scaphites lived near the bottom (Landman et al., 2012), these values reflect the ambient temperature. Using the aragonite-temperature equation of Grossman and Ku (1986), and assuming an average value of δ18O of Cretaceous sea water of -1.0‰ (Shackleton and Kennett, 1975; Dennis et al., 2013), the average value of δ18O of the two best-preserved samples equates to 27.0° C. This value is similar to temperatures calculated by Landman et al. (2018a) for the upper Baculites baculus and lower B. grandis zones of the Pierre Shale at the same site. It is also nearly identical to the average temperature calculated by Kruta et al. (2014) for the slightly older upper Campanian Baculites sp. smooth Zone of the Pierre Shale in South Dakota based on ammonite shells and aptychi.
Predation: Injuries due to predatory damage are common in the scaphite concretionary horizon in the lower Baculites baculus Zone of the Pierre Shale. Unrepaired injuries indicate that the anaimals died as a result of the attacks. Such injuries are manifested by missing pieces of shell, usually on the adapical end of the body chamber. Keupp (2006) referred to these injuries as “forma aegra fenestra” because of their resemblance to windowlike openings. The consistent position of these injuries is a clue that they occurred during the lifetime rather than after the death of the animal (Radwański, 1996; Larson, 2003, 2007; Keupp, 2006; Klompmaker et al., 2009).
The scaphite concretionary horizon contains many examples of such injuries. In AMNH 85450 (fig. 8C), a macroconch of Hoploscaphites crassus, part of the shell is missing along the venter starting in the shaft and extending to the hook, leaving a hole with jagged edges. In AMNH 85444 (fig. 8B), another macroconch of H. crassus, a hole appears on the adapical end of the body chamber. It is 25 mm in diameter with jagged edges. Similarly, in AMNH 85473 (fig. 8A), a macroconch of H. peterseni, a chunk of shell is missing from the right side and venter of the shaft.
The position of these injuries on the venter and ventrolateral flanks on the adapical end of the body chamber indicates that the scaphites were attacked from behind (Larson, 2003; Landman et al., 2012). Such an attack would have allowed the predator to gain access to the muscles and viscera of the animals. These attacks would have come as an unwelcome surprise to the scaphites because their eyes were probably located on the other side of the shell in the pair of reentrants along the apertural margin. The attacks would also have been fatal to the scaphites because the injuries were too far back from the mantle edge to be repaired (Landman and Waage, 1986; Kröger, 2002a, 2002b; Klompmaker et al., 2009). Possible predators included fish, turtles or other reptiles, crustaceans, and coleoids (Landman and Waage, 1986; Larson, 2003; Keupp, 2006; Klompmaker, 2009).
Scaphite jaws: One of the conspicuous features in the scaphite concretionary horizon, as noted above, is the high incidence of scaphite jaws (figs. 9, 10C, D). In contrast, such jaws are rare in the upper part of the B. baculus Zone and are absent altogether in the B. grandis Zone. The jaws in the scaphite concretionary horizon occur either inside the body chamber or in close juxta- position with the ammonite (figs. 9A–F, 10C, D). Lower jaws are much more common than upper jaws (Landman et al., 2015b). This preservational bias possibly reflects the larger size and bulkier shape of the lower jaws.
The morphology of these jaws is similar to that of the jaws described by Landman et al. (2010: 55–62) from the Baculites compressus–B. cuneatus zones of the Pierre Shale. The upper jaw is U-shaped with two narrow wings that converge anteriorly to a beaklike apex (fig. 9G). Usually, only the anterior tip of the upper jaw is preserved. The lower jaw is convex and consists of two wings in mirror image that meet along a plane of bilateral symmetry called the commissure (fig. 9D–F). The commissure is bordered by a flange on each side, which reaches its maximum height just before the posterior margin. The apex is weakly projected forward, and the anterior margin is slightly concave on either side.
Each wing of the lower jaw is composed of two layers: (1) an inner layer of black material, approximately 40 um thick, which presumably represents diagenetically altered chitin and (2) an outer layer of calcite known as the aptychus, approximately 100 um thick (fig. 9J) (for further discussion of the microstructure of the outer layer, see Kruta et al., 2009). The ventral surface of the aptychus is ornamented with growth lines and fine lirae that parallel the lateral and posterior margin. In jaws from the scaphite concretionary horizon, the black layer of the lower jaw is much more commonly preserved than the calcitic layer. The rarity of the calcitic layer is probably due to mechanical damage or chemical dissolution prior to the formation of the enclosing concretion (for a discussion on the diagenetic disappearance of the calcitic layer, see Landman et al., 2006).
Some jaws show evidence of tearing, warping, and compaction, testifying to their residence time on the sea floor (for further details, see Environment of Deposition). In addition, several jaws, such as AMNH 64498 (fig. 9H, I), bear puncture marks that must have been produced by predation. Presumably, the predator crushed part or all of the body chamber and ingested the soft body including the jaws. The jaws would have subsequently been deposited as fecal matter after passing through the digestive track of the predator. Alternatively, the jaws could have been regurgitated by the predator because they were indigestible.
The incidence of scaphite jaws in the lower part of the Baculites baculus Zone on the Cedar Creek Anticline is similar to that in the Hoploscaphites nicolletii and H. nebrascensis zones of the Fox Hills Formation in north-central South Dakota (Landman and Waage, 1993). The incidence is higher than that in the B. compressus–B. cuneatus zones of the Pierre Shale in southwestern South Dakota (Landman et al., 2010; Landman and Klofak, 2012). Such differences may reflect variation in the rate of burial of shelly debris on the sea floor and the timing of formation of the surrounding concretions. Such differences may also reflect variation in the circumstances under which the particular animals died, and the length of time that they floated after death. In Hoploscaphites, the constricted aperture of the body chamber would have prevented the soft body from immediately falling out after death, favoring the preservation of jaws.
Terms and Methods
In our overview of morphological variation, evolutionary patterns, and systematic descriptions, we utilize a number of terms to describe scaphite morphology, specifically as they apply to Hoploscaphites. The adult shell of Hoploscaphites consists of a closely coiled phragmocone and a slightly to strongly uncoiled body chamber (fig. 7A, B). The adult phragmocone is the part of the phragmocone that is exposed in the adult shell. The point of exposure is the most adapical point of the adult phragmocone. An unpaired muscle scar appears on the venter just adoral of the end of the phragmocone (fig. 10A, B). It is small (2–5 mm in maximum length, depending on the size of the specimen) and oval in shape. The body chamber consists of the shaft, beginning at the last septum, and a hook terminating at the aperture. The point of recurvature is the point at which the adapertural part of the body chamber recurves dorsally.
Measurements of the adult shell are illustrated in figure 7. All measurements were made using electronic calipers on actual specimens, rather than on photos.
Maximum length of the adult shell (LMAX) = the length from the venter of the adult phragmocone to the venter of the hook
Umbilical diameter of the adult shell (UD) = the diameter of the umbilicus parallel to the line of maximum length
W = maximum whorl width
H = maximum whorl height measured from the umbilical seam to the midventer
WP1, HP1 = whorl width and whorl height, respectively, at the adapical end of the adult phragmocone, 90° adapical of the line of maximum length
WP2, HP2 = whorl width and whorl height, respectively, at the adoral end of the adult phragmocone, along the line of maximum length
WS, HS = whorl width and whorl height, respectively, at the midshaft of the body chamber
WH, HH = whorl width and height, respectively, at the point of recurvature
VS = width of the venter at midshaft between ventrolateral margins on opposite sides of the venter.
In describing specimens, we note the whorl height at which maximum whorl width occurs. For example, the statement that maximum whorl width occurs at ⅓ whorl height means that it occurs at ⅓ whorl height from the umbilical seam. We calculated several ratios to describe the shape of the adult shell and facilitate comparisons among specimens. The ratios of whorl width to whorl height were calculated at four points on the shell (WP1/HP1, WP2/HP2, WS/HS, WH/HH), as described above, and provide a measure of the degree of whorl compression. The ratio of ventral width to whorl height at midshaft (VS/HS) provides an additional measure of the degree of whorl compression. The inverse of this ratio (HS/VS) expresses the relationship between the height of the whorl and the width of the venter, so that a value of 1.5 implies that the height of the whorl is 1.5× the width of the venter.
The ratio of maximum length to whorl height of the phragmocone along the line of maximum length (LMAX/HP2) is a measure of the degree of uncoiling. The ratio of maximum length to whorl height at midshaft in macroconchs (LMAX/HS) is a measure of the degree of curvature of the body chamber in lateral view. This ratio applies only to macroconchs because the umbilical shoulder of the body chamber in these forms usually coincides with the line of maximum length, and thus the whorl height (HS) is the distance from the line of maximum length to the venter of the body chamber (equivalent to the radius in the case of a semicircle). The apertural angle was measured on photographs of specimens in lateral view. A line was drawn along the umbilical shoulder and another line was drawn along the apertural margin. The apertural angle is the angle of intersection between these two lines, extending from approximately the point of recurvature to the aperture. This measurement applies only to macroconchs.
The terms used to describe ornamentation were reviewed by Landman et al. (2019). Primary ribs originate near the umbilicus, whereas secondary ribs originate on the flanks or venter, either by branching or intercalation. The density of ribs was measured by counting the number of ribs/cm on the venter at four points on the adult shell: (1) the adapical end of the phragmocone, (2) the adoral end of the phragmocone, (3) the midshaft, and (4) the hook. In addition to ribs, the ornamentation consists of tubercles. Umbilicolateral tubercles occur near the umbilicolateral margin, ventrolateral tubercles near the ventrolateral margin, and lateral tubercles on the flanks (fig. 7). The statement that ventrolateral tubercles occur at ⅞ whorl height means that they occur at ⅞ whorl height from the umbilical seam. We recorded the number of ventrolateral, umbilicolateral, and lateral tubercles on the phragmocone and body chamber of the adult shell, in addition to the distances between tubercles, following the curvature of the shell. We also noted the size and shape of the tubercles as well as the number of ribs that join a tubercle dorsally and the number of ribs that branch from it ventrally.
Intra- and Interspecific Variation
In this study, we followed a traditional typological approach in defining species. Our collections consist of large numbers of well-preserved specimens that retain their original dimensions, allowing precise measurements and detailed examination of their morphology. In addition, many specimens are derived from single horizons from the same area, providing snapshots, albeit blurry, of living populations (for a recent discussion of time averaging, see Foote et al., 2007). In describing species, we rely on all morphological traits, including ornamentation, shell shape, size, and sutures. The fact that the mature stage of Hoploscaphites is well defined due to the uncoiling of the body chamber permits an unequivocal separation of variation due to ontogeny (different developmental stages) from phenotypic variation among adults.
One source of adult variation is sexual dimorphism. In general, ammonite dimorphs are referred to as macroconchs and microconchs. Following the traditional view, macroconchs are interpreted as females and microconchs as males (Lehmann, 1981; Davis et al., 1996; Klug et al., 2015). The dimorphs of Hoploscaphites are distinguished by differences in size and morphology (fig. 7A, B). Macroconchs usually attain a larger size than microconchs, but the size range of the two dimorphs overlap (Landman et al., 2010). The outline of the umbilical shoulder of the body chamber relative to that of the venter in side view is a reliable means of distinguishing dimorphs. The umbilical shoulder of the body chamber is straight in macroconchs whereas it is curved in microconchs, following the outline of the venter. In addition, the umbilical wall is nearly flat and subvertical in macroconchs whereas it is broad and outwardly sloping in microconchs.
Another source of variation is size at maturity within each dimorph. For example, we have observed a wide range of variation in the size of adult macroconchs of Hoploscaphites crassus and H. plenus. In H. crassus, the size of the smallest macroconch is 67.7 mm and the size of the largest macroconch is 131.0 mm. In H. plenus, the size of the smallest macroconch is 71.8 mm and the size of the largest macroconch is 130.7 mm. Thus, in both of these species, the ratio of the size of the largest macroconch to that of the smallest is nearly two times. Landman et al. (2010) observed a similar size difference in species of Hoploscaphites from the Baculites compressus–B. cuneatus zones of the Pierre Shale. Such variation may reflect differences in the age at which individuals mature. If all specimens grew at approximately the same rate, smaller specimens would have attained maturity at younger ages (for an extended discussion about size-age variation, see deBaets et al., 2015).
In addition to variation within species, we have observed broad variation between species. In many instances, a single specimen is intermediate between two species. For example, some of the specimens in our collection exhibit a broadly inflated whorl section and were, therefore, attributed to Hoploscaphites crassus. However, the ventrolateral tubercles on the body chamber are large and widely spaced, more closely resembling the pattern in H. plenus. Similar examples of intermediate specimens exist between H. crassus and H. peterseni and between H. peterseni and H. plenus. One possible explanation for this pattern is that all three species represent one biological species with a broad range of intraspecific variation or, alternatively, three subspecies within a single species. We treat them as three separate species because intermediate specimens are relatively rare and because the three species can be readily distinguished from each other based on the diagnoses outlined below.
It is also possible that these three species represent a “flock” of very closely related forms, similar to the “species flocks” observed in modern cichlid fishes (for a discussion about this phenomenon, see Salzburger et al., 2002). Indeed, all three species lived at the same time and inhabited the same geographic area. In addition, all of them share a similar pattern of ornamentation consisting of long, thin, nonbifurcating ribs on the adoral part of the phragmocone, suggesting that they constitute a single monophyletic clade. They differ in the degree of whorl compression and the size and spacing of ventrolateral tubercles. This concept of species flocks has, in fact, been used to explain the explosive radiation of acanthoceratid ammonites in the WIS, as mediated by heterochronic change (Yacobucci, 1999). It may equally apply to the origin of these three species of Hoploscaphites during the early Maastrichtian, following an episode of global cooling. However, the isolation mechanisms that served to separate populations and promote speciation remain obscure (e.g., sea level change, formation of isolated embayments, etc.).
