A large pelagic lobopodian from the Cambrian Pioche Shale of Nevada

Christian R.A. McCall

doi:10.1017/jpa.2023.63

A large pelagic lobopodian from the Cambrian Pioche Shale of Nevada

Published online by Cambridge University Press: 13 December 2023

Christian R.A. McCall

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Christian R.A. McCall*: Affiliation:
Otterville, Ontario N0J 1R0, Canada
*: *Corresponding author.

Article contents

Abstract
Non-technical Summary
Introduction
Geological setting
Materials and methods
Systematic paleontology
Discussion
Declaration of competing interests
Data availability statement
References

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Abstract

Lobopodians are an iconic and diverse group of animals from the Cambrian, which alongside radiodonts, present an important window into the evolution of arthropods and the development of Paleozoic ecosystems. Of these, a rare few species outside of Radiodonta possess lateral swimming flaps. The recent discovery of Utahnax provided much-needed insight into the evolution of swimming flaps, suggesting that the ventrolateral flaps of Kerygmachela evolved independently from other flap-bearing lobopodians and radiodonts. Here a new pelagic lobopodian species is described, Mobulavermis adustus new genus new species, the first lobopodian to be reported from the Cambrian-age Pioche Shale of Nevada. Mobulavermis adustus was large and possessed more ventrolateral flap pairs than any other known lobopodian or radiodont. It is found to be a close relative of both Kerygmachela and Utahnax, allowing the establishment of the new lobopodian family Kerygmachelidae new family. In addition, an indeterminate euarthropod fossil from the Pioche Formation is described in brief, and the recently described Chengjiang species Parvibellus avatus Liu et al., 2022, thought to have been related to the “gilled lobopodians,” is reinterpreted as a juvenile siberiid lobopodian.

UUID: http://zoobank.org/759c4eb9-ec60-4d5a-8b20-4f115ab79575

Type: Articles
Information: Journal of Paleontology , Volume 97 , Issue 5 , September 2023 , pp. 1009 - 1024

DOI: https://doi.org/10.1017/jpa.2023.63 [Opens in a new window]
Copyright: Copyright © The Author(s), 2023. Published by Cambridge University Press on behalf of The Paleontological Society

Non-technical Summary

Lobopodians are an iconic group of animals from the Paleozoic that includes Hallucigenia and Opabinia, as well as living animals such as tardigrades and velvet worms. They would also eventually give rise to the first arthropods by developing a hard, sclerotized exoskeleton. During the Cambrian, a rare subset of lobopodians possessed large swimming flaps, sometimes alongside ventral walking limbs. A new, large-bodied pelagic lobopodian from the Cambrian of Nevada is described, possessing more swimming flaps than any other lobopodian or radiodont.

Introduction

Although popularly considered to be oddities of the Cambrian period that quickly disappeared from the fossil record (Gould, Reference Gould1989), recent discoveries have clarified that lobopodians and radiodonts played a considerable role in Paleozoic ecosystems (Lerosey-Aubril and Ortega-Hernández, Reference Lerosey-Aubril and Ortega-Hernández2022). Lobopodians persisted all the way into the Carboniferous period in the form of marine and onychophoran-like forms from the Mazon Creek Fauna (Murdock et al., Reference Murdock, Gabbott and Purnell2016) and persist today in the form of onychophorans (velvet worms) and tardigrades. Schinderhannes bartelsi Kühl et al., Reference Kühl, Briggs and Rust2009, a diminutive peytoiid, is the youngest known radiodont fossil, dated to the Early Devonian. Radiodonts form a monophyletic group sister to Arthropoda (Moysiuk and Caron, Reference Moysiuk and Caron2022), while the term “lobopodian” has taken on a looser definition. By modern usage, “lobopodians” refers to a paraphyletic group of rare, vermiform, basal panarthropods with lobopodous limbs, or occasionally soft swimming flaps (Caron and Aria, Reference Caron and Aria2020). Radiodonts, owing to their more easily preserved sclerotized appendages and cephalic carapace elements, are described more frequently (Wu et al., Reference Wu, Ma, Lin, Sun, Zhang and Fu2021b) and continue to be discovered at a mostly steady rate.

Among these discoveries, however, very few known nonradiodont taxa belong to the stem arthropods. These animals, known from only a small number of species, include the siberiids (three or four species), the “gilled lobopodians” (three species), and the opabiniids (three or four species). Siberiids, which essentially resemble their onychophoran-branch relatives but with more obvious adaptations for predation, may have been some of the first raptorial animals on the planet according to phylogenetic bracketing (Howard et al., Reference Howard, Giacomelli, Lozano-Fernandez, Edgecombe and Fleming2022), while opabiniids, known only from a single species before the recent descriptions of Utaurora comosa Pates et al., 2022 (Pates et al., Reference Pates, Botting, Muir and Wolfe2022a) and two specimens from the Ordovician of Wales (Pates et al., Reference Pates, Wolfe, Lerosey-Aubril, Daley and Ortega-Hernández2022b), are famously unique, even among other Cambrian taxa. The gilled lobopodians are perhaps some of the least well understood, being known only from two species from the Sirius Passet Lagerstätte of Greenland and, questionably, the recently described Utahnax vannieri Lerosey-Aubril and Ortega-Hernandez, Reference Lerosey-Aubril and Ortega-Hernández2022. The Sirius Passet species, Pambdelurion whittingtoni Budd, Reference Budd, Fortey and Thomas1997 and Kerygmachela kierkegaardi Budd, Reference Budd1993, were initially described as gilled lobopodians for their supposed possession of lobopodous ventral limbs and setal-gill bearing dorsal flaps. Since their descriptions in the 1990s, we have learned more about Pambdelurion and Kerygmachela, from numerous fossils of the former and relatively rare fossils of the latter (Lerosey-Aubril and Ortega-Hernandez, Reference Lerosey-Aubril and Ortega-Hernández2022). At the same time, the nature or presence of “gills” in either taxa remains insufficiently demonstrated, as are the ventral lobopods of Kerygmachela. These taxa are of great importance to our understanding of arthropod evolution and yet remain poorly understood. Here a new “gilled lobopodian” related closely to Kerygmachela and Utahnax is described from the Pioche Shale of Nevada, representing the first and only known lobopodian from the formation.

Geological setting

The lobopodian fossils described herein are recorded (Lieberman, Reference Lieberman2003) as having originated from the same locality (the Ruin Wash locality, west side of Chief Range, 17 km west of Panaca) in the Comet Shale Member (Delamaran) strata of the Pioche Shale in Nevada, USA, within a depositional setting of the then equatorial southern Great Basin (Pates et al., Reference Pates, Daley, Edgecombe, Cong and Lieberman2021b) along the inner shelf of the paleocontinent Laurentia (Wotte and Sundberg, Reference Wotte and Sundberg2017). However, other non-lobopodian specimens recorded as having derived from the same locality within the Comet Shale Member have since been restudied and assigned to the slightly older, underlying Combined Metals Member (Dyeran) (Pates et al., Reference Pates, Daley, Edgecombe, Cong and Lieberman2021b). The lobopodian fossils described here are preserved in yellows, oranges, and dark red colors, which, on the basis of previous textural and elemental analyses of coeval soft-bodied specimens (Moore and Lieberman, Reference Moore and Lieberman2009), suggests they are preserved as botryoidal hematite (Fe₂O₃), the expected mode of preservation for soft-bodied fossils in the Combined Metals Member. Soft-bodied faunal elements from the Comet Shale Member, which are preserved as a kerogenized carbon film, do not demonstrate the same dramatic reddish coloration. A previously described radiodont appendage belonging to Anomalocaris magnabasis Pates et al., Reference Pates, Daley, Edgecombe, Cong and Lieberman2021b and displaying a comparable coloration and mode of preservation, KUMIP 293605, was previously described by Lieberman (Reference Lieberman2003) as coming from the Comet Shale Member but is now known to have come from the Combined Metals Member (Pates et al., Reference Pates, Daley, Edgecombe, Cong and Lieberman2021b). Other soft-bodied taxa collected from Pioche Shale include Canadaspsis perfecta Walcott, Reference Walcott1912, ?Perspicaris dilatus Robison and Richards, Reference Robison and Richards1981, Anomalocaris magnabasis Pates et al., 2021 (Pates et al., Reference Pates, Daley, Edgecombe, Cong and Lieberman2021b), Herpetogaster collinsi Caron et al., Reference Caron, Morris and Shu2010, Alalcomenaeus sp., Hurdia sp., Tuzoia spp., Ottoia sp., an indeterminate panarthropod (KUMIP 293606, see description in the following), and an indeterminate sclerotized tergite previously considered to be a radiodont flap (Lieberman, Reference Lieberman2003; Foster, Reference Foster2014; Kimmig et al., Reference Kimmig, Meyer and Lieberman2019; Ortega-Hernández et al., Reference Ortega-Hernández, Lerosey-Aubril and Pates2019; Pates et al., Reference Pates, Daley, Edgecombe, Cong and Lieberman2021b).