Evolutionary Patterns
The diversity of morphological characters in Hoploscaphites include shell size, shell shape, ornamentation, degree of uncoiling, and sutures, among others. All these features appear in multiple character states. For example, ventrolateral tubercles on the adult body chamber can be closely or widely spaced, small (2 mm high) or large (6 mm high), conical or clavate, etc. Ribs can be rursiradiate, rectiradiate, or prorsiradiate. In addition, the various character states for any particular character can occur in combination with different character states for other characters, leading to varied and novel permutations. For example, small ventrolateral tubercles can cooccur with inflated whorl sections or compressed whorl sections. Large ventrolateral tubercles can cooccur with fine, closely spaced ribs or coarse, widely spaced ribs. This panoply of combinatorial outcomes produces a seemingly endless variety of forms building on a single theme.
Despite this variability, we have noted evidence of morphological integration, that is, the nonrandom, persistent cooccurrence of certain character states. In particular, we have noted a correlation between the degree of whorl compression/depression of the shell and the incidence of lateral tubercles. This is apparent in a comparison between macroconchs of Hoploscaphites crassus, H. plenus, and H. peterseni, on the one hand, and H. macer, H. criptonodosus, and H. sargklofak, on the other hand. The first three species are most abundant in the lower Baculites baculus Zone and the second set of species are most abundant in the upper B. baculus Zone and the B. grandis Zone.
The degree of whorl compression/depression of the shell is expressed by the ratio of whorl width to whorl height at midshaft (WS/HS). This ratio averages 1.31 in Hoploscaphites crassus (table 1), 1.09 in H. plenus (table 3), 0.99 in H. peterseni (table 5), 0.90 in H. criptonodosus (fig. 11), 0.81 in H. macer (fig. 11), and 0.70 in H. sargklofak (fig. 11). The ratio of ventral width to whorl height at midshaft (VS/HS) provides an additional measure of the degree of whorl compression/depression. This ratio averages 0.87 in H. crassus (table 1), 0.68 in H. plenus (table 3), 0.58 in H. peterseni (table 5), 0.43 in H. criptonodosus (fig. 11), 0.40 in H. macer (fig. 11), and 0.35 in H. sargklofak (fig. 11).
Lateral tubercles are rare or absent on shells of Hoploscaphites crassus, H. plenus, and H. peterseni (fig. 11). A maximum of two tubercles have been reported in each of these species (Meek, 1876; Riccardi, 1983). The two tubercles occur on the adapical end of the phragmocone. A single row of five lateral tubercles has been reported in H. macer (fig. 11). They appear on the adapical end of the phragmocone and persist for ½ whorl (Landman et al., 2019). In contrast, lateral tubercles are common on the shells of H. criptonodosus and H. sargklofak (fig. 11). In H. criptonodosus, two rows of lateral tubercles with a combined total of 12 tubercles are present on the adapical part of the exposed phragmocone and persist for as much as ½ whorl (Landman et al., 2019). In H. sargklofak, two rows of lateral tubercles, with a combined total of 13 tubercles, are present on the exposed phragmocone (Landman et al., 2015a). In addition, a single row of as many as five lateral tubercles extends from the adoral end of the shaft to the aperture, so that the total of lateral tubercles on the exposed shell of this species is 18.
The plot of WS/Hs vs VS/HS for these six species is shown in figure 11A. The shape of the shell is more compressed in geologically younger species. In addition, the degree of shell compression is correlated with the number of lateral tubercles (fig. 11B). This correlation is not random but undoubtedly mirrors the change in habitat associated with the appearance of the new species. As noted above, the transition from the Baculites eliasi to B. grandis zones at Red Bird, Wyoming, and the Cedar Creek Anticline, Montana, corresponds to a change to a higher energy, more nearshore environment, reflecting the progressive migration of the western shoreline of the WIS toward the east (fig. 1). The more compressed shell shapes of Hoploscaphites criptonodosus, H. macer, and H. sargklofak would have been more advantageous in such an environment compared to the more depressed shell shapes of H. crassus, H. plenus, and H. peterseni (for a recent discussion of hydrodynamics in ammonites, in general, see Naglik et al., 2015, and in scaphites, in particular, see Peterman et al., 2020). Similarly, the increased tuberculation in the geologically younger species may also be related to the transition to a more nearshore environment, with a simultaneous increase in the number and kinds of predators. The acquisition of lateral tubercles would have provided additional protection against such predators, as suggested by Landman and Waage (1986, 1993), Landman et al. (2010), and Takeda et al. (2016).
Repositories
The repository of specimens described in the text is indicated by a prefix, as follows: Department of Invertebrate Paleontology, American Museum of Natural History (AMNH), New York; Academy of Natural Sciences of Drexel University (ANSP); Black Hills Institute of Geological Research (BHI), Hill City, South Dakota; the Field Museum (FMNH), Chicago, Illinois; Geological Survey of Canada (GSC), Ottawa, Canada; Rutgers University Geological Museum (RUGM), New Brunswick, New Jersey; Yale Peabody Museum (YPM), New Haven, Connecticut; and U.S. National Museum (USNM), Washington, D.C. The localities of the specimens are listed in the appendix.
SYSTEMATIC PALEONTOLOGY
Class Cephalopoda Cuvier, 1797
Order Ammonoidea Zittel, 1884
Suborder Ancyloceratina Wiedmann, 1966
Superfamily Scaphitoidea Gill, 1871
Family Scaphitidae Gill, 1871
Subfamily Scaphitinae Gill, 1871
Genus Hoploscaphites Nowak, 1911
[= Mesoscaphites Atabekian, 1979: 523 (nomen nudum) fide Kennedy, 1986; Wright, 1996; Jeletzkytes Riccardi, 1983: 14]
Type Species: Ammonites constrictus J. Sowerby (1817: 189, pl. A, fig. 1), by original designation.
Diagnosis: “Small to large scaphites, strongly dimorphic, with broad variation in degree of whorl compression ranging from slender to robust, with involute phragmocone, short to long shaft, and weakly recurved hook; apertural angle ranging from approximately 35° to 85°; aperture constricted with dorsal projection; ribs straight to flexuous, increasing by branching and intercalation, with weak to strong adoral projection on venter; adult shell with or without umbilicolateral, flank, and ventrolateral tubercles; suture fairly indented, with symmetrically to slightly asymmetrically bifid first lateral lobe” (Landman et al., 2010: 93).
Hoploscaphites crassus
(Coryell and Salmon, 1934)
Figures 9H, I, 10B–D, 12–31, 32A, B, 33–40
Macroconch Synonomy
1885. Scaphites subglobosus. Whiteaves, p. 52 (pars), pl. 8, fig. 2 only; non pl. 7, fig. 3; non pl. 8, fig. 1.
1917. Scaphites subglobosus Whiteaves. Dowling, p. 32 (pars), pl. 31, fig. 2 only (= Whiteaves, 1885, pl. 8, fig. 2); non pl. 31, fig. 1.
1934. Acanthoscaphites nodosus crassus. Coryell and Salmon, p. 15, figs. 10, 11.
1934. Acanthoscaphites duplico-nodosus. Coryell and Salmon, p. 17, figs. 12, 13.
1983. Jeletzkytes crassus (Coryell and Salmon, 1934). Riccardi, p. 20, pl. 9, figs. 3, 4; text-figs. 9, 13b (suture and cross section, respectively) (= Coryell and Salmon, p. 15, figs. 10, 11); pl. 8, figs. 5, 6; text-fig. 10 (suture) (= Coryell and Salmon, p. 17, figs. 12, 13).
1983. Jeletzkytes cf. crassus (Coryell and Salmon, 1934). Riccardi, p. 20, pl. 7, figs. 3–5; pl. 8, figs. 1–4; pl. 22, figs. 2–4 (= Whiteaves, 1885, p. 52, pl. 8, fig. 2); text-figs. 11, 12, 13c (two sutures and cross section, respectively).
1997. Jeletzkytes crassus (Coryell and Salmon, 1934). Larson et al., p. 79, 80, unnumbered figs.
2016. Jeletzkytes crassus (Coryell and Salmon, 1934). Klein, p. 137.
Microconch Synonomy
1876. Scaphites nodosus var. quadrangularis. Meek, p. 428 (pars), pl. 25, fig. 4 only; non fig. 2a-c (= Hoploscaphites brevis microconch); non fig. 3a-c (= Hoploscaphites plenus microconch).
1977. Hoploscaphties nodosus quadrangularis (Meek and Hayden). Kauffman, pl. 32, fig. 8 (= Meek. 1876, pl. 25, fig. 4).
1983. Jeletzkytes cf. brevis (Meek) ♂. Riccardi, p. 25, pl. 10, figs. 1, 2 (= Meek. 1876, pl. 25, fig. 4).
1997. Jeletzkytes crassus (Coryell and Salmon, 1934). Larson et al., p. 79, 80, unnumbered figs.
1997. Jeletzkytes “quadrangularis” (Meek and Hayden, 1860). Larson et al., p. 78, unnumbered fig. (= Meek. 1876, pl. 25, fig. 4).
2010. Hoploscaphites plenus (Meek, 1876), microconch. Landman, p. 64, fig. 6A–C (= Meek, 1876, pl. 25, fig. 4).
Emended Diagnosis: Macroconchs medium to large in size, globose; whorl cross section of shaft depressed reniform with well-rounded flanks and broadly rounded venter; width of venter approximately 90% whorl height; small, deep umbilicus; prominent umbilical bulge; apertural angle averaging 60°; long, fine, straight, closely spaced ribs on adoral part of phragmocone, with little branching or intercalation, and moderately strong adoral projection on venter; long, fine, weakly concave, moderately widely spaced ribs on shaft, with moderately strong adoral projection on venter; umbilicolateral tubercles absent or small and closely spaced on phragmocone, becoming slightly larger and more widely spaced on body chamber; ventrolateral tubercles small and closely spaced on phragmocone at ⅞ whorl height, becoming slightly larger and more widely spaced on body chamber, usually persisting to aperture. Microconchs medium to large in size, robust, and more loosely uncoiled than macroconchs; umbilical wall of shaft broad and outwardly sloping; pattern of ornament similar to that of macroconchs, with relatively more prominent umbilicolateral tubercles. Suture deeply incised with broad-stemmed asymmetircally bifid first lateral saddle.
Types: The holotype is AMNH 95774 (= formerly AMNH 24234) (fig. 13) from approximately 100 feet (30.3 m) below the top of the Pierre Shale, a little west of the center of T. 14 N., R. 55 E., near Glendive, Dawson County, Montana (Coryell and Salmon, 1934: 15, figs. 10, 11). It was refigured by Riccardi (1983: pl. 9, figs. 3, 4) and is a steinkern with shell material preserved on the adoral part of the phragmocone. Riccardi (1983) pointed out that the specimen of Acanthoscaphites duplico-nodosus of Coryell and Salmon (1934: 17, figs. 12, 13) is a fragment of a phragmocone of a macroconch of H. crassus. We concur and, as first revising authors, select crassus as the name bearer of this species. Whiteaves (1885) described two specimens, both of which are phragmocones, from the Bearpaw Shale of Saskatchewan, as Scaphites subglobosus. As discussed by Cobban (1987), the larger one (Whiteaves, 1885: 52, pl. 7, fig. 3; pl. 8, fig. 1) is the lectotype of Rhaeboceras subglobosum. The smaller one (Whiteaves, 1885: 52, pl. 8, fig. 2) was assigned by Elias (1933) to H. plenus. It is characterized by numerous ventrolateral tubercles, a globose shell shape, and a depressed reniform whorl section. Because it is only part of a phragmocone, it is impossible to identify it to the species level with complete confidence, but we tentatively assign it to H. crassus, in agreement with Riccardi (1983: 20).
Meek (1876: 428) illustrated three specimens of Scaphites nodosus var. quadrangularis. These specimens represent microconchs of three species. One of the paratypes (USNM 365) illustrated by Meek (1876: pl. 25, fig. 4) is a robust specimen with coarse, widely spaced ribs. We interpret it as a microconch of Hoploscaphites crassus (fig. 33). It is probably from the Pierre Shale on the Cedar Creek Anticline, east-central Montana. The holotype of S. nodosus var. quadrangularis (USNM 366) illustrated by Meek (1876: pl. 25, fig. 3a-c) is a microconch of H. plenus (fig. 56H–K), from the same site, and is treated later in the text. The other paratype of S. nodosus var. quadrangularis (USNM 386690), illustrated by Meek (1876: pl. 25, fig. 2a-c), is a microconch of H. brevis (Meek, 1876), as discussed by Landman et al. (2010: 15–17, 160, 161, fig. 6D–G). It is probably from the Pierre Shale on the south fork of the Cheyenne River, South Dakota.
Material: The collection consists of 85 complete or nearly complete macroconchs and microconchs of which 32 macroconchs and 17 microconchs comprise the measured set. Those for which we have detailed information are from the upper part of the Baculites eliasi Zone and lower part of the B. baculus Zone. They are especially abundant in the scaphite concretionary layer in the lower part of the B. baculus Zone of the Pierre Shale on the Cedar Creek Anticline, Montana (Bishop, 1967, 1973).
Macroconch Description: Macroconchs are robust and medium to large in size. LMAX averages 102.5 mm and ranges from 67.7 to 131.0 mm (table 1). The ratio of the size of the largest specimen to that of the smallest is 1.86. The holotype is on the larger end of the spectrum (LMAX = 114.2 mm). The size distribution is broad with two notable gaps at 70–80 mm and 95–100 mm (fig. 12).
All specimens share in common a globose shape with a circular to oval outline in side view. In smaller specimens like AMNH 76341 (fig. 16), the shell is rounded in outline (LMAX/HS = 1.95), whereas in larger specimens, like the holotype (fig. 13), the shell is more oval in outline (LMAX/HS = 2.27). All specimens are tightly coiled. In smaller specimens like BHI 4291 (fig. 22), the hook is closely pressed against the phragmocone (LMAX/HP2 = 2.62), whereas in larger specimens, like the holotype (fig. 13), a small gap appears at this point (LMAX/HP2 = 2.80).
The phragmocone occupies approximately ½ whorl and usually terminates just below the line of maximum length. The apertural angle averages 58.1° and ranges from 40 to 71°. The apertural lip is flexuous with a deep constriction and accompanying varix. The dorsal margin of the aperture is bordered by an elongate, broadly rounded projection, as shown in AMNH 77604 (fig. 24).