Materials and methods

The two specimens of the new lobopodian were studied through numerous photographs (dry and under liquid immersion) taken and provided by KUMIP staff. Photographs of KUMIP material were taken using a Canon EOS 7D Mark II at a focal length of 50 mm and using a Canon EOS 500D at a focal length of 60 mm, all by KUMIP staff. Figures were prepared using Adobe Photoshop 23.2.2. Photographs of specimens were adjusted digitally for enhanced color and contrast.

Phylogenetic methods

A phylogenetic matrix of 168 morphological characters for 69 taxa was compiled, referenced primarily from previous phylogenetic studies focusing on radiodont taxa and other basal panarthropods. Many characters were modified from previous studies or added, and in the case of the phylogenetic matrix used by Zeng et al. (Reference Zeng, Zhao and Zhu2023), many characters were removed, as coding discrete characters for endites and podomeres with great specificity resulted in a tree topology far less precise than coding using a smaller, but still specific, set of characters that code for the frontal appendages more generally. The trees were rooted on the aysheaiid lobopodian Aysheaia pedunculata Walcott, Reference Walcott1911b, a consistently basal species (often recovered as basal to the total-group onychophoran/total-group arthropodan split) (Howard et al., Reference Howard, Hou, Edgecombe, Salge, Shi and Ma2020). Kerygmachela specifically was coded following the alternative flap origin hypothesis argued for in Lerosey-Aubril and Ortega-Hernandez (Reference Lerosey-Aubril and Ortega-Hernández2022), which is further supported by the morphology of the new lobopodian described herein. The morphological matrix was assembled using Mesquite 3.70 (Maddison and Maddison, Reference Maddison and Maddison2021), analyzed using TNT 1.5 (Goloboff and Catalano, Reference Goloboff and Catalano2016), using New Technology Search with Sectorial Search, Rachet, Drift, and Tree Fusing all enabled under standard settings, set to find the minimum length 500 times, under equal weights (concavity constant k = 3, 4, 10) and under implied weighting, and with the option to collapse trees after search enabled, and visualized using TreeGraph 2.15 (Stöver and Müller, Reference Stöver and Müller2010). The morphological matrix and list of taxa and characters, including notes on characters added or changed from previous studies, are included with the supplementary information.

Repositories and institutional abbreviations

All Pioche Shale specimens are housed at the University of Kansas, Biodiversity Institute, Division of Invertebrate Paleontology collections (KUMIP). Material of Kerygmachela studied through photographs for comparison is deposited at the Geological Museum, Natural History Museum of Denmark, University of Copenhagen (MGUH). The holotype of Parvibellus avatus Liu et al., Reference Liu, Dunlop, Steiner and Shu2022 is deposited in the Early Life Institute (ELI) of Northwest University, Xi'an, China.

Systematic paleontology

Superphylum Panarthropoda Nielsen, Reference Nielsen1995
Family Kerygmachelidae new family

Type genus

Kerygmachela Budd, Reference Budd1993.

Other taxa included

Utahnax Lerosey-Aubril and Ortega-Hernández, Reference Lerosey-Aubril and Ortega-Hernández2022, Mobulavermis n. gen.

Diagnosis

Lobopodians with lobopod-derived ventrolateral swimming flaps and lacking dorsal flaps or setal blades; trunk elongate, roughly cylindrical, and annulated; paired frontal appendages large and raptorial.

Remarks

Although formerly grouped together under the informal title “gilled lobopodians” (Young and Vinther, Reference Young and Vinther2017), the morphological disparity between Kerygmachela and Pambdelurion is evident. Their anatomical differences extend from the caudal spine (one long telson-like caudal spine in Kerygmachela, contrasted with Pambdelurion's short pair of annulated cerci) to their heads, where they are perhaps most different. While their large frontal appendages are outwardly similar, the head of Pambdelurion is also dominated by a large ventral-facing extensible mouth, lined on either side with strongly sclerotized triangular teeth (Vinther et al., Reference Vinther, Porras, Young, Budd and Edgecombe2016). The mouth of Kerygmachela, by contrast, is small and forward set and opens anteriorly; it apparently lacks sclerotized teeth and possesses instead a pair of stylet-like spines on either side of the mouth, originating just behind it (Park et al., Reference Park, Kihm, Woo, Park, Lee, Smith, Harper, Young, Nielsen and Vinther2018). Despite these differences, however, they have long been isolated from the rest of the lobopodians, with their closest relatives being basal siberiids lacking swimming flaps and eyes, and the opabiniids, with numerous eyes and their frontal appendages conjoined up to their anterior into a fleshy, annulated proboscis (a notable exception is Omnidens amplus Hou et al., Reference Hou, Bergström and Jie2006, known only from the mouthparts, which bear tremendous similarity to those of Pambdelurion; comparison of the two suggests that Omnidens could reach sizes up to 1.5–1.7 m, making it the largest known Cambrian animal, awaiting confirmation from more-complete remains). For this reason, the term “gilled lobopodian” has continued to be used, in lieu of more taxa to clarify their relationships with other lobopodians. The description of Utahnax (Lerosey-Aubril and Ortega-Hernández, Reference Lerosey-Aubril and Ortega-Hernández2022) was a welcome and necessary addition to this grade of flap-bearing lobopodians and cast further doubt on the presence of ventral lobopods in Kerygmachela, and its relationship to Pambdelurion. The discovery of yet another new flap-bearing lobopodian closely related to Kerygmachela allows the formal establishment of a family clade containing Kerygmachela, and yet excluding Pambdelurion. Whether or not ventral lobopods are genuinely absent in the kerygmachelids (Utahnax, Kerygmachela, and the new lobopodian species) could still be considered ambiguous, particularly in the case of Kerygmachela from the often difficult-to-interpret fossils of the Sirius Passet; however, the available evidence strongly favors the alternative hypothesis presented by Lerosey-Aubril and Ortega-Hernández (Reference Lerosey-Aubril and Ortega-Hernández2022).

Genus Mobulavermis new genus

Type species

Mobulavermis adustus, by monotypy.

Diagnosis

As for type species, by monotypy.

Etymology

From Mobula, the genus name of extant manta rays and devil rays, drawing comparison to the elongate flexible caudal spines and broad swimming flaps of Mobula rays, which resemble the outline of the new taxon, combined with the Latin vermis, meaning “worm.”

Remarks

As for species.

Mobulavermis adustus new species
Figures 1, 2, 3.1–3.4, 3.6, 4

Reference Lieberman2003: Anomalocaridid gen. indet. sp. indet.; Lieberman, p. 683, fig. 6.4.
Reference Lerosey-Aubril and Ortega-Hernández2022: indeterminate anomalocaridid; Lerosey-Aubril and Ortega-Hernández, p. 15.

Figure 1. Mobulavermis adustus KUMIP 298510 (holotype) from the Pioche Shale, middle Cambrian, Nevada: (1) KUMIP 298510a (part), immersed, showing curving body and caudal spine preserved in negative relief; (2) KUMIP 298510b (counterpart), immersed, with caudal spine in strong positive relief; (3) KUMIP 298510b (counterpart), dry, closeup of caudal spine in positive relief and some reduced terminal flaps; (4) KUMIP 298510a (part), immersed, closeup of trunk interior, showing digestive tract, possible gut gland, and possible evidence of strong trunk annulation; (5) KUMIP 298510b (counterpart), dry, closeup of flap surfaces near anterior of specimen. Scale bars = 10 mm. afm = anterior flap margin; an = annulations; bw = body wall; cs = caudal spine; dt = digestive tract; fo = flap ornamentation; mg = midgut gland; pfm = posterior flap margin; tf = terminal reduced flaps.

Figure 2. Mobulavermis adustus KUMIP 298510 (holotype) from the Pioche Shale, middle Cambrian, Nevada: (1) KUMIP 298510a (part), dry; (2) interpretative drawing of Mobulavermis adustus KUMIP 298510. Scale bars = 10 mm. Abbreviations as in Figure 1.

Figure 3. Mobulavermis adustus KUMIP 298511 (paratype) and indeterminate euarthropod KUMIP 293606 from the Pioche Shale, middle Cambrian, Nevada: (1) Mobulavermis adustus KUMIP 298511a (part), immersed, showing extent and outline of flaps in the posterior and middle of the body; (2) Mobulavermis adustus KUMIP 298511b (counterpart), immersed; (3) Mobulavermis adustus KUMIP 298511a (part), dry, colors inverted for clarity, with white arrows indicating approximate topographic changes between distinct lateral flaps; (4) Mobulavermis adustus KUMIP 298511b (counterpart), immersed, closeup of caudal spine and terminal reduced flaps; (5) Pioche euarthropod KUMIP 293606, normal color, dry; (6) interpretative drawing of Mobulavermis adustus KUMIP 298511 (paratype). Scale bars = 10 mm. af = anterior flap; ans = anus; ct = expanded caudal tergite; ey = eye; pl = pleura of tergite; pm = proximal margin of pleural region; ofm = outer flap margin; tc = trunk cuticle; other abbreviations as in Figure 1.

Figure 4. Comparison between Mobulavermis adustus and other lobopodian taxa: (1) Mobulavermis adustus KUMIP 298510a (holotype, part), dry, showing steep changes in elevation between successive flaps; (2) Hurdia sp. KUMIP 314057a (part) from the Spence Shale (Cambrian, Utah, USA), immersed, showing the construction of the peytoiid lateral flap as composed of numerous tightly spaced strengthening rays running the total length of the flap (note the overlapping, angled strengthening rays in the posterior of the flap); (3) Kerygmachela kierkegaardi MGUH 22.083 (holotype) from the Sirius Passet (Cambrian, Greenland); (4) Kerygmachela kierkegaardi MGUH 22.083 (holotype) from the Sirius Passet (Cambrian, Greenland), showing detail of flap wrinkles and limb-like structures; (5) Kerygmachela kierkegaardi MGUH 22.083 (holotype) from the Sirius Passet (Cambrian, Greenland), showing detail of head region; (6) Kerygmachela kierkegaardi MGUH 22.085 (paratype) from the Sirius Passet (Cambrian, Greenland); (7) Kerygmachela kierkegaardi MGUH 22.085 (paratype) from the Sirius Passet (Cambrian, Greenland), showing detail of caudal region; (8) Parvibellus avatus ELI-EJ 048A (holotype, part) from the Chengjiang Biota, Chiungchussu Formation (Cambrian, Yunnan, China) (9) Anomalocaris magnabasis KUMIP 293605 frontal appendage, immersed, from the Combined Metals Member, showing a deep red coloring, owing to heavy hematite concentration; (10) Anomalocaris magnabasis KUMIP 307022 frontal appendage, immersed, from the Comet Shale Member, which is not associated with hematitic preservation, showing a desaturated blueish hue. Photographs of Kerygmachela were provided by M. L. Nielsen on behalf of the Natural History Museum of Denmark. The photograph of Parvibellus is adapted from Liu et al. (Reference Liu, Dunlop, Steiner and Shu2022), under CC BY 4.0. Scale bars = 10 mm. en = endite; fa = frontal appendage; fm = flap musculature; lo = lobopodous limbs; oc = oral cone; pfm = proximal flap margin; phr = pharynx; psr = posterior strengthening ray; sr = strengthening ray; tf = tail fan; tn = trunk dorsal node; wr = wrinkled surface of flap. Other abbreviations as in Figures 1 and 3.

Type specimens

Holotype: KUMIP 298510, part and counterpart, a large, incomplete individual preserving the posterior portion of the body, including a caudal spine. Paratype: KUMIP 298511, part and counterpart, a smaller, also incomplete individual preserving the posterior portion of the body.

Diagnosis

Lobopodian with vermiform body terminating in an elongate, flexible caudal spine; numerous broad, densely packed, lobopod-derived ventrolateral body flaps strongly overlapping successively; posterior ventrolateral body flaps decreasing in size linearly toward base of caudal spine until becoming flush with trunk; ventrolateral body flap posterior margins convex, anterior margin begins perpendicular to body wall before gradually curving posteriorly.

Occurrence

Pioche Formation, Combined Metals Member (Cambrian Series 2, Stage 4, Nephrolenellus multinodus Biozone), Lincoln County, Nevada; Ruin Wash locality, 17 km west of Panaca, west side of Chief Range, NW 1/4, SW 1/4, Sec 15, R65E TS2.

Description

The holotype specimen (KUMIP 298510) of Mobulavermis adustus n. gen. n. sp. is a probably ventrally exposed specimen, following the interpretation of Budd (Reference Budd1999) where the flaps are imbricated normally; see also MGUH 32.061, which demonstrates the normal imbrication of the swimming flaps (Park et al., Reference Park, Kihm, Woo, Park, Lee, Smith, Harper, Young, Nielsen and Vinther2018, supp. fig. 9d, e), unlike the reverse imbrication of radiodont flaps (Daley and Edgecombe, Reference Daley and Edgecombe2014), preserving the posterior portion of the body (Fig. 1). The specimen is dark red to yellowish due to a high concentration of weathered hematite. The total length of the body is unknown, but the preserved portion of the holotype measures 80.60 mm (measured along the sagittal curve of the trunk) long and 11.5 mm at the greatest width of the trunk, excluding the ventrolateral flaps, which are easily distinguished from the trunk by a strong and steep shift in color, seen as a bright orange-yellow border on each side of the body, with little preserved between. In some places, evidence of annulation may be present (Fig. 1.1, 1.4), although little of the actual trunk surface is preserved. On either side of the preserved portion of the body are at least 11 or 12 ventrolateral swimming flaps visible (red to dark red), although they are often poorly delineated. The flaps are broad and strongly imbricated and show no evidence of annulation, ruling out the possibility that they represent large lobopodous appendages. The posterior margins of the flaps are typically more clearly visible and show a gently convex outline (Fig. 1.1, 1.2). The anterior margins of the flaps are preserved less often but are apparently perpendicular to the body wall for much of the length of the flap before also developing a slight convex curve. The maximum length of the longest exposed ventrolateral flap (close to the anterior of the body; Fig. 1.1, 1.2, 1.5) is 19.1 mm, although the flap appears to continue beyond this. The flaps appear uniformly flat and apparently without any kind of anterior zone or radiodont-like strengthening rays. The largest of the flaps, previously mentioned, perhaps shows traces of wrinkled ornamentation running distally and slightly posteriorly, similar to that observed in Kerygmachela and Utahnax (Lerosey-Aubril and Ortega-Hernández, Reference Lerosey-Aubril and Ortega-Hernández2022); however, this could also be taphonomic wrinkling.

The exposed portion of the digestive tract (Fig. 1.4), orange in color, measures 2.1 mm in width and, judging from the paratype, probably terminates at the base of the caudal spine, where the flaps end. The caudal spine is elongate, unsegmented, and probably flexible and transitions smoothly from the trunk-bearing portion of the body with no marked change in width or shape, unlike what is seen in Kerygmachela, where the caudal spine reduces to nearly half the width of the trunk at the anus (Park et al., Reference Park, Kihm, Woo, Park, Lee, Smith, Harper, Young, Nielsen and Vinther2018). Notably, there is a fair degree of three-dimensional preservation to the caudal spine. The caudal spine is shorter than that of Kerygmachela, at least in this specimen, and probably somewhat flexible judging from the slight curve of the caudal spine seen in both the holotype and paratype, in contrast to the entirely stiff caudal spine of Kerygmachela (Fig. 4.7). Toward the posterior of the trunk, close to the body wall, is a single reddish subcircular structure (2.3 mm at its widest) with flat relief (Fig. 1.1, 1.2, 1.4). The structure is incomplete, unlikely to represent the insertion point of a walking limb, but could represent a gut gland or, less likely, a dorsal tubercule (Fig. 2).