The umbilicus is small and deep. The umbilical diameter averages 6.0 mm and ranges from 3.8 to 8.6 mm (table 1). UD/LMAX averages 0.06 and ranges from 0.04 to 0.07. The umbilicus is partially occluded by an umbilical bulge on the umbilical shoulder of the shaft. Due to the presence of the umbilical bulge, the outline of the umbilical shoulder is convex in lateral view. The umbilical bulge is prominent in BHI 4291 (fig. 22) but not as well developed in USNM 723203 (fig. 23).
The whorl section of the phragmocone near the point of exposure is depressed reniform with maximum whorl width at ⅓ whorl height. WP1/HP1 averages 1.22 and ranges from 1.06 to 1.43 (1.33 in the holotype). The umbilical wall is steep and subvertical and the umbilical shoulder is sharply rounded. The flanks of the phragmocone are well rounded, as in BHI 4291 (fig. 22), to broadly rounded, as in BHI 4301 (fig. 28), with maximum whorl width at ⅓ whorl height. The ventrolateral shoulder is sharply to well rounded and the venter is broadly rounded.
In passing from the adapical to the adoral part of the phragmocone, the whorl width and height increase, so that the cross section of the shell, as viewed from the ventral side, develops a V-shape, as shown in AMNH 77604 (fig. 24). The whorl section of the phragmocone along the line of maximum length is slightly more depressed than that at the point of exposure. WP2/HP2 averages 1.28 and ranges from 1.05 to 1.46 (1.45 in the holotype). The whorl section varies from depressed ovoid, as in BHI 4291 (fig. 22), to depressed reniform, as in the holotype (fig. 13). The umbilical wall is steep and subvertical and the umbilical shoulder is sharply rounded. The inner flanks are well rounded and the outer flanks are broadly rounded and converge toward the venter. The ventrolateral shoulder is sharply rounded and the venter is broadly to well rounded.
In passing from the phragmocone to the shaft, whorl width increases markedly and reaches its maximum value at midshaft forming a swelling at this point, coincident with the position of the umbilical bulge. WS/HS averages 1.31 and ranges from 1.03 to 1.52 (1.44 in the holotype). The whorl section is depressed reniform with maximum whorl width at ⅓ whorl height. The umbilical wall is steep and convex and the umbilical shoulder is sharply rounded. The inner flanks are well rounded and the outer flanks are broadly rounded and converge toward the venter. The ventrolateral shoulder is sharply rounded and the venter is broadly rounded. VS/HS averages 0.87 and ranges from 0.69 to 1.05 (0.90 in the holotype), indicating that the venter is, on average, nearly as wide as the whorl is high.
Both whorl width and whorl height decrease toward the point of recurvature. This decrease is accentuated in BHI 4301 (fig. 28) in which the shell pinches in approximately 1 cm adapical of the aperture. This is probably due to an injury or growth deformity. In general, the shape of the whorl section at the point of recurvature is nearly the same as that at midshaft. WH/HH averages 1.41 and ranges from 1.15 to 1.80 (1.53 in the holotype). The umbilical wall is broad and nearly flat and the umbilical shoulder is sharply rounded. The flanks are well rounded, the ventrolateral shoulder is sharply rounded, and the venter is broadly rounded.
Whorl width and whorl height continue to decrease toward the aperture and, as a result, the aperture is markedly reduced in size relative to the whorl section at midshaft. The aperture is ovoid and nearly equidimensional in AMNH 77604 (fig. 24), whereas it is ovoid and slightly depressed in YPM 35608 (fig. 18). The umbilical wall is broad and nearly flat and the umbilical shoulder is sharply rounded. The flanks are broadly rounded and converge to a narrow, broadly rounded venter.
At the adapical end of the exposed phragmocone, narrow ribs arise at the umbilical seam and cross the umbilical wall slightly rursiradiate. They strengthen across the umbilical shoulder and swing slightly backward and then forward on the inner flanks. If umbilicolateral tubercles are present on the specimen, one rib usually joins an umbilicolateral tubercle dorsally and two or three ribs branch from it ventrally, with one to three ribs intercalating between tubercles. Ribs are straight and rectiradiate on the outer flanks. In SDSM 149986 (fig. 19), the ribs on the right side of the phragmocone are more closely spaced than those on the left side due to an injury. Intercalation and branching occur at the ventrolateral tubercles or at their respective locations, and along the outer margins of the outer flanks. One rib usually joins a ventrolateral tubercle dorsally and two ribs branch from it ventrally, with two or three ribs intercalating between tubercles. Ribs are uniformly spaced on the venter, which they cross with a moderately strong adoral projection. The rib density on the venter on the adapical part of the phragmocone ranges from 5 to 7 ribs/cm (6 ribs/cm in the holotype).
The same pattern of ribbing continues onto the adoral part of the phragmocone. Ribs are narrow and slightly rursiradiate on the broad umbilical wall. They strengthen on the umbilical shoulder and are slightly concave on the inner flanks. If umbilicolateral tubercles are present on the specimen, one or two ribs usually join a tubercle dorsally and two or three ribs branch from it ventrally, with one or two ribs intercalating between tubercles. Ribs are straight and rectiradiate on the midflanks, forming a broad area of evenly spaced, nonbifurcating ribs. Branching and intercalation occur at the ventrolateral tubercles and on the outer margins of the outer flanks. One or two ribs usually join a ventrolateral tubercle dorsally and two to four ribs branch from it ventrally. If tubercles are paired on opposite sides of the venter, ribs loop between tubercles, with as many as five nontuberculate ribs intercalating between them. If tubercles are not paired on opposite sides of the venter, ribs that branch from a tubercle on one side of the venter intercalate between pairs of tubercles on the opposite side of the venter. Ribs cross the venter with a moderately strong adoral projection. They are slightly more closely spaced on the adoral than on the adapical part of the phragmocone. The rib density on the venter on the adoral part of the phragmocone ranges from 6 to 8 ribs/cm (8 ribs/cm in the holotype).
Ribs are not preserved on the shaft of the holotype but are preserved in many other specimens such as BHI 4291 (fig. 22) and AMNH 134699 (fig. 15). In BHI 4291 (fig. 22), 9 ribs/cm are present on the umbilical wall at midshaft. On the adapical one-third of the shaft, ribs are slightly concave on the inner flanks but straighten out on the outer flanks. Starting at midshaft, ribs are broadly concave on both the inner and outer flanks; they become progressively more prorsiradiate and widely spaced toward the aperture. One or two ribs usually join an umbilicolateral tubercle dorsally and three or four ribs branch from it ventrally, with four or five ribs intercalating between tubercles. Intercalation and branching also occur at the ventrolateral tubercles. Two or three ribs usually join a ventrolateral tubercle dorsally and four or five ribs branch from it ventrally. As on the phragmocone, if tubercles are paired on opposite sides of the venter, ribs loop between tubercles, with three to five nontuberculate ribs intercalating between them. If tubercles are not paired on opposite sides of the venter, ribs that branch from a tubercle on one side of the venter intercalate between pairs of tubercles on the opposite side of the venter. Ribs are evenly and closely spaced on the venter, which they cross with a moderately strong adoral projection. The rib density on the venter at midshaft ranges from 4 to 9 ribs/cm (7 ribs/cm in the holotype).
The same pattern of ribbing persists onto the hook. Ribs swing forward at the umbilical shoulder and are broadly concave on the flanks. Intercalation and branching occur at the umbilicolateral and ventrolateral tubercles. Ribs cross the venter with a slight adoral projection. The rib density on the venter of the hook is similar to that at midshaft and ranges from 6 to 9 ribs/cm (7 in the holotype).
Umbilicolateral tubercles are usually present at the point of exposure, having migrated out from a more dorsal position in earlier whorls. They occur at ⅓ whorl height. They are closely spaced, gradually becoming more widely spaced toward the adoral end of the phragmocone. The maximum distance between consecutive tubercles on the phragmocone ranges from 4 to 7.5 mm. The total number of umbilicolateral tubercles on the exposed phragmocone ranges from 5 to 13 (13 in the holotype); BHI 4291 (fig. 22) bears 9 umbilicolateral tubercles on the phragmocone. In contrast, umbilicolateral tubercles are absent altogether in AMNH 135326 (fig. 26).
The umbilicolateral tubercles on the phragmocone range in height from 0.25 to 1.0 mm. They are bullate and elongated radially. As mentioned previously, one or two ribs usually join an umbilicolateral tubercle dorsally and two or three ribs branch from it ventrally. However, in USNM 723203 (fig. 23), the ribs that join an umbilicolateral tubercle dorsally are very broad and, in some instances, even comprise two ribs fused together. Moreover, in the holotype (fig. 13), some of the umbilicolateral tubercles do not occur on ribs at all, but rather in the interspaces between them.
Umbilicolateral tubercles occur at ⅓ to nearly ½ whorl height on the body chamber. The number of umbilicolateral tubercles on the body chamber ranges from 3 to 8 (5 in the holotype), with the exception of AMNH 135326 (fig. 26), in which they are absent altogether. Excluding this specimen, the total number of umbilicolateral tubercles on the exposed shell ranges from 9 to 20 (20 in the holotype). The umbilicolateral tubercles attain their maximum spacing at midshaft and usually become more closely spaced thereafter. They usually persist to the aperture, as in the holotype (fig. 13) and BHI 4291 (fig. 22). The tubercles are bullate but terminate in sharp points. They are relatively more prominent in smaller specimens, such as BHI 4891 (fig. 22), than in larger specimens, such as SDSM 149986 (fig. 19). The maximum height of tubercles ranges from 1.5–2 mm.
Even in specimens in which umbilicolateral tubercles are absent or reduced in size such as AMNH 135326 (fig. 26) and SDSM 149987 (fig. 27), ventrolateral tubercles are present starting at the point of exposure. They occur at ¾ to ⅞ whorl height and may be paired or offset on opposite sides of the venter. The total number of ventrolateral tubercles on the exposed phragmocone ranges from 7 to17, depending on the size of the shell (17 in the holotype). They are more or less evenly spaced, becoming progressively more widely spaced toward the base of the body chamber, with the maximum distance between tubercles ranging from 6 to 15 mm (12 mm in the holotype). We note, however, many exceptions to this pattern. In YPM 35608 (fig. 18), the tubercles are grouped in pairs, and in BHI 4291 (fig. 22), three of the most closely spaced tubercles occur near the adoral end of the phragmocone.
As mentioned in describing the phragmocone, one or two ribs usually join a ventrolateral tubercle dorsally and two to four ribs branch from it ventrally. However, in many specimens such as BHI 4291 (fig. 22) and SDSM 149987 (fig. 27), some of the ventrolateral tubercles occur in the interspaces between ribs. The tubercles on the phragmocone are radially elongated but terminate in sharp points. As shown in USNM 723203 (fig. 23), tubercles usually exhibit steeply sloping adapical faces and more gently sloping adoral faces. They range in height from 1.0–2.5 mm.
Ventrolateral tubercles continue onto the body chamber, usually persisting right to the aperture. They occur at ⅞ whorl height and are paired or slightly offset on opposite sides of the venter. The total number of ventrolateral tubercles on the body chamber ranges from 8 to 15 (13 in the holotype), so that the total number of ventrolateral tubercles on the exposed shell ranges from 21 to 36 (30 in the holotype). Tubercles gradually become more widely spaced adorally, and attain their maximum spacing at midshaft or on the adoral one-third of the shaft. The maximum distance between consecutive tubercles ranges from 7 to 18 mm (12 mm in the holotype). Thereafter, the spacing between tubercles decreases toward the aperture, as shown in the holotype (fig. 13). Exceptions to this rule are BHI 4292 (fig. 25), AMNH 135326 (fig. 26), and ANSP IP 81678 (fig. 30), in which the distance between tubercles remains nearly the same on the entire body chamber, a pattern that is similar to that in Hoploscaphites plenus.
Ventrolateral tubercles usually attain their maximum height on the adoral one-third of the shaft. They range in height from 2 mm, as in the holotype (fig. 13), to 5 mm, as in AMNH 135326 (fig. 26). However, in general, tubercles do not attain the size of those in Hoploscaphites plenus. Smaller tubercles (2 mm high) are conical in shape whereas larger tubercles (5 mm high) are clavate in shape, with steep adapical and gently sloping adoral faces.
Lateral tubercles are absent in all the specimens we examined. The only possible exception is SDSM 149983 (fig. 21), in which two ribs become slightly bullate just dorsal of the ventrolateral tubercles on the adapical end of the phragmocone.
The suture is deeply incised. The first lateral saddle (E/L) is broad stemmed and asymmetrically bifid, with the ventral branch larger than the dorsal branch. The first lateral lobe (L) is narrow, symmetrically bifid, and nearly as deep as the ventral lobe (fig. 31).
Microconch Description: What we take to be microconchs of this species are robust, loosely uncoiled forms, with the same pattern of ornamentation as on the macroconchs. LMAX averages 67.4 mm and ranges from 57.7 to 78.3 mm (table 2). The size distribution is unimodal and asymmetric with a peak at 70–75 mm (fig. 12). The ratio of the average size of microconchs to that of macroconchs is 0.66.
UD averages 4.2 mm and ranges from 3.4 to 5.1 mm. UD/LMAX averages 0.06 and ranges from 0.04 to 0.08. The umbilical seam of the shaft is concave in lateral view, as in other microconchs of Hoploscaphites. All specimens are robust with an oval outline in lateral view. In addition, microconchs are more loosely uncoiled than macroconchs. LMAX/HP2 averages 2.96, which is significantly higher than that in macroconchs (2.78).
The whorl section of the exposed phragmocone is depressed subquadrate. WP1/HP1 averages 1.08 and ranges from 0.90 to 1.24 (table 2). WP2/HP2 averages 1.16 and ranges from 1.05 to 1.28. The umbilical wall is steep and subvertical and the umbilical shoulder is sharply rounded. The inner flanks are sharply rounded and the outer flanks are broadly rounded, with maximum whorl width at ⅓ whorl height. The ventrolateral shoulder is sharply rounded and the venter is well rounded.
Whorl width increases gradually from the phragmocone into the body chamber and attains its maximum value at the point of recurvature. Whorl height also increases gradually and attains its maximum value at midshaft, and remains nearly the same thereafter. The whorl section at midshaft is depressed reniform with maximum whorl width at ⅓ whorl height. Ws/Hs averages 1.22 and ranges from 1.09 to 1.38 (table 2). The umbilical wall is steep and slopes outward, and the umbilical shoulder is sharply rounded. The flanks are broadly rounded, the ventrolateral shoulder is sharply rounded, and the venter is broadly rounded. VS/HS averages 0.87 and ranges from 0.72 to 1.05, indicating that, on average, the venter is nearly as wide as the whorl is high. The whorl section at the point of recurvature is more ovate than that at midshaft. WH/HH averages 1.29 and ranges from 1.19 to 1.42.