The paratype specimen (KUMIP 298511) is of a smaller individual (~ 50.7 mm along the sagittal curve of the trunk), also preserving only the posterior portion of the body (Fig. 3). The trunk in this specimen is perhaps faintly annulated and, perhaps due to its smaller size (3.3 mm at its widest), is more completely preserved, although the trunk disappears almost entirely a short distance anteriorly. Small and isolated portions of the bright orange trunk region are still present down the length of the whole specimen (Fig. 3.1, 3.2), showing that the trunk follows a gentle sinusoidal curve and probably changes little in width anteriorly. The trunk displays the same banded coloration of oranges, yellows, and dark reds observed in the holotype specimen. The posterior portion of the digestive tract (the preserved portion of which is 2.3 mm long and 0.5 mm wide) is visible as a much lighter-colored stripe in the middle of the trunk, tapering posteriorly, in contrast to the dark reds and blacks that overlie it down most of the trunk length. Where the digestive tract tapers and abruptly terminates may indicate the position of the anus, around where the ventrolateral flaps are at their smallest but just before the flaps disappear entirely, giving way to the caudal spine. The paratype specimen better illustrates the general outline of the animal. The outline, including all observable ventrolateral flaps, could be described as cordate or acuminate posteriorly, where the ventrolateral flaps are widest in the middle of the body, gently tapering toward the posterior. The tapering of the posterior flaps then becomes more gradual, such that the distal outline of the ventrolateral flaps joins smoothly to the outline of the caudal spine. The distance between successive flaps shrinks posteriorly along with their size. The caudal spine is mostly straight and appears to be incompletely preserved posteriorly. The distal outline of the ventrolateral flaps is essentially smooth and unbroken down its entire length, excluding areas where parts of the flap surface are missing. The ventrolateral flaps are mostly orange red or very dark red/black, darkening at the edges. In some places along these edges, yellowish preserved organic material appears to bleed out of the edge of the orange-red flaps (Fig. 3.2). These areas of yellow staining may represent the original distal boundaries of the ventrolateral flaps or may be a taphonomic artifact. Steep changes in elevation that occur down the length of the specimen demarcate new flap surfaces, demonstrating that this is not a continuous structure but instead densely arranged flaps taking on the appearance of a continuous surface (Fig. 3.3). The preserved portion of the trunk appears to bear at least 18 or 20 ventrolateral trunk flap pairs, more than observed in any other known gilled lobopodian (Budd, Reference Budd, Fortey and Thomas1997), radiodont (Pates et al., Reference Pates, Lerosey-Aubril, Daley, Kier, Bonino and Ortega-Hernández2021a; Zeng et al., Reference Zeng, Zhao and Zhu2023), or opabiniid (Pates et al., Reference Pates, Botting, Muir and Wolfe2022a). Like the holotype, the total length of the body in this specimen cannot be reliably estimated, but there were likely more flap pairs on the remainder of the body that are not preserved here.

Considering that the preserved portions of KUMIP 298510 and KUMIP 298511 are similar in overall size (80.6 mm and 50.7 mm long along the trunk, respectively), the mismatch of their relative proportions is problematic. The trunk region of KUMIP 298510 is ~3.5 times wider than that of KUMIP 298511, and the posteriormost flaps of KUMIP 298510 appear much larger and more developed than the gradually reducing flaps at the base of the caudal spine region in KUMIP 298511. While the trunk region could have grown wider proportionally through ontogeny, comparison between the two specimens, including caudal spine length and ventrolateral flap pair count, still suggests that the larger KUMIP 298510 represents the equivalent of only the posterior half of the smaller KUMIP 298511. If the trunk flap count for each specimen is correct, or close, this suggests that the complete trunk length of KUMIP 298510 may have been around 20 cm (representing only half the body portion shown in the paratype), not including the reconstructed head or frontal appendages and not considering the likely possibility that the trunk continues beyond the 18–20 flaps preserved in KUMIP 298511. At their longest from base to tip, the frontal appendages of Kerygmachela kierkegaardi are roughly equal in length to the flap-bearing trunk section (Park et al., Reference Park, Kihm, Woo, Park, Lee, Smith, Harper, Young, Nielsen and Vinther2018). By direct comparison, the frontal appendages of Mobulavermis could have reached up to ~20 cm, although the frontal appendages of Mobulavermis may have been considerably shorter (perhaps closer to only ~10 cm), as the frontal appendages of Kerygmachela bear extremely elongate terminal spines (the “outermost frontal processes” of Park et al. [Reference Park, Kihm, Woo, Park, Lee, Smith, Harper, Young, Nielsen and Vinther2018]) and may represent an extreme among the group. Regardless, Mobulavermis adustus may have been among one of the largest known lobopodians. A conservative estimate for the total body length of Mobulavermis, from tail spine to the end of the frontal appendages, could be ~30 cm, and more maximally ~50 cm, assuming the holotype is fully grown.

Etymology

From the Latin adustus, meaning “burnt,” “singed,” or “sun-burnt,” in reference to the dramatic yellow, red, and black coloration of the two known specimens and to the arid conditions of the type locality.

Remarks

M. adustus represents the first, and currently only, described species of lobopodian from the Pioche Shale of Nevada. The description of this new taxon is based on two specimens collected from the Ruin Wash locality in the late 1990s by Allison Palmer. Lieberman (Reference Lieberman2003) presented a report on the soft-bodied fauna of the Pioche Shale, which included a number of anomalocaridid remains, since interpreted as belonging mostly to Anomalocaris magnabasis (Pates et al., Reference Pates, Daley, Edgecombe, Cong and Lieberman2021b). Among these, three possible anomalocaridid body fossils were briefly described, the first of which was figured while the second was only discussed. The first two body fossils are here described under a new genus, while the final body specimen mentioned, KUMIP 293606, is better interpreted as a euarthropod and is inconsistent with either fossil of the species described herein or with any radiodont body fossil. This new taxon represents one of only a handful of flap-bearing lobopodians known around the world (Pambdelurion whittingtoni, Kerygmachela kierkegaardi, Utahnax vannieri, and Omnidens amplus, which is known only from the mouth [Vinther et al., Reference Vinther, Porras, Young, Budd and Edgecombe2016], which is similar enough to the smaller Pambdelurion that some authors consider Omnidens to be Pambdelurion sp. rather than a distinct genus [Du et al., Reference Du, Ortega-Hernández, Yang, Yang and Guo2020]), and even fewer in which the swimming flaps are derived from the ventrolateral lobopods (Lerosey-Aubril and Ortega-Hernández, Reference Lerosey-Aubril and Ortega-Hernández2022) rather than being paired with them, providing further insight into the problem of ventral lobopods in Kerygmachela.

Phylum Euarthropoda Lankester, Reference Lankester1904
Class, Order, and Family uncertain
Pioche euarthropod KUMIP 293606
Figure 3.5

Reference Lieberman2003: Anomalocaridid gen. indet. sp. indet.; Lieberman, p. 683, fig. 6.3.
Reference Moore and Lieberman2009: Anomalocaris; Moore and Lieberman, p. 58.

Occurrence

Description

KUMIP 293606 (Fig. 3.5) is a small soft-bodied panarthropod fossil, incomplete along the right side of the trunk. The animal is curved, with the intensity of the curve increasing toward the posterior. The outline of the animal is oblong, with the widest point slightly anterior to the middle of the body. The head is preserved mostly along its margins, with a large empty space of exposed matrix occupying the middle of the cephalic region. On the left side of the head is a possible diminutive eye tucked into the margin of the head; a similar structure on the right side of the head may represent the other eye, but the differentiation from the rest of the cephalic carapace on this side is less clear. The entire specimen is a uniform orange-red color, which becomes desaturated or obscured toward the middle of the specimen, except for a distinct linear structure in the axial region, which corresponds to a thin, central gut without any obvious extensions and which terminates at about the widest point of the body, and a second linear trace that probably represents a deviation or fold in the shape of the carapace. This second trace is mirrored on the right side in a single well-preserved pleural structure. At the anterior of the specimen is a large and flat structure with a linear trace running through its middle anteroposteriorly, probably a raised midline of the carapace. Assuming the specimen is preserved in ventral, the pleural regions imbricate normally. The distal margins of each pleural structure are mostly straight and smooth parallel to the axial region, and the anterior and posterior margins of the pleural structures are also apparently straight.

Material

KUMIP 293606, a mostly complete but poorly preserved body fossil, without an accompanying counterpart.

Remarks

KUMIP 293606 has been included here as it has been previously attributed to the Radiodonta alongside the two specimens of Mobulavermis described here (Lieberman, Reference Lieberman2003; Moore and Lieberman, Reference Moore and Lieberman2009) and thus warrants a comparison. However, this specimen is inconsistent with the two Mobulavermis specimens. The pleural structures, assumedly tergite pleura, have a broadly rectangular shape, with a sharper corner posteriorly. The preservation of the head is also inconsistent with a flap-bearing lobopodian or radiodont as, although the margins of the head are preserved, it lacks any large frontal appendages, sclerotized or not, and lacks distinct cephalic sclerites found in radiodonts, both of which should preserve more readily than the margin of the head itself. The flattened caudal tergite is also more consistent with a euarthropod than with a radiodont or lobopod. However, as the specimen is still rather poorly preserved, its exact affinities are harder to identify; the overall shape of the specimen resembles arthropods such as Mollisonia Walcott, Reference Walcott1912 and Leanchoilia Walcott, Reference Walcott1912 but matches neither exactly. Alalcomenaeus sp. is known from the Pioche formation by a well-preserved lateral specimen, but this specimen and a dorsoventrally preserved specimen from the Marjum show a very different carapace shape, particularly in the expansive, trapezoidal cephalon (Ortega-Hernández et al., Reference Ortega-Hernández, Lerosey-Aubril and Pates2019), which this specimen does not appear to have. KUMIP 293606 is left in open nomenclature.