TABLE 1
Measurements of Hoploscaphites crassus (Coryell and Salmon, 1934), macroconchs
See Figure 7 for description of measurements. All measurements are in mm except for apertural angle. 1 = intermediate to H. peterseni, n. sp.; 2 = non-lethal injury; 3 = suture. Abbreviations: uBe= upper Baculites eliasi Zone; Bb = Baculites baculus Zone; lBb = lower Baculites baculus Zone; lBg = lower Baculites grandis Zone; CCA= Cedar Creek Anticline, Montana.
continued
TABLE 2
Measurements of Hoploscaphites crassus (Coryell and Salmon, 1934), microconchs
See Figure 7 for description of measurements. All measurements are in mm. 1 = suture. Abbreviations: Bb= B. baculus Zone; lBb= lower B. baculus Zone; lBg= lower B. grandis Zone; CCA=Cedar Creek Anticine, Montana.
Ornament in microconchs is similar to that in macroconchs. On the exposed phragmocone, narrow ribs arise at the umbilical seam and strengthen across the umbilical shoulder. They bend slightly backward on the inner flanks and slightly forward on the outer flanks, forming a broad convexity. On the adoral end of the phragmocone, one rib usually joins an umbilicolateral tubercle dorsally and two ribs branch from it ventrally, with one rib intercalating between tubercles. As on macroconchs, intercalation and branching also occur at the ventrolateral tubercles and along the outer margins of the outer flanks. One or two ribs usually join a ventrolateral tubercle dorsally and two or three ribs branch from it ventrally, with one or two ribs intercalating between tubercles. Ribs are uniformly spaced on the venter, which they cross with a moderately strong adoral projection. The rib density on the venter on the adoral part of the phragmocone ranges from 6 to 8 ribs/cm.
Ribs are strong and moderately widely spaced on the shaft. They swing slightly backward on the umbilical wall and inner flanks, slightly forward on the midflanks, and slightly backward again on the outer flanks. They become progressively more prorsiradiate toward the adoral end of the shaft. Intercalation and branching occur at the umbilicolateral and ventrolateral tubercles, as exemplified by USNM 365 (fig. 33). In this specimen, two ribs join an umbilicolateral tubercle dorsally, and three ribs branch from it ventrally, with two ribs intercalating between tubercles. Two or three ribs join a ventrolateral tubercle dorsally, and an equal number of ribs branch from it ventrally. In areas where tubercles are paired on opposite sides of the venter, ribs loop between tubercles, with two or three nontuberculate ribs intercalating between them. In areas where tubercles are not paired on opposite sides of the venter, ribs that branch from a tubercle on one side of the venter intercalate between pairs of tubercles on the opposite side of the venter. Ribs are evenly and closely spaced on the venter, which they cross with a moderately strong adoral projection. The rib density on the venter at midshaft in USNM 365 is 6 ribs/cm, which remains the same on the hook (fig. 33).
Umbilicolateral tubercles are present in all specimens and first appear on the adoral end of the phragmocone. They occur at ⅓ whorl height and are more prominent in microconchs than in macroconchs. They strengthen on the shaft and develop into bullae, with a maximum height of 3 mm. Many of the tubercles exhibit steep adapical faces and gently sloping adoral faces. The tubercles become progressively more widely spaced adorally, and attain their maximum spacing on the adoral one-third of the shaft, after which they become more closely spaced again toward the aperture. The maximum distance between consecutive tubercles on the adoral one-third of the shaft in USNM 365 is 7 mm (fig. 33).
Ventrolateral tubercles are present starting at the point of exposure. In SDSM 149989 (fig. 38), in which the ornamentation is very well preserved, a total of 17 ventrolateral tubercles appear on the phragmocone. They occur at ⅞ whorl height and are more or less evenly spaced, gradually becoming more widely spaced toward the adoral end of the phragmocone. The distance between consecutive tubercles in this specimen increases from 4 mm on the adapical end of the phragmocone to 8 mm on the adoral end of the phragmocone. Tubercles are usually paired on opposite sides of the venter but, occasionally, they are offset. They are conical in shape but elongated radially, with a maximum height of 3 mm.
Ventrolateral tubercles continue uninterruptedly to the aperture. In SDSM 149989 (fig. 38), nine ventrolateral tubercles appear on the body chamber, so that the total number of tubercles on the exposed shell of this specimen is 26. Tubercles become increasingly larger and more clavate on the shaft, reaching a maximum height of 4 mm. They exhibit steep adapical faces and gently sloping adoral faces. Tubercles gradually become more widely spaced toward the adoral one-third of the shaft. In our sample of specimens, the maximum distance between consecutive tubercles in this area ranges from 10 to 16 mm. Tubercles become more closely spaced toward the aperture and, in some instances, disappear altogether, as shown in USNM 723215 (fig. 36).
The suture of microconchs is similar to that of macroconchs (fig. 32A, B).
Discussion: Hoploscaphites crassus is characterized by a globose shell with strongly inflated flanks and small, evenly spaced ventrolateral tubercles. It most closely resembles H. plenus, from which it differs in having more numerous, smaller, and more closely spaced ventrolateral tubercles, and a more robust whorl section. For example, the average value of VS/HS in macroconchs of H. crassus is significantly higher than that in macroconchs of H. plenus (0.87 vs 0.68). However, H. crassus clearly shows much morphology in common with H. plenus. Riccardi (1983: 21) also recognized this fact and cautioned that “more material is necessary to establish the ranges of their morpholgical variability and hence definite validity.” We retain the two as separate species because of discernable differences but acknowledge the existence of intermediate specimens that share features of both species. Hoploscaphites crassus is easily distinguished from the slightly younger H. criptonodosus (Riccardi, 1983) by its more inflated whorl section and lack of lateral tubercles.
Occurrence: Hoploscaphites crassus is restricted to the upper part of the Baculites eliasi and the lower part of the B. baculus zones. It occurs in the Pierre Shale on the Cedar Creek Anticline, east-central Montana, the Pierre Shale on the Old Woman Anticline in Niobrara County, Wyoming, the Lewis Shale in Carbon County, Wyoming, and the Bearpaw Shale in Valley and Stillwater counties, Montana. On the Cedar Creek Anticline, it is most abundant in the scaphite and septarian concretionary layers in the lower part of the B. baculus Zone. Hoploscaphites crassus is also reported from the B. eliasi and B. baculus zones in Saskatchewan and Alberta (Riccardi, 1983).
Hoploscaphites plenus (Meek and Hayden, 1860)
Figures 10C, D, 32C, D, 41–58
Macroconch Synonymy
1860a. Scaphites nodosus var. plenus. Meek and Hayden, p. 177.
1860b. Scaphites nodosus var. plenus. Meek and Hayden, p. 420.
1861. Scaphites nodosus var. plenus. Gabb, p. 33.
1864. Scaphites nodosus var. plenus Meek and Hayden. Meek, p. 24.
1876. Scaphites nodosus Owen var. plenus Meek and Hayden. Meek, p. 429, pl. 26, fig. 1a-c.
?1899. Scaphites nodosus Meek. Logan, p. 209, pl. 22, fig. 2; pl. 23, figs. 1–4, 6–12 (unidentifiable because only sutures and drawings of early ontogenetic stages).
1905. Scaphites nodosus plenus Meek and Hayden. Schuchert, p. 588.
?1905. Scaphites nodosus var. plenus Meek and Hayden. Smith, p. 638, figs. 1.1; 3.4, 7, 8, 10 (unidentifiable because only sutures and early ontogenetic stages).
1916. Scaphites nodosus plenus. Nowak, p. 59.
1927. Acanthoscaphites nodusus var. plenus. Reeside, p. 32.
1933. Scaphites plenus Meek. Elias, p. 314 (pars), pl. 36, fig. 1a-c, 2a-c (unidentifiable because only early ontogenetic stages); pl. 37, fig. 1a-c (unidentifiable because only early ontogenetic stage); pl. 39, fig. 1a-c (unidentifiable because only early ontogenetic stage); pl. 40, figs. 3–5 (unidentifiable because sutures of only early ontogenetic stages), fig. 6 (= Meek, 1876, pl. 26, fig. 1c).
1934. Acanthoscaphites nodosus plenus. Coryell and Salmon, p. 11.
1940. Acanthoscaphites plenus. Landes, p. 178.
1977. Hoploscaphites nodosus plenus (Meek and Hayden). Kauffman, p. 274, pl. 32, fig. 1 (= Meek, 1876, pl. 26, fig. 1a).
1980. Hoploscaphites nodosus plenus. Thomel, fig. 111.
1983. Jeletzkytes plenus (Meek). Riccardi, p. 21, pl. 9, figs. 1, 2; text-fig. 13a (= cross section of Meek, 1876, pl. 26, fig. 1a).
?1983. Jeletzkytes aff. brevis (Meek) ♀. Riccardi, p. 27, pl. 6, figs. 1–4; text fig. 23 (suture); text fig. 24 (cross section).
1997. Jeletzkytes plenus (Meek and Hayden, 1860). Larson et al., p. 80, unnumbered figs.
non 2010. Hoploscaphites plenus (Meek, 1876). Landman, p. 50, fig 2A, B; p. 198, fig. 86E-G.
2016. Jeletzkytes plenus (Meek and Hayden, 1861). Klein, p. 143.
Microconch Synonomy
1876. Scaphites nodosus var. quadrangularis Meek, p. 248 (pars), pl. 25, fig. 3a-c only; non fig. 2a-c (= Hoploscaphites brevis microconch); non fig. 4 (= Hoploscaphites crassus microconch).
1910. Scaphites nodosus quadrangularis (Meek). Grabau and Shimer, p. 177, figs. 1429, 1430 (= Meek, 1876, pl. 25, figs. 3a-c).
1915. Scaphites binodosus F.A. Roemer var. quadrangularis Meek. Frech, p. 559, text-fig. 5.
1921. Scaphites nodosus var. quadrangularis. Grabau, p. 701, fig. 1698h (= Meek, 1876, pl. 25, fig. 3c).
?1931. Acanthoscaphites nodosus var. quadrangularis (Meek and Hayden). Warren, pl. 1, fig. 2.
1934. Acanthoscaphites nodosus quadrangularis. Coryell and Salmon, fig. 9a, b (= Meek, 1876, pl. 25, fig. 3a, b).
1944. Acanthoscaphites nodosus quadrangularis. Shimer and Shrock, p. 591, pl. 246, figs. 4–6 (= Meek, 1876, pl. 25, fig. 3a-c).
?1968. Scaphites elegans Tate. Jeletzky, p. 49.
1983. Jeletzkytes cf. brevis (Meek, 1876) ♂. Riccardi, p. 25 (pars), pl. 10, figs. 5, 6 only (= Meek, 1876: pl. 25, fig. 3a, b), ? figs. 10–18; ? text-fig. 22b (suture).
1997. Jeletzkytes “quadrangularis” (Meek and Hayden, 1860). Larson et al., p. 78, unnumbered fig., lower right (= Meek, 1876, pl. 25, fig. 3a + ventral view).
non 2010. Hoploscaphites plenus (Meek, 1876). Landman et al., p. 14, fig. 6A–C (= Hoploscaphites crassus microconch).
2010. Hoploscaphites plenus (Meek, 1876), microconch. Landman et al., p. 14, fig. 6H-K (= Meek, 1876, pl. 25, figs. 3a, b + right lateral + ventral).
Emended Diagnosis: Macroconchs medium to large in size, robust; whorl cross section of shaft depressed subquadrate with broadly rounded flanks and venter; width of venter approximately 70% whorl height; small umbilicus; apertural angle averaging 60°; long, fine, straight, closely spaced ribs on adoral part of phragmocone, with little branching or intercalation, and moderately strong adoral projection on venter; long, fine, straight, more widely spaced ribs on shaft, with moderately strong adoral projection on venter; small, closely spaced umbilicolateral tubercles on phragmocone, becoming slightly larger and more widely spaced on body chamber; small, moderately widely spaced ventrolateral tubercles on phragmocone at ⅞ whorl height, becoming much larger and more widely spaced on body chamber, usually persisting to aperture. Microconchs medium to large in size, robust, and more loosely uncoiled than macroconchs; umbilical wall of shaft broad and outwardly sloping; pattern of ornament similar to that of macroconchs, with relatively more prominent umbilicolateral tubercles. Suture deeply incised with broad-stemmed asymmetircally bifid first lateral saddle.
Types: Meek and Hayden (1860a: 177) described Scaphites nodosus var. plenus and noted that
it differs from Dr. Owen's [1852] figure of S. nodosus in being greatly more ventricose, and shorter in proportion to its height, whilst the inner row of nodes are much smaller and near the umbilicus. There are some differences in the details of the septa which cannot, however, be readily explained without figures. It is likewise much larger than the specimens represented by Professor Owen, or any individual of that form that we have seen, its length being 4.57 inches, height 3.87 inches, and its breadth 2.52 inches.
The detailed dimensions given by the authors indicate that they were referring to a single specimen, which is, thus, the type by monotypy (USNM 364). Meek (1876: pl. 26, fig. 1a-c) illustrated “the perfect large type-specimen of this variety,” which exactly matches the dimensions given by Meek and Hayden (1860a: 177). It is a steinkern of a macroconch but retains some shell on the adoral end of the phragmocone and body chamber. The right side of the hook exhibits a large reparied injury. It is from the Pierre Shale on the “Yellowstone River, Montana, 150 miles [248 km] above the mouth,” and was collected by Lieutenant G.K. Warren of the U.S. Topographical Engineers. It is probably from the layer of scaphite concretions in the lower Baculites baculus Zone of the Pierre Shale on the Cedar Creek Anticline, Montana (Bishop, 1967, 1973). Since its initial description, the variety plenus has been elevated to the species level by many authors (e.g., Riccardi, 1983).