Discussion

Comparisons with other flap-bearing panarthropods

The species most morphologically similar to Mobulavermis adustus n. gen n. sp. is Kerygmachela kierkegaardi (Fig. 4.3–4.7), with both taxa bearing broad ventrolateral swimming flaps, a roughly cylindrical body, and an elongate caudal spine devoid of flaps (Park et al., Reference Park, Kihm, Woo, Park, Lee, Smith, Harper, Young, Nielsen and Vinther2018). The similarity of the two genera allows for inferences on the anterior morphology of Mobulavermis, such as the very likely presence of sessile, ventrally situated compound eyes, a forward-facing mouth, and large raptorial frontal appendages. These inferred features, in addition to the broad flaps and the absence of walking limbs, suggest that like Kerygmachela, Mobulavermis was primarily or exclusively pelagic, although more discussion of its ecology awaits the discovery of specimens preserving the anterior morphology. Mobulavermis differs from Kerygmachela in a few aspects, however, such as Mobulavermis bearing many more pairs of flaps, which are densely spaced and more broadly shaped. In addition, the flaps of Mobulavermis gradually reduce in size until they become essentially flush with the caudal spine, which is much shorter and possibly more flexible than that of Kerygmachela. Compared with Utahnax, the swimming flaps of Mobulavermis appear much more derived—Utahnax may represent a kind of transitional form between the cylindrical limbs of siberiids and the expanded flaps of later kerygmachelids. The anterior regions of the flaps in Utahnax show evidence of evaginations of the body cavity (shown as darker staining of the surface) extending deep into the anterior of the flap, similar to the condition in the lobopodous limbs of siberiids and Opabinia regalis Walcott, Reference Walcott1912 (Lerosey-Aubril and Ortega-Hernández, Reference Lerosey-Aubril and Ortega-Hernández2022). In addition, the anterior region of the flaps in Utahnax preserve some three-dimensionality, suggesting that the anterior region may have been thicker than the posterior region (they also merge onto the same plane before the merge with the body, suggesting this topographic change is not evidence of a separate, hidden structure), which is essentially flat and unornamented. Thus, it could be proposed that in the Kerygmachelidae, ventrolateral flaps were developed not by uniform dorsoventral compression of the lobopod limbs, but by the extension of a flattened flap-like posterior margin, alongside the more gradual flattening of the lobopodous limb as a whole, such that the surface would be essentially flat in later genera (Kerygmachela and Mobulavermis show no obvious signs of a differentiated anterior region or any indication of the extent of the body cavity into the flaps).

The description of Mobulavermis lends further credibility to the hypothesis that the flaps of Kerygmachela and Utahnax are unrelated to the dorsal flaps of Pambdelurion, Opabiniidae, and a number of peytoiid radiodonts (Lerosey-Aubril and Ortega-Hernández, Reference Lerosey-Aubril and Ortega-Hernández2022). Studies on preserved musculature in panarthropods from the Sirius Passet of Greenland have suggested that musculature was absent in the flaps of Pambdelurion but present in the lobopodous ventral limbs (Young and Vinther, Reference Young and Vinther2017). This casts doubt on the swimming capabilities of Pambdelurion and, by extension, the Opabiniidae, which share homologous dorsal flaps and the controversial ventral lobopods (Budd and Daley, Reference Budd and Daley2012); recent discoveries, including the ventral lobopods of Mieridduryn bonniae Pates et al., Reference Pates, Wolfe, Lerosey-Aubril, Daley and Ortega-Hernández2022b, and small, enigmatic structures possibly attributable to lobopodous legs in the holotype of Utaurora comosa Pates et al., Reference Pates, Botting, Muir and Wolfe2022a, suggest that the lobopods of Opabinia are genuine. That the dorsal flaps are homologous to the dorsal flaps of Pambdelurion also suggests Opabinia may have moved primarily by walking on its lobopod legs rather than as an active swimmer, as previously believed. However, the same study (Young and Vinther, Reference Young and Vinther2017) on the musculature of Pambdelurion also failed to identify flap musculature in Kerygmachela (the sole specimen cited in the study as belonging to Kerygmachela more closely resembles Pambdelurion judging from its broad, anteroposteriorly tapering trunk, lack of dorsal trunk nodes, large and anteriorly widened pharynx, and wide gap between the bases of the frontal appendages).

There is at least one specimen of Kerygmachela, MGUH 25.053, which undoubtedly preserves muscle tissue, attributable to Kerygmachela by the large trunk tubercules and the mostly cylindrical trunk. In this specimen, elongate bundles of muscle fibers are found outside the boundaries of the trunk, tapering outwardly (Budd, Reference Budd1999). For each metameric segment of the body, two of these bundles are developed on either side of the body, with one pair associated with the dorsal tubercules and the other offset behind, set between successive sets of dorsal tubercules. Some of these bundles are slightly curved posteriorly. Their exact origin on the body is undetermined, but they appear to originate laterally from the body. Comparison of these muscle fiber bundles with the elongate high-relief structures, supposedly lobopodous ventral limbs in the holotype and paratype of Kerygmachela, shows that some of these limb-like structures are associated with the dorsal tubercules (holotype, Fig 4.3, 4.4), while in other specimens (paratype, Fig. 4.6), they are set between the dorsal tubercule rows. This would make little sense if they were interpreted as lobopodous limbs, both their inconsistent position and the apparently doubled number of limbs per segment. Triangular limb-like structures with positive relief are also found in MGUH 32.059 (Park et al., Reference Park, Kihm, Woo, Park, Lee, Smith, Harper, Young, Nielsen and Vinther2018, supp. fig. 8f–h), where they are associated with the dorsal tubercules, oriented perpendicular to the body, and apparently more elongate than those of the holotype and paratype of Kerygmachela.

In the complete specimen MGUH 32.048, comparable structures are seen in relief (although they are particularly shallow in this specimen) and under high-angle polarized light. In this specimen, both positional modes of these structures can be identified, associated with the dorsal tubercules and offset between them; these “non-neural impressions” (Park et al., Reference Park, Kihm, Woo, Park, Lee, Smith, Harper, Young, Nielsen and Vinther2018) extend far into the pleural region, beyond the extent of the supposed diminutive lobopod limbs (Budd, Reference Budd1993, Reference Budd1999). Non-neural impressions are further identified in other specimens under high-angle polarized lighting, showing reflective patches that connect to the trunk and extend a great distance into the pleural region (Park et al., Reference Park, Kihm, Woo, Park, Lee, Smith, Harper, Young, Nielsen and Vinther2018, supp. fig. 6). While the suggestion that one or all of these high-relief triangular structures in the holotype and paratype of Kerygmachela represent lobopodous ventral limbs, the deep pleural extension of the “non-neural impressions,” which appear to correspond to the supposed “lobopod limbs,” suggests that all of these structures may be better interpreted as muscular extensions into the ventrolateral flaps rather than distinct ventral legs. The interpretation that these two muscle-fiber bundles power a single flap rather than a pair of structures on either side of the body aligns with the known intrinsic limb musculature of Pambdelurion, which consists of a distinct promotor and remotor muscle which taper anteriorly, extending distally from the trunk (Young and Vinther, Reference Young and Vinther2017, fig. 9). Considering the limbs of Pambdelurion are homologous to either the flaps or the proposed ventral lobopods of Kerygmachela, a similar musculature should be expected, and available material suggests that these muscles belonged to the flaps. Restudy of the type material of Kerygmachela also elucidated further detail on the structures originally interpreted as setal-blade gills. While Lerosey-Aubril and Ortega-Hernández (Reference Lerosey-Aubril and Ortega-Hernández2022) described these striations as confined mostly to the distal parts of the body flaps, the holotype and paratype material show no such preference (Fig. 4.3, 4.4, 4.6). The striations, or wrinkles, are present down the entire length of the flap, ending at the trunk, directed mostly anteroposteriorly rather than posterodistally. These wrinkles overlying the paired limb-like structures (which are here interpreted as internal flap musculature) may be responsible for the appearance of “annulations” on limbs (labeled “striated limb tip” in Budd, Reference Budd1999). These wrinkles are unlikely to be related to, or analogous to, the strengthening rays of radiodonts, which must have evolved later. Their exact function is unknown, but they perhaps served a similar respiratory role to the setal-blade gills of radiodonts.