The holotype (USNM 366) of Scaphites nodosus var. quadrangularis illustrated by Meek (1876: 428, pl. 25, figs. 3a-c) is a microconch of Hoploscaphites plenus (fig. 56H-K). Together, with the macroconch described above, they form a single dimorphic pair, here desginated as H. plenus.The microconch is from the same locality as the macroconch. It is relatively finely ribbed with widely spaced ventrolateral tubercles. It exhibits a repaired injury on the venter at the point of recurvature, which takes the form of a blister and, as a result, the ribs are more widely spaced in this region.
Material: The collection consists of 85 complete or nearly complete specimens of which 38 macroconchs and 30 microconchs comprise the measured set. They are most abundant in the Baculites baculus Zone but occasionally occur in the B. eliasi Zone and possibly in the lower part of the B. grandis Zone.
Macroconch Description: Adults are medium to large in size. LMAX averages 96.0 mm and ranges from 71.8 to 130.7 mm (table 3). The holotype is on the larger end of the spectrum (LMAX = 116.2 mm). As in Hoploscaphites crassus, the size distribution is broad with peaks at 85–90 mm and 95–100 mm. Many of the smaller specimens such as BHI 4303 (fig. 49) and BHI 4701 (fig. 50) appear to be from higher up in the stratigraphic section (upper part of the Baculites baculus Zone or possibly lower part of the B. grandis Zone), but the details needed to confirm this are lacking. The ratio of the size of the largest specimen to that of the smallest is 1.82. The outline of the shell in lateral view is oval. LMAX/HS averages 2.16 and ranges from 2.02 to 2.34 (2.23 in the holotype). YPM 35679 (fig. 53) is an example of a shell with a more rounded outline (LMAX/HS = 2.02) and AMNH 76294 (fig. 46) is an example of a shell with a more oval outline (LMAX/HS = 2.34). The shells are relatively tightly coiled with a short shaft and small gap, if any, between the phragmocone and hook. LMAX/HP2 averages 2.85 and ranges from 2.56 to 3.05 (2.95 in the holotype).
The phragmocone occupies approximately ½ whorl and usually terminates just below the line of maximum length. The apertural angle averages 60° and ranges from 44° to 73° (table 3). The apertural margin is flexuous with a prominent constriction and accompanying varix. The umbilicus is small and deep. The umbilical diameter averages 5.1 mm, and ranges from 3.7 to 6.9 mm. UD/LMAX averages 0.05 and ranges from 0.04 to 0.07 (table 3). The umbilical shoulder of the shaft is straight in side view with a weak umbilical bulge.
The whorl section of the phragmocone at the point of exposure is depressed subquadrate with maximum whorl width at ⅓ whorl height. WP1/HP1 averages 1.10 and ranges from 0.90 to 1.24 (1.23 in the holotype). The umbilical wall is steep and subvertical and the umbilical shoulder is sharply rounded. The flanks are broadly rounded and gently converge toward the venter. The ventrolateral shoulder is sharply rounded and the venter is broadly rounded. In passing from the adapical to the adoral end of the phragmocone, both the whorl width and whorl height increase equally, so that the cross section of the shell, as viewed from the ventral side, does not develop a V-shape, as in Hoploscaphites crassus. The whorl section of the phragmocone along the line of maximum length is only slightly more depressed than that at the point of exposure. WP2/HP2 averages 1.17 and ranges from 0.99 to 1.31 (1.22 in the holotype).
The shell attains its maximum whorl width on the adoral one-third of the shaft, after which the width decreases steadily to the aperture. The shell attains its maximum whorl height at midshaft, after which the height decreases to the point of recurvature and then remains nearly the same up to the aperture. The whorl section at midshaft is depressed subquadrate to reniform. For example, it is subquadrate in YPM 35679 (fig. 53) whereas it is more nearly reniform in the holotype (fig. 42). WS/HS averages 1.09 and ranges from 0.97 to 1.28 (1.20 in the holotype). The umbilical wall of the shaft is steep and subvertical and the umbilical shoulder is sharply rounded. The inner flanks are inflated and well rounded and the outer flanks are more broadly rounded and gently converge toward the venter. The ventrolateral shoulder is sharply rounded and the venter is broadly rounded. VS/HS averages 0.68 and ranges from 0.52 to 0.87 (0.83 in the holotype), indicating that, on average, the venter is not as wide as the whorl is high.
The whorl section becomes more depressed toward the point of recurvature due to a marked decrease in whorl height. WH/HH averages 1.24 and ranges from 1.05 to 1.43 (1.25 in the holotype). The umbilical shoulder is sharply rounded and the flanks are well rounded. The venter is much narrower and more sharply rounded than at midshaft. As in Hoploscaphites crassus, the apertural opening is reduced in size relative to the whorl section at midshaft. It is depressed trigonal in AMNH 76294 (fig. 46) and depressed subovoid in SDSM 149981 (fig. 43).
At the point of exposure, strong ribs arise at the umbilical seam and cross the umbilical wall slightly rursiradiate. They strengthen on the umbilical shoulder and bend slightly backward on the inner flanks and intersect the umbilicolateral tubercles. One rib usually joins an umbilicolateral tubercle dorsally and two or three ribs branch from it ventrally, with one rib intercalating between tubercles. The ribs are straight, moderately widely spaced, and prorsiradiate on the outer flanks with additional intercalation and branching at the ventrolateral tubercles and on the outer margins of the outer flanks. One rib usually joins a ventrolateral tubercle dorsally and two or three ribs branch from it ventrally, with two or three ribs intercalating between tubercles. If the ventrolateral tubercles are paired on opposite sides of the venter, ribs that branch from a tubercle on one side of the venter loop to a tubercle on the opposite side. Ribs are uniformly strong and evenly spaced on the venter, which they cross with a moderately strong adoral projection. In the holotype, the rib density on the venter is 6 ribs/cm on the adapical end of the phragmocone.
On the adoral end of the phragmocone, ribs are narrow and slightly rursiradiate on the umbilical wall. They strengthen on the inner flanks and pass between or merge with the umbilicolateral tubercles. In the holotype, one or two ribs join an umbilicolateral tubercle dorsally and two or three ribs branch from it ventrally, with one or two ribs intercalating between tubercles. The outer flanks are covered with long, narrow, closely spaced, rectiradiate ribs, a pattern that this species shares in common with Hoploscaphites crassus and H. peterseni. Intercalation and branching occur on the outer margins of the outer flanks and at the ventrolateral tubercles. In the holotype, groups of four or five ribs branch from each ventrolateral tubercle and link to tubercles on the opposite side of the venter, with as many as five nontuberculate ribs intercalating between tubercles. Ribs cross the venter with a moderately strong adoral projection. The rib density on the venter on the adoral part of the phragmocone ranges from 6 to 8 ribs/cm (6 ribs/cm in the holotype).
On the shaft, ribs cross the umbilical wall with a slight backward bend. In YPM 35679 (fig. 53), 9 ribs/cm are present on the umbilical wall. They strengthen on the umbilical shoulder and are concave on the inner flanks. Due to poor preservation of this specimen, it is difficult to determine the exact number of ribs that join and branch from each umbilicolateral tubercle. The best estimate is that one or two ribs join an umbilicolateral tubercle dorsally and two or three ribs branch from it ventrally. Ribs are straight and weakly prorsiradiate on the flanks, becoming more strongly prorsiradiate adorally. In the holotype, four or five ribs join a ventrolateral tubercle dorsally and six or seven ribs branch from it ventrally, with as many as eight ribs intercalating between tubercles. Because tubercles are offset on opposite sides of the venter in the holotype, the ribs that branch from a tubercle on one side of the venter intercalate between pairs of tubercles on the opposite side of the venter. Ribs cross the venter with a moderately strong adoral projection. The rib density on the venter ranges from 5 to 8 ribs/cm (6 ribs/cm in the holotype).
As on the shaft, the ribs on the flanks of the hook are straight and prorsiradiate. The ribbing on the holotype is interrupted by an injury on the right side (fig. 42). As a result, the ribs are strongly convex on the flanks and bend backward at the ventrolateral margin, which is devoid of ornament. In contrast, the ornament on the left side of the shell is undisturbed. In all specimens, ribs cross the venter with a moderately strong adoral projection. In general, the ribs on the hook are slightly more closely spaced than those on the shaft (6 ribs/cm on the venter of the shaft versus 7 ribs/cm on the venter of the hook in the holotype).
Small, closely spaced umbilicolateral tubercles are present on the phragmocone in most, but not all, specimens. They occur at ⅓ whorl height. The tubercles are more or less evenly spaced, becoming slightly more widely spaced toward the adoral end of the phragmocone. The maximum distance between consecutive tubercles ranges from 4 to 5.5 mm (4.5 mm in the holotype). A total of 11 umbilicolateral tubercles are present on the phragmocone of the holotype. The tubercles are bullate in shape and radially elongate, with a maximum height of 1 mm.
If umbilicolateral tubercles are present on the phragmocone, they usually extend onto the body chamber, but not necessarily to the aperture. They are surprisingly weak relative to the much stronger ventrolateral tubercles. They occur at ⅓ whorl height and become more widely spaced adorally, with the maximum distance between consecutive tubercles ranging from 10 to 17 mm (17 mm in the holotype). A total of 4 umbilicolateral tubercles are present on the body chamber of the holotype, so that the total number of umbilicolateral tubercles on the exposed shell of this specimen is 14. The tubercles are bullate in shape with a maximum height of 2 mm.
Ventrolateral tubercles are present at the point of exposure and continue onto the entire exposed phragmocone. They occur at ⅞ whorl height and are perched either on the ribs or in the interspaces between them. Tubercles may be paired or offset from one side of the venter to the other. A total of 11 ventrolateral tubercles are present on the phragmocone of the holotype. Tubercles are more or less evenly spaced, becoming more widely spaced toward the base of the body chamber. The distance between the two most adoral tubercles in the holotype is 13 mm. Tubercles are conical in shape and slightly elongated radially. They range in height from 1.25–2.25 mm.
The ventrolateral tubercles on the body chamber also occur at ⅞ whorl height and are paired or offset on opposite sides of the venter. They are widely spaced with the maximum distance between consecutive tubercles occuring on the adoral end of the shaft, after which they become slightly more closely spaced on the hook and usually, but not always, persist to the aperture. We describe the spacing of tubercles in three specimens to illustrate the range of variation. In the holotype (fig. 42), the distance between tubercles increases from 19 mm on the adapical end of the shaft to 30 mm on the adoral end of the shaft, and then decreases to 25 mm on the hook. In AMNH 76294 (fig. 46), which is a slightly smaller specimen, the distance between tubercles on the shaft remains nearly the same throughout (14–16 mm), and then gradually decreases to 8.5 mm near the aperture. In AMNH 135090 (fig. 47), which is nearly the same size as AMNH 76294, the distance between tubercles on the shaft also remains nearly the same throughout (17–20 mm), and then gradually decreases to 7 mm near the aperture.
In addition to their wide spacing, one of the characteristic features of the ventrolateral tubercles is their large size. They reach a maximum size on the adoral end of the shaft and beginning of the hook, after which they diminish in size or disappear. They are clavate in shape with steeply sloping adapical faces and gently sloping adoral faces. Where preserved in their entirety, or nearly so, tubercles range from 2 to 6 mm in height and up to 11 mm in length. Commonly, however, the tubercles are broken off and only their bases remain.
As a result of their large size and wide spacing, the number of ventrolateral tubercles on the shell is lower than that in the closely related species Hoploscaphites crassus. For example, the total number of ventrolateral tubercles on the exposed shell of the holotype of H. plenus is 19 (fig. 42). The total number of tubercles on the exposed shell of BHI 4701 is 18 (fig. 50) and the total number of tubercles on the exposed shell of AMNH 105910 is 23 (fig. 44). In contrast, the total number of ventrolateral tubercles on the exposed shell of the holotype of H. crassus is 30 (fig. 13).
Lateral tubercles are rare or absent in all of the specimens in our collection. The holotype bears slightly bullate swellings, three in number, starting at the point of exposure, on the left side of the shell. They occur near the ventrolateral tubercles on the outer one-third of the flanks. The maximum height of the swellings is 0.5 mm and the maximum distance between them is 6.5 mm. The swellings disappear toward the middle one-third of the exposed phragmocone.
The suture is deeply incised (fig. 32C; Meek, 1876: pl. 26, fig. 1c; Elias, 1933: pl. 40, fig. 6). The first lateral saddle is broad stemmed and asymmetrically bifid. The first lateral lobe (L) is narrow, symmetrically bifid, and not as deep as the ventral lobe.
Microconch Description: What we interpret as microconchs of this species are robust, loosely uncoiled forms, with relatively flat flanks and widely spaced ventrolateral tubercles on the body chamber. Adults are small to medium in size. LMAX averages 58.5 mm and ranges from 51.1 to 68.2 mm (table 4). The size distribution is unimodal with a peak at 60–65 mm (fig. 41). The ratio of the average size of microconchs to that of macroconchs is 0.61.
UD averages 3.8 mm and ranges from 3.0 to 4.7 mm (table 4). UD/LMAX averages 0.06 and ranges from 0.06 to 0.08. The average value in microconchs is higher than that in macroconchs (0.05). The umbilical shoulder is concave in lateral view in contrast to macroconchs in which it is straight or convex in lateral view. Microconchs are oval in side view and more loosely uncoiled than macroconchs. LMAX/HP2 averages 3.02, which is significantly higher than that in macroconchs (2.85). The phragmocone is relatively large and represents approximately 60% of the shell length and usually terminates below the line of maximum length.
The whorl section at the point of exposure is subovoid and nearly equidimensional, with maximum whorl width at ¼ whorl height. WP1/HP1 averages 1.02 and ranges from 0.74 to 1.30. The umbilical wall is steep and subvertical, and the umbilical shoulder is sharply rounded. The inner flanks are well rounded and the outer flanks are broadly rounded and gently converge toward the venter. The ventrolateral shoulder is sharply rounded and the venter is broadly rounded.
Whorl width expands into the body chamber and attains its maximum value at the point of recurvature. Whorl height also increases, and attains its maximum value at midshaft, after which it remains the same. The whorl section at midshaft is depressed reniform with maximum whorl width at ⅓ whorl height. WS/HS averages 1.11 and ranges from 0.88 to 1.30 (table 4). The umbilical wall is broad and slopes outward, and the umbilical shoulder is sharply rounded. The inner flanks are well rounded and the outer flanks are broadly rounded. The ventrolateral shoulder is sharply rounded and the venter is broadly rounded. VS/HS averages 0.74 and ranges from 0.59 to 0.90, indicating that, on average, the venter is approximately ¾ as wide as the whorl is high. The whorl section at the point of recurvature is more ovoid and depressed than that at midshaft. WH/HH averages 1.19 and ranges from 1.02 to 1.36. The apertural opening is approximately the same size as the whorl section at midshaft, unlike the situation in macroconchs in which the apertural opening is reduced relative to that at midshaft.
The ornament in microconchs is similar to that in macroconchs. On the exposed phragmocone, ribs arise at the umbilical seam and are strong and rectiradiate on the umbilical wall. They swing backward on the inner flanks, forward on the midflanks, and backward again on the outer flanks. Intercalation and branching occur almost exclusively at the umbilicolateral and ventrolateral tubercles. One rib usually joins an umbilicolateral tubercle dorsally and two ribs branch from it ventrally, with one rib intercalating between tubercles. One or two ribs join a ventrolateral tubercle dorsally and as many as four ribs branch from it ventrally, with one or two ribs intercalating between tubercles. Ribs are strong and uniformly spaced on the venter, which they cross with a moderately strong adoral projection. The rib density on the adoral part of the phragmocone is 8 or 9 ribs/cm.
TABLE 3
Meaurements of Hoploscaphites plenus (Meek and Hayden, 1860), macroconchs
See figure 7 for description of measurements. All measurements are in mm except for apertural angle.1 = donated by L. Eichhorn; 2 = intermediate to an older, unnamed species. 3 = suture. Abbreviations: lBe = lower B. eliasi Zone; uBe = upper B. eliasi Zone; Bb = B. baculus Zone; lBb = lower B. baculus Zone; uBb = upper B. baculus Zone; lBg = lower B. grandis Zone; CCA=Cedar Creek Anticline, Montana.
continued
TABLE 4
Meaurements of Hoploscaphites plenus (Meek and Hayden, 1860) microconchs
See Figure 7 for description of measurements. 1 = suture. Abbreviations: uBe = upper B. eliasi Zone; Bb = B. baculus Zone; lBb = lower B. baculus Zone; uBb = upper B. baculus Zone; lBg = lower B. grandis Zone; CCA = Cedar Creek Anticline, Montana.
continued
At midshaft, ribs are evenly and closely spaced on the umbilical wall, e.g., 12 ribs/cm on the umbilical wall in YPM 1971 (fig. 57A-C). They merge with or intercalate between umbilicolateral tubercles. Two ribs usually join an umbilicolateral tubercle dorsally and four ribs branch from it ventrally, with two ribs intercalating between tubercles. Ribs are prorsiradiate on the flanks, swinging slightly forward on the midflanks and slightly backward on the outer flanks, forming a broad convexity. In AMNH 76342 (fig. 54D-F) in which the ornamentation on the shaft is very well preserved, it appears that three ribs join a ventrolateral tubercle dorsally and four ribs branch from it ventrally, with as many as four ribs intercalating between tubercles. Ribs are closely and evenly spaced on the venter, which they cross with a strong adoral projection. The rib density on the venter at midshaft in AMNH 76342 is 8 ribs/cm (fig. 54D-F). Ribs become progressively more prorsiradiate and closely spaced toward the aperture. For example, the rib density on the venter of the hook in AMNH 76342 is 9 ribs/cm (fig. 54D-F).
Umbilicolateral tubercles are present starting at the adoral end of the phragmocone. They continue onto the body chamber and usually persist to the aperture. They are perched on the umbilical shoulder at ¼ whorl height. They are evenly and moderately widely spaced on the body chamber. The distance between consecutive tubercles at midshaft ranges from 7 to 8.5 mm. Although as noted above, two ribs usually join a tubercle dorsally, in many specimens such as AMNH 76342 (fig. 54D–F), tubercles also occur in the interspaces between ribs. A total of 9 or 10 umbilicolateral tubercles are present on the exposed shell.
Given the smaller size of microconchs compared to macroconchs, umbilicolateral tubercles are relatively more prominent on microconchs than they are on macroconchs. They are bullate and rectiradiate on the adapical end of the shaft, becoming progressively more prorsiradiate toward the aperture. In some specimens such as AMNH 76342 (fig. 54D–F), they develop into large clavi as much as 3 mm high, with steeply sloping adapical faces and gently sloping adoral faces.
Ventrolateral tubercles are present in all specimens starting at the adapical end of the exposed phragmocone. In YPM 1971(fig. 57A–C) in which the ornamentation is very well preserved, a total of 11 ventrolateral tubercles are present on the phragmocone. They occur at ⅞ whorl height and become more widely spaced adorally, although the distance between them does not increase uniformly. For example, the distance between consecutive tubercles in this specimen, starting at the point of exposure, is 4.5, 6, 6, 3.5, 4.5, 7, 3.5, 5, 6, and 6 mm. Most of the tubercles are paired on opposite sides of the venter, but some are offset. The tubercles become increasingly larger toward the adoral end of the phragmocone and develop into clavi.
Ventrolateral tubercles continue onto the shaft and usually, but not always, extend to the aperture. For example, tubercles extend to the aperture in AMNH 76342 (fig. 54D–F), whereas they terminate at the adoral end of the shaft in AMNH 135983 (fig. 58E–H). As a result, the number of tubercles on the body chamber is higher in AMNH 76342 than in AMNH 135983 (9 vs. 6). Tubercles are more or less evenly spaced on the body chamber at intervals of 10–12 mm. The maximum distance between tubercles occurs on the adoral end of the shaft, e.g., 14 mm in AMNH 76342 (fig. 54D–F). Tubercles also become larger and more clavate in this area and attain a height of as much as 5 mm. They exhibit steeply sloping adapical faces and gently sloping adoral faces, as shown in AMNH 76342 (fig. 54D–F). The top of each tubercle in this specimen forms a flat, inclined plane with a raised, horseshoe-shaped outer rim.
The suture of microconchs is similar to that of macroconchs (fig. 32D).
Discussion: What has traditionally been considered Hoploscaphites plenus is a large, fairly robust shell. However, our collection contains many smaller size specimens that we include in this species. The stratigraphic distribution of these smaller specimens is not well constrained (upper part of the Baculites baculus Zone–lower part of the B. grandis Zone) and requires further examination. Hoploscaphites plenus most closely resembles H. crassus from which it differs in having a more compressed whorl section with flatter flanks, and fewer, larger, and more widely spaced ventrolateral tubercles. However, as noted in the discussion about H. crassus, many specimens are intermediate between the two species.
Elias (1933, p. 314, pl. 36, fig. 2a-c; pl. 40, fig. 5) described and illustrated a small specimen as Scaphites plenus from the basal beds of the Salt Grass Member of the Pierre Shale in Wallace County, Kansas. It is a broken fragment 35 mm in diameter consisting mostly of phragmocone. The flanks are relatively flat and subparallel and the venter is broadly rounded; as a result, the whorl cross section is subquadrate. However, until the early ontogeny of Hoploscaphites plenus is more fully documented, we hesitate to attribute it to this species. In addition, the source of this specimen—the lower part of the Salt Grass Member—dates from the Baculites reesidei and B. jenseni zones (Gill et al., 1972: 10), and is older than any of our specimens of H. plenus.
In descriptions of Hoploscaphites plenus, much has been made about the presence of an incipient row of lateral tubercles on the adapical portion of the exposed phragmocone. Meek (1876: 429) described the holotype as showing “a slight tendency to develop a third intermediate series of very small lateral nodes about midway between the other rows, such as I have not seen in any of the other varieties. This tendency, however, is only marked by a scarcely perceptible swelling of the costae at this point.” Such a row of slightly bullate swellings is also present, but rare, in specimens of H. crassus and H. peterseni. In contrast, lateral tubercles are much more common in the closely related, geologically younger species H. macer, H. sargklofak, and H. criptonodosus.
Occurrence: Hoploscaphites plenus is abundant in the Baculites baculus Zone but also occurs in the B. eliasi and possibly the lower part of the B. grandis zones. It occurs in the Pierre Shale on the Cedar Creek Anticline, east-central Montana, and in Niobrara, Weston, and Crook counties, northeast Wyoming. It has also been reported en passant from the B. eliasi and B. baculus zones of the Bearpaw Shale of southern Saskatchewan and southern Alberta (Forester et al., 1977; Riccardi, 1983, and references therein).
Hoploscaphites peterseni, n. sp.
Figures 10A, 32E, 59–78
Macroconch Synonymy
1997. Jeletzkytes plenus. Larson et al., p. 81, unnumbered fig.
2019. Hoploscaphites sp. Landman et al., figs. 11E, F, 23F.
Diagnosis: Macroconchs medium to large in size, nearly circular in outline; whorl cross section of shaft compressed subovoid with broadly rounded flanks and venter; width of venter approximately 60% whorl height; small umbilicus with umbilical bulge; apertural angle averaging 56°; long, fine, straight, closely spaced ribs on adoral part of phragmocone, with little branching or intercalation, and weak adoral projection on venter; long, fine, weakly concave, slightly more widely spaced ribs on shaft, with moderately strong adoral projection on venter; umbilicolateral tubercles absent or small and closely spaced on body chamber, forming a semicircle; ventrolateral tubercles small and closely spaced at ⅞ whorl height, usually persisting to aperture. Microconchs medium to large in size, and more loosely uncoiled than macroconchs; umbilical wall of shaft broad and outwardly sloping; pattern of ornament similar to that on macroconchs, with relatively more prominent umbilicolateral tubercles. Suture deeply incised with broad-stemmed, asymmetrically bifid first lateral saddle.
Etymology: This species is named in honor of Jack G. Petersen (Waterloo, Iowa) who, for over 25 years, collected and skillfully prepared hundreds of specimens of Eutrephoceras and Hoploscaphites from the Cedar Creek Anticline in east-central Montana. He has also generously donated many of these specimens to the AMNH for scientific research and display. It is fair to say that without Jack's contributions to this study, we would never have succeeded in conveying the richness and variety of the ammonites from the Cedar Creek Anticline.
Types: Following the traditional practice in scaphite systematics (Landman and Waage, 1993), we designate a macroconch rather than a microconch, as the holotype of this species. It is AMNH 71848 (fig. 60) from the Baculites baculus Zone or lower part of the B. grandis Zone of the Pierre Shale on the Cedar Creek Anticline in east-central Montana. It is a steinkern that retains some of its shell and is 88.7 mm in diameter with a weak umbilical bulge. It exhibits a repaired injury on the right side of the phragmocone near the point of exposure, which is manifested by an interruption in the ribbing. The macroconch paratypes are AMNH 41294 (fig. 61) and 105906 (fig. 70) from the B. baculus Zone from the same general site and USNM 723217 (fig. 67) from the B. eliasi Zone of the Bearpaw Shale, Valley County, Montana. The microconch paratypes are AMNH 76400 (fig. 77G–I) and 105901 (fig. 75A–D) from the B. baculus Zone or lower part of the B. grandis Zone, and the upper part of the B. baculus Zone, respectively, from the Pierre Shale on the Cedar Creek Anticline in east-central Montana.
Material: The collection consists of approximately 70 complete or nearly complete specimens of which 36 macroconchs and 26 microconchs comprise the measured set. Those for which we have detailed stratigraphic information are mostly from the lower part of the B. baculus Zone of the Pierre Shale on the Cedar Creek Anticline, east-central Montana, and the B. eliasi Zone of the Bearpaw Shale, Valley County, Montana.
Macroconch Description: Macroconchs are medium to large in size and robust. LMAX averages 87.8 mm and ranges from 69.5 to 114.6 mm (table 5). The holotype is in the middle of the size range (LMAX = 88.7 mm). The ratio of the size of the largest specimen to that of the smallest is 1.65. The size distribution is bimodal with a primary peak at 75-80 mm and a secondary peak at 100–105 mm (fig. 59).
All specimens are circular in side view. LMAX/HS averages 2.04, indicating that LMAX is approximately 2× the whorl height at midshaft, conforming nearly perfectly to the proportions of a circle. In addition, all specimens are tightly coiled with hardly any gap between the phragmocone and hook. LMAX/HP2 averages 2.77 and ranges from 2.46 to 3.11 (3.11 in the holotype).
As in other species of Hoploscaphites, the phragmocone of the adult shell is relatively large and represents approximately 60% of the shell length. The phragmocone usually terminates adoral of the line of maximum length. The apertural angle is relatively high; it averages 56.3° and ranges from 45° to 67°. The apertural lip is flexuous with a deep constriction and accompanying varix. The dorsal margin of the aperture is bordered by an elongate, broadly rounded projection.
The umbilicus is small and deep. The umbilical diameter averages 4.2 mm and ranges from 2.6 to 5.6 mm (table 5). UD/LMAX averages 0.05 and ranges from 0.04 to 0.06. In many specimens, the umbilicus is partially occluded by an umbilical bulge on the umbilical shoulder of the shaft. Due to the presence of the bulge, the outline of the umbilical shoulder is convex in lateral view. The umbilical bulge is prominent in AMNH 41294 (fig. 61) but not as well developed in the holotype (fig. 60).
The whorl section at the point of exposure is subovoid and nearly equidimensional, with maximum whorl width at ¼ whorl height. WP1/HP1 averages 1.03 and ranges from 0.73 to 1.24 (1.12 in the holotype). The umbilical wall is steep and convex and the umbilical shoulder is sharply rounded. The flanks are well rounded and gently converge toward the venter. The ventrolateral shoulder is sharply rounded and the venter is broadly rounded.
In passing from the adapical to the adoral part of the phragmocone, both whorl width and whorl height increase, so that the shape of the whorl section of the phragmocone along the line of maximum length is approximately the same as that at the point of exposure. WP2/HP2 averages 1.04 and ranges from 0.78 to 1.24 (1.24 in the holotype). The cross section is subovoid with maximum whorl width at ⅓ whorl height. The umbilical wall is steep and subvertical and the umbilical shoulder is sharply rounded. The flanks are broadly rounded and gently converge toward the venter.