Mobulavermis can be differentiated from the radiodonts by its nearly cylindrical, extremely elongate trunk (judging from the portion of the trunk that is preserved), contrasted with the strongly posteriorly or anteroposteriorly tapering, rather compact bodies of radiodonts (Potin and Daley, Reference Potin and Daley2023); by the absence of any associated sclerotized appendages, carapace elements, or mouthparts; and by the absence of any ornamentation on its relatively well-preserved flaps (some peytoiids with dorsal flaps such as Aegirocassis Van Roy et al., Reference Van Roy, Daley and Briggs2015, have trunks that are blocky in cross section and only weakly tapering posteriorly, but this condition is very dissimilar to the present fossils and always accompanied by obvious setal blades). Radiodonts exhibit a diverse array of flap morphologies, which can be separated into a few different archetypes. Anomalocaridid and amplectobeluid radiodonts have elongate, mostly lobate flaps divided into a clear anterior zone, which is robust and strengthened by vein-like strengthening rays running anterodistally from the median of the flap to the anterior margin, and a posterior zone, which is mostly smooth and featureless (Zeng et al., Reference Zeng, Zhao and Zhu2023). In Ramskoeldia platyacantha Cong et al., Reference Cong, Edgecombe, Daley, Guo, Pates and Hou2018 and a number of isolated body flaps from the Emu Bay Shale (Daley et al., Reference Daley, Paterson, Edgecombe, García-Bellido and Jago2013), the flaps are broad and roughly triangular, with a posterior margin essentially perpendicular to the trunk axis, with a wide anterior zone ornamented with strongly anterodistally directed strengthening rays. This occasionally leads to their confusion with the body flaps of peytoiids (Zhu et al., Reference Zhu, Lerosey-Aubril and Ortega-Hernández2021). In peytoiids, flaps are generally short, either subcircular or triangular, and may be paired with dorsal flaps (Van Roy et al., Reference Van Roy, Daley and Briggs2015). The ventrolateral flaps of peytoiids are uniformly ornamented with strengthening rays that run from the base of the flap to the outer margin; in at least Peytoia Walcott, Reference Walcott1911a, there is also a posterior zone where the strengthening rays are absent or weak. The strengthening rays of peytoiids are well defined, while no such structures are observed in the fossils of Mobulavermis, nor do they match the morphology of anomalocaridid/amplectobeluid flaps with their clearly divided anterior and posterior zones. In addition, the condition of an elongate, unpaired caudal spine lacking an associated tail fan is not known in any known radiodont.

Alternative interpretation of Parvibellus

The recently discovered lobopodian Parvibellus avatus Liu et al., Reference Liu, Dunlop, Steiner and Shu2022 from the Chengjiang Fauna of Yunnan, China, was initially interpreted as a lower stem group arthropod bearing at least 11 pairs of ventrolaterally protruding, slightly overlapping trunk flaps (Fig. 4.8) described as similar to the dorsal flaps of other Cambrian lobopodian genera such as Opabinia and unlike the clawed walking legs of lobopodians such as Aysheaia. The single known specimen of Parvibellus (total length 5.25 mm) also preserved a distinct, rounded head region with a large, ventrally projecting circular mouth lined with sclerotized tooth plates, no evidence supporting the presence of eyes, and two small, unsclerotized, antennae-like frontal appendages. The trunk of the specimen is wide and preserves a simple gut running from the mouth to between the terminal pair of trunk outgrowths, described as diminutive furcae. The authors excluded the possibility of the specimen representing a juvenile or larval radiodont by comparisons with known juvenile specimens of Lyrarapax unguispinus Cong et al., Reference Cong, Ma, Hou, Edgecombe and Strausfeld2014, which are virtually identical to adult specimens (Liu et al., Reference Liu, Lerosey-Aubril, Steiner, Dunlop, Shu and Paterson2018) (a suite of juvenile Stanleycaris hirpex Pates et al., Reference Pates, Daley and Ortega-Hernandez2018 fossil specimens show that the overall shape of the radiodont body remains largely unchanged through ontogeny, with the eyes developing precociously, although there is a period of anamorphic growth where trunk segments were added posteriorly [Moysiuk and Caron, Reference Moysiuk and Caron2023]). This is highly inconsistent with an interpretation of Parvibellus as a radiodont. Parvibellus as a total-group Onychophoran lobopodian or as belonging to the more basal aysheaiids was also rejected as the trunk of Parvibellus is short, with stout, laterally projecting limbs lacking claws or obvious annulation. In addition, while the overall shape of Parvibellus could be consistent with an aysheaiid, the mouth of Parvibellus is obviously ventral and lined with large triangular tooth plates, while the mouth openings of aysheaiids are devoid of obvious sclerites and directed far anteriorly (Whittington, Reference Whittington1978).

With these groups excluded, the authors allied Parvibellus with the “APOK” group (Anomalocaridids, Pambdelurion, Opabinia, Kerygmachela). As evidence toward this placement, the authors compared the lack of eyes in their specimen with traditional reconstructions of Pambdelurion and Kerygmachela, which were both originally described as lacking eyes. However, recent evidence has demonstrated that both Kerygmachela and Pambdelurion possessed large, ventral, sessile compound eyes—long and sickle-shaped in Kerygmachela (Park et al., Reference Park, Kihm, Woo, Park, Lee, Smith, Harper, Young, Nielsen and Vinther2018) and more bulbous in Pambdelurion (Fleming et al., Reference Fleming, Kristensen, Sørensen, Park and Arakawa2018). These eyes are evidenced by paired and consistently shaped reflective patches on the undersides of the head region, just posterior to the bases of the frontal appendages (in Pambdelurion, they flank the large ventral mouth on either side), making the argument that the lack of eyes is shared between Parvibellus and the traditionally defined gilled lobopodians unconvincing. This also excludes Parvibellus from aligning with the opabiniids Opabinia and Utaurora, while the paired and unfused frontal appendages exclude it from the possibly eyeless taxa recently described from the Castle Bank fauna of Wales (Pates et al., Reference Pates, Wolfe, Lerosey-Aubril, Daley and Ortega-Hernández2022b). The comparison between the appendages of Parvibellus and the dorsal flaps of opabiniids and gilled lobopodians is also in opposition with the emerging view that the dorsal flaps of Pambdelurion and Opabinia were simple extrusions of the body wall lacking muscular control and that the flaps of the kerygmachelids evolved swimming flaps independently.

Not discussed by the authors, or included within the phylogenetic analysis and matrix accompanying the description, is the possibility that the specimen represents one of the slightly more basal siberiid lobopodians, more closely related to the gilled lobopodians and radiodonts than to the total-group onychophoran lobopodians such as Hallucigenia Conway Morris, Reference Conway Morris1977 or Microdictyon Bengston et al., 1986 (Smith and Ortega-Hernández, Reference Smith and Ortega-Hernández2014). Siberiids are very uncommon among lobopodians but easily identified by their broad, mostly uniform trunk regions, paired lobopodous limbs projecting ventrolaterally, absence of any claws on the trunk limbs, large raptorial frontal appendages, ventrally projecting mouth bearing a circumoral ring of triangular sclerites, and lack of eyes. This is in addition to the differences in preservation between Burgess Shale fossils and other Chengjiang fossils, which make some direct comparisons between Parvibellus and fossils of Opabinia problematic. Whereas in Opabinia the flaps lie on different bedding planes, with individual flaps marked by small and sudden changes in elevation (Whittington, Reference Whittington1975), the fossil of Parvibellus is preserved on a single bedding plane. In Parvibellus, dark outlines trace the shapes of the appendages and, although they may have been slightly warped taphonomically, show that the overlapping of the appendages, and overall shape and flexibility, are much more in line with the interpretation of these appendages as siberiid-like lobopodous walking legs rather than flattened, reverse-imbricated swimming flaps. The appendages of Parvibellus are elongate and highly flexible, preserved orientated at inconsistent angles; they mostly overlap each other by the curling and compression of appendages over-top of one another, not overlapping at their bases as is observed in gilled lobopodians and most radiodont taxa.

Parvibellus differs from the siberiids in a few notable ways, however. The lobopods of the siberiids bear repeated elongate papillae lining the posterior margin of the trunk appendages (Dzik, Reference Dzik2011), which perhaps served a respiratory function to support a more active, predatory lifestyle more comparable to the gill-bearing opabiniids and radiodonts, while Parvibellus lacks any such structures. The largest of the siberiids, Jianshanopodia, capable of reaching over 30 cm long judging from comparisons of ELI−J0005A to complete specimens of Jianshanopodia and Megadictyon, has elongate, tree-like papillae projecting from the posterior margins of its lobopods (Liu et al., Reference Liu, Shu, Han, Zhang and Zhang2006; Dzik, Reference Dzik2011). These additional branches to the main structure could have greatly increased the surface area if these papillae served a respiratory function, similar to the convoluted surface of the respiratory setal blades in Aegirocassis. Regarding the digestive tract observed in Parvibellus, it appears to lack any kind of diverticula structures, in contrast to the well-developed digestive tracts of other Chengjiang siberiids (Vannier et al., Reference Vannier, Liu, Lerosey-Aubril, Vinther and Daley2014) (although gut glands may be absent in Siberion). Finally, the frontal appendages of Parvibellus are small and undeveloped, while the frontal appendages of known siberiids are robust and bear raptorial endites or even claws at their tips (Vannier et al., Reference Vannier, Liu, Lerosey-Aubril, Vinther and Daley2014). The lack of these features in Parvibellus could, however, be explained by ontogenetic changes. The smallest known siberiid, Siberion lenaicus Dzik, Reference Dzik2011, is thought to have reached a maximum length of approximately 50–60 mm, judging from the more complete of the two known specimens (Dzik, Reference Dzik2011), while the sole specimen of Parvibellus measures only just over 5 mm, ~10 times smaller than Siberion. The diminutive size of the specimen would not immediately demand the growth of respiratory papillae as the existing surface area of the body would satisfy oxygen requirements. Restricting comparisons to only the Chengjiang Fauna, from which Parvibellus and the majority of siberiid species derive, possible adult forms become much larger, suggesting that Parvibellus could be a very early instar. The size and probably early developmental stage of the specimen could also explain the lack of any raptorial adaptations to the frontal appendages as individuals at this stage must have depended on a very different food source or prey than their large adult counterparts. The posteriormost portion of the specimen is poorly preserved, and a large area of it is missing. What is interpreted as a presumably paired furca-like structure may be interpreted as a reduced limb or part of a caudal fan, as observed in Jianshanopodia (Liu et al., Reference Liu, Shu, Han, Zhang and Zhang2006), or it may represent part of a medial lobe-like structure as seen in both Jianshanopodia and Siberion (Dzik, Reference Dzik2011). The interpretation of this structure as one of two paired furcae may also be correct. Because it probably represents a larval individual of an existing genus or species of siberiid lobopodian, and otherwise cannot be identified conclusively due to its probable immaturity, Parvibellus is here considered a nomen dubium and has not been included in the present phylogenetic analysis.

Phylogenetic relationships

The tree topology (Fig. 5) recovered by analysis of the modified matrix is broadly similar to previously recovered topologies from other studies on radiodont systematics. The trees were rooted with Aysheaia, a consistently basal panarthropod (Howard et al., Reference Howard, Hou, Edgecombe, Salge, Shi and Ma2020). The most-basal clade of total-group Euarthropoda, the Siberiidae (Dzik, Reference Dzik2011), contains Jianshanopodia Liu et al., Reference Liu, Shu, Han, Zhang and Zhang2006, Siberion Dzik, Reference Dzik2011, and Megadictyon Luo and Hu in Luo et al., Reference Luo, Hu, Chen, Zhang and Tao1999. Megadictyon is more poorly understood than the former two genera, with the type species initially known only from a section of the trunk bearing large, robust limbs and diverticulae, missing both the anterior and posterior sections of the body. Because of this ambiguity in the holotype, all subsequent, more-complete specimens have been attributed only tentatively to the genus, under Megadictyon cf. M. haikouensis (Liu et al., Reference Liu, Shu, Han, Zhang and Zhang2007). There are several more indeterminate siberiid lobopodian fossils from the Chengjiang Fauna (Vannier et al., Reference Vannier, Liu, Lerosey-Aubril, Vinther and Daley2014), but these were not included in the study. A new clade of three taxa, including Utahnax vannieri, Kerygmachela kierkegaardi, and Mobulavermis adustus n. gen. n. sp., is recovered in all trees under both equal weighting and implied weighting. In past studies, the informal name gilled lobopodians was used to join Kerygmachela and Pambdelurion. No formal name was established to unite the two genera, however, as the two genera formed a grade basal to the opabiniids, radiodonts, and arthropods rather than a distinct clade of closely related animals. The descriptions of Utahnax vannieri and of Mobulavermis adustus (Fig. 6) allow a more confident separation of Pambdelurion whittingtoni (and by extension, Omnidens amplus, which clades with Pambdelurion) from Kerygmachela and the establishment of a new formal clade between Siberiidae and the Opabiniidae (a monophyletic clade of Opabinia regalis and Utaurora comosa is present in all recovered trees, while the inclusion of the Castle Bank taxa is uncertain).

Figure 5. Phylogenetic results. (1) Majority-rule (50%) consensus of 299 most parsimonious trees under equal weighting (CI = 0.518, RI = 0.820), with newly named taxa highlighted and representative taxa bolded. Numbers beneath branches represent the percentage of trees in which that node was recovered, while branches without percentages are present in all trees. (2) Simplified trunk body plans of representative lobopodian and radiodont taxa (showing arrangements of annulation, setal blades, and limbs), in same order as bolded names. Models are shown facing away and to the right.

Figure 6. Digital life reconstruction of Mobulavermis adustus, shown swimming in a Cambrian ocean alongside small bivalved arthropods and early chordates (speculative anterior morphology based on Kerygmachela kierkegaardi).

Deuteropoda is recovered as sister to Radiodonta and is rooted in a polytomy of the recently described Erratus sperare Fu et al., Reference Fu, Legg, Daley, Budd, Wu and Zhang2022 and (under equal weighting) the much earlier discovered Cucumericrus decoratus Hou et al., Reference Hou, Bergström and Ahlberg1995. Both possess elongate unsclerotized trunk regions (save for the single large tergite that covers the head and much of the body in Erratus; a similar tergite is assumed to be present in Cucumericrus by phylogenetic bracketing but is not known from direct fossil evidence), with biramous appendages consisting of a lobopodous or distally sclerotized (Simonetta, Reference Simonetta2004) walking limb and a soft dorsolateral flap. They are followed by the Isoxyidae and then by the euarthropods, including Kylinxia zhangi Zeng et al., Reference Zeng, Zhao, Niu, Zhu and Huang2020 (Izquierdo-López and Caron, Reference Izquierdo-López and Caron2022). A probable group of “paranomalocaridids”, composed of Paranomalocaris and a recently figured undescribed species from the Kinzers Formation, were excluded from the matrix due to a relative absence of relevant applicable characters and the lack of any known remains besides the frontal appendages. The paranomalocaridids were similarly excluded from the analysis by Zeng et al. (Reference Zeng, Zhao and Zhu2023) with the additional reason of their radiodont affinities being questionable overall. Caryosyntrips Daley and Budd, Reference Daley and Budd2010, typically classed as a basal radiodont, is here recovered as basal to both Radiodonta and Deuteropoda. Caryosyntrips is recovered in a similar position by Moysiuk and Caron (Reference Moysiuk and Caron2019) and found in a polytomy with Deuteropoda and Radiodonta by Lerosey-Aubril and Pates (Reference Lerosey-Aubril and Pates2018) and by Moysiuk and Caron (Reference Moysiuk and Caron2021). The analysis by Zeng et al. (Reference Zeng, Zhao and Zhu2023) found Caryosyntrips as within Euarthropoda, rather than sister to it, or within Radiodonta.

A monophyletic Peytoiidae is rooted under equal weighting at two recently discovered fossils from the Chengjiang Fauna (Wu et al., Reference Wu, Pates, Ma, Lin, Wu, Zhang and Fu2022) attributed to Peytoiidae, but which both possess posteriorly oriented pectinate auxiliary spines, in contrast to the forward-facing or mesially oriented pectinate endites of all other peytoiids. The family name Peytoiidae is employed rather than “Hurdiidae” because, as pointed out by Greenfield (Reference Greenfield2023), the family name Hurdiidae has yet to be properly established following ICZN standards, and the name Peytoiidae (Conway Morris and Robison, Reference Conway Morris and Robison1982) is, as the oldest and only available name for the clade, the correct name to use. The known members of the Tamisiocarididae all form a polytomy with the base of Peytoiidae. Notably, Houcaris saron Hou et al., Reference Hou, Bergström and Ahlberg1995, as well as “Ramskoeldia” consimilis Cong et al., Reference Cong, Edgecombe, Daley, Guo, Pates and Hou2018, which is here included under the genus Houcaris (see Supplementary Information), are not recovered as tamisiocaridids as recently described (Wu et al., Reference Wu, Fu, Ma, Lin, Sun and Zhang2021a) but consistently as members of Amplectobeluidae.