Whorl width increases markedly and reaches its maximum value on the adoral part of the shaft, whereas whorl height reaches its maximum value at midshaft. WS/HS averages 0.99 and ranges from 0.80 to 1.16 (1.08 in the holotype). The whorl section at midshaft is compressed subovoid, as in the holotype (fig. 60), or reniform, as in USNM 723217 (fig. 67), with maximum whorl width at ⅓ whorl height. The umbilical wall is steep and weakly convex and the umbilicolateral shoulder is sharply rounded. The inner flanks are well rounded and the outer flanks are broadly rounded and converge steeply toward the venter. The ventrolateral shoulder is sharply rounded and the venter is broadly rounded. VS/HS averages 0.58 and ranges from 0.46 to 0.73 (0.71 in the holotype), indicating that the width of the venter is, on average, slightly more than one-half the height of the whorl.
In passing from the shaft to the hook, the whorl width remains nearly the same. In contrast, the whorl height decreases markedly. As a result, the whorl section is more depressed at the point of recurvature than at midshaft. WH/HH averages 1.16 and ranges from 0.93 to 1.37 (1.19 in the holotype). The umbilical shoulder is sharply rounded and the flanks are broadly rounded. The opening at the aperture is reduced in size relative to the whorl section at midshaft. It is subovoid and slightly depressed in the holotype (fig. 60).
At the point of exposure, ribs are straight and rectiradiate on the umbilical wall. They bend slightly backward on the inner flanks and pass between or merge with the umbilicolateral tubercles. In the holotype (fig. 60), one rib joins an umbilicolateral tubercle dorsally and three ribs branch from it ventrally, with one or two ribs intercalating between tubercles. The ribs bend forward on the outer flanks and form a broad convexity. Intercalation and branching occur on the outer margins of the outer flanks and at the ventrolateral tubercles. In the holotype, one or two ribs join a ventrolateral tubercle dorsally and two or three ribs branch from it ventrally, with an equal number of ribs intercalating between tubercles. The ribs that branch from tubercles on one side of the venter loop to tubercles on the other side of the venter. Ribs are uniformly strong and evenly spaced on the venter, and show a slight adoral projection. The rib density on the venter of the adapical end of the phragmocone in the holotype is 6 ribs/cm.
On the adoral part of the phragmocone, ribs bend slightly backward on the umbilical wall. They are straight on the inner flanks, and bend forward on the midflanks and backward on the outer flanks, forming a broad convexity. Ribs are long, narrow, and closely spaced on the outer flanks, a pattern similar to that in Hoploscaphites crassus and H. plenus. Intercalation and branching occur on the outer flanks and at the umbilicolateral and ventrolateral tubercles. In the holotype, one rib joins an umbilicolateral tubercle dorsally and two ribs branch from it ventrally, with two ribs intercalating between tubercles. One or two ribs join a ventrolateral tubercle dorsally and groups of two or three ribs branch from it ventrally, which loop to paired tubercles on the opposite side of the venter, with one or two ribs intercalating between groups. Ribs are closely and evenly spaced on the venter, which they cross with a slight adoral projection. The rib density is higher on the adoral than on the adapical part of the phragmocone (7 vs. 6 ribs/cm in the holotype).
The shaft is covered with thin, closely spaced ribs. They bend slightly backward on the umbilical wall and shoulder. In the holotype, 10 ribs/cm are present on the umbilical wall. Ribs bend strongly forward on the inner flanks and strongly backward on the outer flanks, forming a broad convexity. They are rectiradiate on the adapical end of the shaft and become progressively more prorsiradiate toward the adoral end of the shaft. As on the phragmocone, intercalation and branching occur on the outer flanks and at the sites of the umbilicolateral and ventrolateral tubercles. As a result, the midflanks are covered with a broad area of nonbifurcating ribs. In the holotype, one or two ribs join an umbilicolateral tubercle dorsally and two or three ribs branch from it ventrally, with as many as five ribs intercalating between tubercles. Two or three ribs join a ventrolateral tubercle dorsally and three or four ribs branch from it ventrally, with up to five ribs intercalating between tubercles. Because the ventrolateral tubercles are paired on opposite sides of the venter in the holotype, ribs that branch from a tubercle on one side of the venter loop to the tubercle on the other side of the venter. Ribs cross the venter with a moderately strong adoral projection. The rib density on the shaft of the holotype is the same as that on the adoral part of the phragmocone (7 ribs/cm).
As on the shaft, ribs on the flanks of the hook are narrow, prorsiradiate, and nearly straight. Intercalation and branching occur on the outer margins of the outer flanks and at the umbilicolateral and ventrolateral tubercles. Ribs cross the venter with a moderately strong adoral projection and become progressively more closely spaced toward the aperture, culminating in a rib density of 10 ribs/cm on the venter of the holotype.
Umbilicolateral tubercles are present in only one-half of the specimens in our collection. For example, they are present in the holotype starting at the point of exposure (fig. 60), but are absent in AMNH 41294 (fig. 61). The tubercles occur at ⅓ whorl height and are evenly spaced, becoming slightly more widely spaced toward the adoral end of the phragmocone. In the holotype, the distance between the two most adoral tubercles on the phragmocone is 5 mm. The tubercles are small with a maximum height of 1 mm and are elongated radially. A total of seven tubercles are present on the phragmocone of the holotype. Some of these tubercles do not occur on the ribs themselves but rather in the interspaces between them.
In those specimens in which umbilicolateral tubercles are present on the phragmocone, the tubercles continue onto the body chamber, usually persisting to the aperture. They occur at ⅓ whorl height and are arranged in a semicircle paralleling the outline of the venter in side view. They gradually become more widely spaced and attain their maximum spacing at midshaft, after which they become more closely spaced. The maximum distance between tubercles in the holotype is 9 mm. As on the phragmocone, the umbilicolateral tubercles on the body chamber are small, with a maximum height of 1 mm. They are bullate and follow the curvature of the ribs, so that the tubercles on the midshaft and hook are elongated in a prorsiradiate direction. A total of 6 umbilicolateral tubercles are present on the body chamber of the holotype, so that the total number of tubercles on the exposed shell of this specimen is 11.
All specimens bear ventrolateral tubercles starting at the point of exposure. They occur at ⅞ whorl height and are more or less evenly spaced, with maximum spacing at the adoral end of the phragmocone. However, in many specimens, the tubercles are grouped in clusters. For example, in the holotype (fig. 60), the distance between consecutive tubercles on the exposed phragmocone on the left side, starting at the point of exposure, is 8, 4, 6.5, 11, 6.5, 7.5, 6, 7.5, 8.5, and 7.5 mm. A total of 11 ventrolateral tubercles are present on the phragmocone of the holotype and are paired on opposite sides of the venter. In contrast, in SDSM 149991 (fig. 64), the ventrolateral tubercles are offset from one side of the venter to the other. Tubercles are conical in shape and slightly elongated radially, with a maximum height of 3 mm.
Ventrolateral tubercles extend onto the body chamber and, almost always, persist to the aperture. They are moderately widely spaced and nearly evenly distributed, forming a pattern similar to that in Hoploscaphites crassus. The tubercles attain their maximum spacing on the adoral one-third of the shaft (11.5 mm in the holotype), after which they become more closely spaced. Similarly, the tubercles attain their maximum size on the adoral one-third of the shaft, after which they decrease in size. In many specimens, such as SDSM 149990 (fig. 71), the tubercles develop into clavi with a maximum height of 3 mm. A total of 14 ventrolateral tubercles occurs on the body chamber of the holotype, so that the total number of ventrolateral tubercles on the exposed shell of this specimen is 25.
Lateral tubercles are very rare. In the holotype (fig. 60), one bullate tubercle occurs on the adapical end of the phragmocone on the left side of the specimen just dorsal of the ventrolateral tubercle. Similarly, in SDSM 149991 (fig. 64), two bullate tubercles are present on the adapical end of the phragmocone on the right side of the specimen just dorsal of the ventrolateral tubercles.
The suture is deeply incised with a broad stemmed and asymmetrically bifid first lateral saddle (E/L) and a narrow, symmetrically bifid first lateral lobe (L) that is nearly as deep as the ventral lobe (fig. 32E).
Microconch Description: Microconchs are smaller and more loosely uncoiled than macroconchs, but exhibit a similar ornamentation and shape of the whorl section. LMAX averages 58.1 mm and ranges from 44.2 to 79.1 mm (table 6). The size distribution is unimodal with a peak at 50–55 mm (fig. 59). The ratio of the average size of microconchs to that of macroconchs is 0.66. The umbilical shoulder of the shaft in microconchs is concave in lateral view and parallels the curvature of the venter. UD averages 3.5 mm and ranges from 2.6 to 4.5 mm (table 6). UD/LMAX averages 0.06 and ranges from 0.05 to 0.07. In AMNH 76311 (fig. 78E-H), the umbilical diameter on the right side is much larger than that on the left side due to a pathology. As noted, microconchs are more loosely uncoiled than macroconchs. This difference is expressed by the ratio LMAX/HP2, which averages 2.98 in microconchs versus 2.77 in macroconchs.
The whorl section at the adapical end of the phragmocone is compressed subquadrate with maximum whorl width at ¼ whorl height. WP1/HP1 averages 0.94 and ranges from 0.74 to 1.09 (table 6). The umbilical wall is steep and subvertical and the umbilical shoulder is sharply rounded. The flanks are broadly rounded and the ventrolateral shoulder is sharply rounded. The whorl section at the adoral end of the phragmocone is more depressed than that at the adapical end because of a larger increase in whorl width than whorl height. WP2/HP2 averages 1.05 and ranges from 0.93 to 1.22. The whorl section is compressed subovoid with maximum whorl width at ⅓ whorl height. The inner flanks are well rounded, and the outer flanks are more broadly rounded and gently converge toward the venter.
Whorl width and height both increase in passing into the shaft. Whorl width attains its maximum value at the point of recurvature whereas whorl height attains its maximum value at midshaft. The whorl section at midshaft is subquadrate to reniform with maximum whorl width at ¼ whorl height, coincident with the position of the umbilicolateral tubercles. WS/HS averages 1.03 and ranges from 0.78 to 1.18. The umbilical wall is broad and slopes outward, and the umbilical shoulder is sharply rounded. The flanks are broadly rounded to nearly flat and gently converge toward the venter. The ventrolateral shoulder is sharply rounded and the venter is broadly rounded. VS/HS averages 0.67 and ranges from 0.55 to 0.80, indicating that, on average, the venter is slightly more than one-half as wide as the whorl is high. The whorl section at the point of recurvature is more depressed; WH/HH averages 1.14 and ranges from 0.82 to 1.32.
On the exposed phragmocone, ribs arise at the umbilical seam and are straight to slightly rursiradiate on the umbilical wall. They are weakly flexuous on the flanks, swinging slightly backward on the inner flanks, slightly forward on the midflanks, and slightly backward again on the outer flanks. On the adoral end of the phragmocone, where umbilicolateral tubercles appear, one rib usually joins an umbilicolateral tubercle dorsally and three ribs branch from it ventrally, with two ribs intercalating between tubercles. Additional branching and intercalation occur on the outer flanks and at the ventrolateral tubercles. One rib usually joins a ventrolateral tubercle dorsally and two ribs branch from it ventrally, with an equal number of ribs intercalating between tubercles. Ribs are uniformly and evenly spaced on the venter, which they cross with a slight adoral projection. The rib density on the venter on the adoral part of the phragmocone is 7 or 8 ribs/cm.
Ribs are closely spaced and slightly rursiradiate on the umbilical wall of the shaft. They are moderately widely spaced and prorsiradiate on the flanks. They swing forward on the inner flanks and backward on the outer flanks, forming a broad convexity. Intercalation and branching occur on the outer flanks and at the umbilicolateral and ventrolateral tubercles. One rib usually joins an umbilicolateral tubercle dorsally and three ribs branch from it ventrally, with up to three ribs intercalating between tubercles. In AMNH 105901 (fig. 75A-D), three or four ribs join a ventrolateral tubercle dorsally and five to seven ribs branch from it ventrally, with one to three ribs intercalating between tubercles. The result of so much branching at the ventrolateral tubercles is that the venter is covered with fine, closely spaced ribs. The rib density on the venter at midshaft in this specimen is 9 ribs/cm. Ribs become progressively more prorsiradiate and closely spaced toward the aperture.
Umbilicolateral tubercles appear on the adoral end of the exposed phragmocone. They strengthen on the shaft and usually persist to the aperture. They are perched on the umbilical shoulder at ⅓ whorl height. The umbilicolateral tubercles in microconchs are relatively stronger than they are in macroconchs. They are bullate and become progressively more prorsiradiate toward the aperture. In many specimens, they develop into clavi as much as 2 mm high, with steep adapical faces and gently sloping adoral faces. They are evenly and moderately widely spaced; the maximum distance between tubercles usually occurs at midshaft, e.g., 8.5 mm in AMNH 76400 (fig. 77G–I). The number of umbilicolateral tubercles on the exposed shell ranges from 4 to 6.
TABLE 5
Measurements of Hoploscaphites peterseni, n.sp., macroconchs
See Figure 7 for description of measurements. All measurements are in mm except for apertural angle. 1 = donated by T. Linn; 2 = muscle scar; 3 = intermediate to H. macer; 4 = intermediate to older, unnamed species; Be = B. eliasi Zone; lBe = lower B. eliasi Zone; Bb = B. baculus Zone; lBb = lower B. baculus Zone; mBb = middle B. baculus Zone; uBb = upper B. baculus Zone; lBg = lower B. grandis Zone. CCA= Cedar Creek Ancticline, Montana.
continued
TABLE 6
Measurements of Hoploscaphites peterseni, n. sp., microconchs
See Figure 7 for description of measurements. All measurements are in mm. Abbreviations: Bb = B.baculus Zone; lBb = lower B. baculus Zone; uBb= upper B. baculus one; lBg = lower B. grandis Zone; CCA = Cedar Creek Anticline, Montana.
continued
Ventrolateral tubercles are usually present starting at the point of exposure, as in BHI 4129 (fig. 75E-H). However, we have observed many exceptions to this rule, as in AMNH 76400 (fig. 77G–I), in which tubercles only first appear on the adoral end of the phragmocone. As a result, the number of tubercles on the phragmocone in the latter specimen is lower than that in the former specimen (5 vs. 18). Tubercles occur at ⅞ whorl height and are usually paired on opposite sides of the venter. Although as noted above, one rib usually joins a ventrolateral tubercle dorsally, tubercles sometimes occur in the interspaces between ribs. In many specimens, the tubercles are grouped in clusters. For example, in BHI 4129 (fig. 75E–H), clusters of closely spaced tubercles (2–3.5 mm between consecutive tubercles) alternate with clusters of more widely spaced tubercles (4–4.5 mm between consecutive tubercles).