Two species tentatively attributed to Innovatiocaris? in the description of Innovatiocaris maotianshanensis Zeng et al., Reference Zeng, Zhao and Zhu2023 form a monophyletic group within lower Amplectobeluidae, distant from the type species in Anomalocarididae, indicating they probably belong to a distinct genus. They are similar to the type species in their lack of posteriorly oriented auxiliary spines but easily differentiated by the outward kink separating the shaft and distal articulated regions, the hypertrophied first distal articulated zone endite pair, and the highly reduced or absent shaft endites in Innovatiocaris? multispiniformis Zeng et al., Reference Zeng, Zhao and Zhu2023 and Innovatiocaris sp., all distinctive traits of amplectobeluids. This morphological disparity warrants the establishment of a new genus, but this is outside the scope of the current study. Laminacaris Guo et al., Reference Guo, Pates, Cong, Daley, Edgecombe, Chen and Hou2019 is recovered as a basal amplectobeluid alongside Guanshancaris kunmingensis Wang et al., Reference Wang, Huang and Hu2013, alongside “Anomalocaris” sp. from the Balang Formation (Liu, Reference Liu2013), although the placement of “Anomalocaris” sp. should be viewed with caution until more complete material is described.

Acknowledgments

I thank N. Lopez Carranza from the Biodiversity Institute, University of Kansas, for providing new photos of KUMIP specimens for study and for assistance with the collections, and M.L. Nielsen and the staff of the Natural History Museum of Denmark, University of Copenhagen's Invertebrate Paleontology and Paleobotany division, for providing new photos of Kerygmachela kierkegaardi. I thank B. Lieberman, Z. Zhang, and one anonymous reviewer for their constructive critique. I thank J.M. Wolfe for valuable discussion on the morphology and lobopods of Opabinia regalis.

Declaration of competing interests

The author declares no competing interest.

Data availability statement

The morphological matrix used for the phylogenetic analyses performed for this study, as well as an explanatory document detailing the matrix with notes on the coding of certain taxa, are available from MorphoBank (www.morphobank.org) doi:10.7934/P4884, at the permalink: https://morphobank.org/permalink/?P4884.

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Figure 1. Mobulavermis adustus KUMIP 298510 (holotype) from the Pioche Shale, middle Cambrian, Nevada: (1) KUMIP 298510a (part), immersed, showing curving body and caudal spine preserved in negative relief; (2) KUMIP 298510b (counterpart), immersed, with caudal spine in strong positive relief; (3) KUMIP 298510b (counterpart), dry, closeup of caudal spine in positive relief and some reduced terminal flaps; (4) KUMIP 298510a (part), immersed, closeup of trunk interior, showing digestive tract, possible gut gland, and possible evidence of strong trunk annulation; (5) KUMIP 298510b (counterpart), dry, closeup of flap surfaces near anterior of specimen. Scale bars = 10 mm. afm = anterior flap margin; an = annulations; bw = body wall; cs = caudal spine; dt = digestive tract; fo = flap ornamentation; mg = midgut gland; pfm = posterior flap margin; tf = terminal reduced flaps.

Figure 2. Mobulavermis adustus KUMIP 298510 (holotype) from the Pioche Shale, middle Cambrian, Nevada: (1) KUMIP 298510a (part), dry; (2) interpretative drawing of Mobulavermis adustus KUMIP 298510. Scale bars = 10 mm. Abbreviations as in Figure 1.

Figure 3. Mobulavermis adustus KUMIP 298511 (paratype) and indeterminate euarthropod KUMIP 293606 from the Pioche Shale, middle Cambrian, Nevada: (1) Mobulavermis adustus KUMIP 298511a (part), immersed, showing extent and outline of flaps in the posterior and middle of the body; (2) Mobulavermis adustus KUMIP 298511b (counterpart), immersed; (3) Mobulavermis adustus KUMIP 298511a (part), dry, colors inverted for clarity, with white arrows indicating approximate topographic changes between distinct lateral flaps; (4) Mobulavermis adustus KUMIP 298511b (counterpart), immersed, closeup of caudal spine and terminal reduced flaps; (5) Pioche euarthropod KUMIP 293606, normal color, dry; (6) interpretative drawing of Mobulavermis adustus KUMIP 298511 (paratype). Scale bars = 10 mm. af = anterior flap; ans = anus; ct = expanded caudal tergite; ey = eye; pl = pleura of tergite; pm = proximal margin of pleural region; ofm = outer flap margin; tc = trunk cuticle; other abbreviations as in Figure 1.

Figure 4. Comparison between Mobulavermis adustus and other lobopodian taxa: (1) Mobulavermis adustus KUMIP 298510a (holotype, part), dry, showing steep changes in elevation between successive flaps; (2) Hurdia sp. KUMIP 314057a (part) from the Spence Shale (Cambrian, Utah, USA), immersed, showing the construction of the peytoiid lateral flap as composed of numerous tightly spaced strengthening rays running the total length of the flap (note the overlapping, angled strengthening rays in the posterior of the flap); (3) Kerygmachela kierkegaardi MGUH 22.083 (holotype) from the Sirius Passet (Cambrian, Greenland); (4) Kerygmachela kierkegaardi MGUH 22.083 (holotype) from the Sirius Passet (Cambrian, Greenland), showing detail of flap wrinkles and limb-like structures; (5) Kerygmachela kierkegaardi MGUH 22.083 (holotype) from the Sirius Passet (Cambrian, Greenland), showing detail of head region; (6) Kerygmachela kierkegaardi MGUH 22.085 (paratype) from the Sirius Passet (Cambrian, Greenland); (7) Kerygmachela kierkegaardi MGUH 22.085 (paratype) from the Sirius Passet (Cambrian, Greenland), showing detail of caudal region; (8) Parvibellus avatus ELI-EJ 048A (holotype, part) from the Chengjiang Biota, Chiungchussu Formation (Cambrian, Yunnan, China) (9) Anomalocaris magnabasis KUMIP 293605 frontal appendage, immersed, from the Combined Metals Member, showing a deep red coloring, owing to heavy hematite concentration; (10) Anomalocaris magnabasis KUMIP 307022 frontal appendage, immersed, from the Comet Shale Member, which is not associated with hematitic preservation, showing a desaturated blueish hue. Photographs of Kerygmachela were provided by M. L. Nielsen on behalf of the Natural History Museum of Denmark. The photograph of Parvibellus is adapted from Liu et al. (2022), under CC BY 4.0. Scale bars = 10 mm. en = endite; fa = frontal appendage; fm = flap musculature; lo = lobopodous limbs; oc = oral cone; pfm = proximal flap margin; phr = pharynx; psr = posterior strengthening ray; sr = strengthening ray; tf = tail fan; tn = trunk dorsal node; wr = wrinkled surface of flap. Other abbreviations as in Figures 1 and 3.

Figure 6. Digital life reconstruction of Mobulavermis adustus, shown swimming in a Cambrian ocean alongside small bivalved arthropods and early chordates (speculative anterior morphology based on Kerygmachela kierkegaardi).

Article contents

A large pelagic lobopodian from the Cambrian Pioche Shale of Nevada

Abstract

Non-technical Summary

Introduction

Geological setting

Materials and methods

Phylogenetic methods

Repositories and institutional abbreviations

Systematic paleontology

Superphylum Panarthropoda Nielsen, Reference Nielsen1995Family Kerygmachelidae new family

Type genus

Other taxa included

Diagnosis

Remarks

Genus Mobulavermis new genus

Type species

Diagnosis

Etymology

Remarks

Mobulavermis adustus new species Figures 1, 2, 3.1–3.4, 3.6, 4

Type specimens

Diagnosis

Occurrence

Description

Etymology

Remarks

Phylum Euarthropoda Lankester, Reference Lankester1904Class, Order, and Family uncertainPioche euarthropod KUMIP 293606Figure 3.5

Occurrence

Description

Material

Remarks

Discussion

Comparisons with other flap-bearing panarthropods

Alternative interpretation of Parvibellus

Phylogenetic relationships

Acknowledgments

Declaration of competing interests

Data availability statement

References

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Superphylum Panarthropoda Nielsen, Reference Nielsen1995
Family Kerygmachelidae new family

Mobulavermis adustus new species
Figures 1, 2, 3.1–3.4, 3.6, 4

Phylum Euarthropoda Lankester, Reference Lankester1904
Class, Order, and Family uncertain
Pioche euarthropod KUMIP 293606
Figure 3.5