Ventrolateral tubercles continue onto the body chamber and usually terminate at the point of recurvature. They are evenly and moderately widely spaced. The maximum distance between consecutive tubercles ranges from 10 to 12 mm. They develop into small clavi at midshaft with a maximum height of 2 mm. The number of tubercles on the body chamber in BHI 4129 (fig. 75E–H) and AMNH 76400 (fig. 77G–I) is 10 and 5, respectively, so that the total number of ventrolateral tubercles on the exposed shell of these specimens is 28 and 10, respectively. Tubercles are usually paired on opposite sides of the venter. In BHI 4893 (fig. 78I–L), the rows of ventrolateral tubercles on opposite sides of the venter are reduced to a single midventral row due to a non-lethal injury in early ontogeny. After reaching maturity, the specimen was attacked again, this time fatally, as indicated by a missing chunk of shell from the adapical part of the body chamber.
Discussion: Hoploscaphites peterseni, n. sp., most closely resembles H. crassus. Both species are characterized by numerous, closely spaced ventrolateral tubercles that usually extend to the aperture. In addition, both species exhibit long, narrow, and closely spaced ribs on the flanks of the adoral part of the phragmocone. The two species differ in the degree of whorl inflation. In H. peterseni, the whorl section of the shaft is compressed subovoid with broadly rounded flanks and venter whereas in H. crassus, the whorl section of the shaft is depressed reniform with well rounded flanks and broadly rounded venter. Hoploscaphites peterseni also closely resembles H. macer. The principal differences between these two species are that the ribs on the adoral part of the phragmocone are much finer and more closely spaced in H. perterseni than in H. macer. The two species also differ in the degree of whorl inflation, with H. peterseni more depressed than H. macer. Macroconchs of H. peterseni bear a vague resemblance to those of the geologically older species H. brevis (Meek, 1876) because the umbilicolateral tubercles on the shaft are arranged in a semicircle in both species. However, the whorl section is more inflated and the ribs on the adapical part of the phragmocone are coarser and more widely spaced in H. peterseni than in H. brevis.
Occurrence: Hoploscaphites peterseni ranges from the Baculites eliasi Zone to the lower part of the B. grandis Zone. It is especially abundant in the scaphite and septarian concretionary horizons in the lower part of the B. baculus Zone of the Pierre Shale on the Cedar Creek Anticline in east-central Montana. It occurs in the same zone in the Pierre Shale in Niobrara and Weston counties, Wyoming. It is also present in the B. eliasi Zone of the Bearpaw Shale in Valley, Garfield, and McCone counties, Montana.
ACKNOWLEDGMENTS
At the American Museum of Natural History, we thank Ana Rashkova, Bushra Hussaini, Mary Conway, Kathleen Sarg, and Marion Savas for accessioning material and assigning AMNH numbers, Mary Knight for editing the manuscript for publication, and Stephen Thurston for photographing specimens and preparing figures. We thank the landowners Donley and Nancy Darnell and Bobbie Blankenship for permission to collect on their property. Many students, colleagues, and family members have helped us collect in the field and interpret the results, and we wish to express our thanks to Jamie Brezina, J. Kirk Cochran, Matthew P. Garb, Kate F. Grier, Isabella Kruta, Ekaterina Larina, Luke Larson, Corinne Myers, Jack Petersen, Dean G. Grier, Kristin Polizzotto, Remy Rovelli, Al Rowe, Joshua Slattery, Kazushige Tanabe, James Witts, Lee Herman, and Benjamin Laabs. We thank many individuals, who at our request, tracked down locality information, assigned numbers, and facilitated loans of specimens in their collections: K.C. McKinney (USGS), Susan H. Butts and Jessica Utrup (YPM), Kathy Hollis (USNM), Jocelyn A. Sessa and Katy Estes-Smargiassi (ANSP), Lauren Neitzke Adamo and Julia Criscione (RUGM), Scott Lidgard and Paul Mayor (FMNH), and Laurie Anderson (SDSM). Many of the specimens of Hoploscaphites at SDSM were collected by Gale Bishop during the course of his M.S. thesis on the Cedar Creek Anticline. L.T. thanks Annaka Clement for help in making thin sections. J.C. and J.W. Grier thank Donald P. Schwert and Allan C. Ashwerth who introduced them to the Cedar Creek Anticline and the late William A. Cobban who was an active and frequent mentor, including in the field. This research was supported by the N.D. Newell Fund (AMNH), the René M. Vandervelde Research Grant to N.H.L. from the Association of Applied Paleontological Sciences, and personal funds of J.C. and J.W. Grier, T. Linn, and N.L. Larson. The authors are deeply indebted to Matthew P. Garb and Royal H. Mapes for their detailed review of this manuscript, covering stratigraphy and paleontology. Their comments substantially improved the manuscript. This manuscript is dedicated to Robert Parr Whitfield, first Curator of Invertebrate Paleontology at the AMNH and founder of the AMNH Bulletin series.
REFERENCES
APPENDIX
List of LocaLities
Localities are from the American Museum of Natural History (AMNH), the U.S. Geological Survey (USGS), and the Yale Peabody Museum (YPM). The names of collectors and dates of collection are indicated at the end of each entry, where known. In the USGS numbers, the prefix D refers to Denver locality numbers and the others refer to Washington, D.C., locality numbers.
AMNH LOCALITIES
3194. Kara Bentonitic Member and upper unnamed shale member, Pierre Shale, N¼ sec. 17, T. 46 N., R. 64 W., Osage Oilfield, near Osage, Weston County, Wyoming.
3244. Baculites eliasi–B. grandis zones, Pierre Shale, SE¼ sec. 35 + SW¼ sec. 36, T. 14 N., R. 55 E. + NE¼ sec. 2 + NW¼ sec. 1, T. 13 N., R. 55 E., south of Glendive, Dawson County, Montana. [Biostratigraphic information may be more precise for a particular specimen, as recorded in the field notes and on the label].
3245. Baculites eliasi–B. grandis zones, Pierre Shale, SW¼ sec. 35, T. 14 N., R. 55 E., south of Glendive, Dawson County, Montana. [Biostratigraphic information may be more precise for a particular specimen, as recorded in the field notes and on the label].
3246. Baculites baculus–B. grandis zones, Pierre Shale, W½ sec. 5 + NE¼ sec. 6, T. 12 N., R. 57 E. + south-central ½ sec. 35, T. 13 N., R. 57 E., southwest of Wibaux (= Mingusville), Wibaux County, Montana. [Biostratigraphic information may be more precise for a particular specimen, as recorded in the field notes and on the label].
3270. Baculites baculus Zone, Pierre Shale, SW 1/4 sec. 6, T. 13 N., R. 56 E., south of Glendive, Dawson County, Montana. [Biostratigraphic information may be more precise for a particular specimen, as recorded in the field notes and on the label].
3730 (= G71488). Baculites baculus–B. grandis zones, mostly in and below 8 ft (2.4 m) thick bentonite noted by Gill and Cobban (1966), upper unnamed shale member, Pierre Shale, in an area trending northeast across Brewster Draw, 2.1–2.5 mi (3.4–4.0 km) north-northeast of Red Bird, from SW ¼ to NW¼ NE¼ NE¼ sec. 14, T. 38N., R. 62W., Niobrara County, Wyoming. 1988. [Biostratigraphic information may be more precise for a particular specimen, as recorded in the field notes and on the label].
3921. Baculites baculus–B. grandis zones, Pierre Shale, Cedar Creek Anticline, Wibaux, Dawson, Fallon, and Prairie counties, Montana. [Biostratigraphic information may be more precise for a particular specimen, as recorded in the field notes and on the label].
USGS LOCALITIES
7215. Pierre Shale, sec. 28, T. 46 N., R. 64 W., Weston County, Wyoming. 1911.
9797. Bearpaw Shale, NW¼ sec. 5, T. 2 N., R. 19 E., Stillwater County, Montana. W.T. Thom, Jr., for E.T. Hancock. 1916.
10771. Bearpaw Shale, concretions in bed of Prairie Elk Creek 0.25 mi (0.4 km) southeast of ranch house, sec. 35, T. 26 N., R. 45 E., McCone County, Montana. W.T. Thom and T.W. Stanton. 1921.
11217. Upper part of Pierre Shale, about 100 ft (30.5 m) below base of Fox Hills Formation, about 6.5 mi (10.4 km) east of Upton, Weston County, Wyoming. C.R. Longwell and W.W. Rubey. 1922.
12745. Baculites baculus Zone, Pierre Shale, south of Glendive, Dawson County, Montana. E.E. Teller. 1924.
22141. Bearpaw Shale, 100 - 150 ft (30.5 - 45.7 m) below the Fox Hills Sandstone. SE¼ sec. 11, T. 26 N., R. 41 E., Valley County, Montana. F.S. Jensen. 1949.
22142. Baculites elaisi Zone, upper part of Bearpaw Shale, E½ sec. 5 and W½ sec. 4, T. 26 N., R. 42 E., Valley County, Montana. W.A. Cobban and F.S. Jensen. 1948.
23396. Bearpaw Shale, NE¼ SW¼ sec. 23, T. 27 N., R. 45 E., Valley County, Montana. R.B. Colton. 1950. [Collection mixed in office, but all specimens believed to be from same horizon].
23399. Bearpaw Shale, SW¼ NE¼ sec. 23, T. 27 N., R. 45 E., Valley County, Montana. R.B. Colton. 1950.
D430. Baculites baculus Zone, red concretion zone at top of middle member, Pierre Shale, 7 mi (11.2 km) southeast of Moorcroft, sec. 2, T. 48 N., R. 67 W., Weston County, Wyoming. W.J. Mapel, C.S. Robinson, and W.A. Cobban. 1955.
D1047. Baculites baculus Zone, Pierre Shale, from gray calcareous concretions 77–87 ft (23.5 - 26.4 m) below top, 10 mi (16 km) south of Glendive, near center of E½ E½ sec. 27, T. 14 N., R. 55 E., Dawson County, Montana (same locality as D1045). W.A. Cobban. 1956.
D1636. Baculites eliasi Zone, Pierre Shale, from ferro-calcareous concretions 190–200 ft (57.9–60.1 m) below top of Kara Bentonitic Member, E½ NE¼ NW¼ sec. 23, T. 38 N., R. 62 W., Niobrara County, Wyoming (same locality as D1956). H.A. Tourtelot, J.R. Gill, C.S. Robinson, W.J. Mapel, and W.A. Cobban. 1957, 1958.
D1967. Baculites eliasi Zone, Pierre Shale, from limestone concretions 37 ft (11.3 m) above top of Kara Bentonitic Member, NE¼ NW¼ SE¼ sec. 14, T. 38 N., R. 62 W., Niobrara County, Wyoming (same locality as D1959). J.R. Gill, W.J. Mapel, C.S. Robinson, and H.A. Tourtelot. 1958.
D1973. Baculites baculus Zone, Pierre Shale, from brownish limestone concretions 117 ft (35.7 m) above top of Kara Bentonitic Member, SW¼ NE¼ NE¼ NW¼ sec. 23, T. 38 N., R. 62 W., Niobrara County, Wyoming (same locality as D1971). W.A. Cobban. 1958.
D1974. Baculites baculus Zone, Pierre Shale, from highly fossiliferous limestone concretions 147 ft (44.8 m) above top of Kara Bentonitic Member, SW¼ NE¼ NW¼ sec. 23, T.38 N., R. 62 W., Niobrara County, Wyoming. W.A. Cobban. 1958.
D1975. Baculites baculus Zone, Pierre Shale, same level as D1974, near center of north line of NE¼ NW¼ SE¼ sec. 14, T. 38 N., R. 62 W., Niobrara County, Wyoming. H.A. Tourlelot, W.J. Mapel, J.R. Gill, C.S. Robinson, and W.A. Cobban. 1958.
D1976. Baculites baculus Zone, Pierre Shale, from a gray limestone concretion 157 ft (47.8 m) above top of Kara Bentonitic Member, SW¼ NE¼ NE¼ NW¼ sec. 23, T. 38 N., R. 62 W., Niobrara County, Wyoming (same locality as D1971). W.A. Cobban. 1958.
D1981. Baculites baculus Zone, Pierre Shale, about 205 ft (62.5 m) above top of Kara Bentonitic Member, S½ SE¼ SE¼ SW½ sec. 14, T. 38 N., R. 62 W., Niobrara County, Wyoming (same locality as D1978). J.R. Gill, W.J. Mapel, C.S. Robinson, and H.A. Tourtelot. 1958.
D3338. Lewis Shale, about 100 ft (30.5 m) above base, SE¼SW¼ sec. 6, T. 21 N., R. 88 W., Carbon County, Wyoming. H.A. Tourtelot. 1961.
D4760 (G64-1-4) = D4761 (G64-1-19). Baculites eliasi Zone, Lewis Shale, NE¼ SW¼ sec. 19, T. 23 N., R. 79 W., Carbon County, Wyoming. R.C. Givens. 1964.
YPM LOCALITIES
A4778. Lower part of Baculites baculus Zone, unit 89 of Traverse A (Gill and Cobban, 1966), upper unnamed shale member, Pierre Shale, gulley west of fence, 1.8 mi (2.9 km) northeast of Red Bird, NW¼ sec. 23, T. 62 W., R. 38 N., Niobrara County, Wyoming. K.M. Waage and C.W. Byers II, 1971.
A6520. Pierre Shale, Sage Creek, Pennington County, South Dakota. G.A. Clarke, 1860. (Questionable locality because of the date of the collection)
A6521. Fort Yates, Sioux County, North Dakota. 1893. (Questionable locality because of the date of the collection)
C1503. Baculites baculus Zone, Pierre Shale, Wibaux (= Mingusville), Wibaux County, Montana.
C3353. Pierre Shale, west of Moorcroft, Crook County, Wyoming. K.M. Waage and E. Dorf, 1937.