arising from C.D. Whalen & N.H. Landman. Nature Communications https://doi.org/10.1038/s41467-022-28333-5 (2022)
Recently, on the basis of a single specimen (ROMIP 64897) from the Royal Ontario Museum (Canada), Whalen and Landman1 described the new coleoid taxon with a fairly completely preserved frontal part as Syllipsimopodi bideni. The specimen, recovered from the Bear Gulch Limestone, Heath Formation in Fergus County, Montana, USA, is of Serpukhovian age2. Based on the suggested presence of a gladius, ten arms, and fins, as well as the supposed absence of a phragmocone, the authors interpreted the “remarkably well-preserved” specimen as “the oldest definitive vampyropod and crown coleoid”1. We herein test if the fidelity of preserved characters in S. bideni affects the interpretation of this organism—particularly by comparing these characters to other soft bodied cephalopod fossils from Bear Gulch. We provide evidence for the likely synonymy of S. bideni and Gordoniconus beargulchensis. Our interpretation casts doubt on the phylogeny proposed by Whalen and Landman1, who suggested S. bideni as the oldest vamyropod. Vampyropoda ( = Octobrachia or Octopodiformes) is considered to be the sister group of all ten-armed cephalopods (Decabrachia)3,4,5, which is also supported by recent molecular analyses6,7,8.
The holotypes of the early coleoids Gordoniconus beargulchensis9 and Syllipsimopodi bideni share many important morphological characters. They are both of the same age and come from the same locality. In our Fig. 1, we show the photographs of both holotypes (Fig. 1a, e) and line drawings made after these published images (Fig. 1b, d) at the same scale. In Fig. 1c, we overlaid the line drawings of both holotypes with the drawing of G. beargulchensis being scaled down by 20% to fit the body chamber width to each other. This overlay demonstrates that the morphology and proportions of the preserved parts of the two holotypes are so similar that we consider S. bideni may be a subjective junior synonym of G. beargulchensis. Importantly, the distinctly tapering body in S. bideni with straight margins is identical with the body-chamber portion of G. beargulchensis. The few differences can be explained by taphonomic alteration, such as the median ridge in S. bideni being the result of compactional fracturing of the mineralised body chamber. The absence of the chambered phragmocone is due to oblique splitting of the rock and without the missing counterpart it is impossible to state definitively that this character is truly absent. Accordingly, the extension of the phylogenetic split of the Decabrachia and Octobrachia (‘Vampyropoda’1) into the Early Carboniferous is not supported. Instead, we think that the phylogenies presented earlier3,4,5 as well as recent molecular analyses6,7,8 support a timing of this divergence during the Middle Permian to Early Triassic. The latter theory is based on palaeontological and neontological morphological data, as well as on molecular data derived from modern coleoids; it has been tested repeatedly and found support from several independent lines of reasoning. Furthermore, the supposed Carboniferous octobrachian Pohlsepia10,11,12,13,14 is a highly doubtful taxon -as stated by Whalen and Landman1- and should, therefore, not be used to support the phylogenetic split of the Decabrachia and Octobrachia (‘Vampyropoda’1) during the Early Carboniferous.
We suggest that the specimen described as Syllipsimopodi bideni is synonymous with Gordoniconus beargulchensis. They have the same geographic and stratigraphic origin. They share their absolute size (body chamber width differs by 20%, possibly representing slightly different ontogenetic stages or different degrees of compaction), the conch shape (orthoconic conch with an acute apical angle of less than 13°, and a rostrum with an apical angle of ca. 10°), the body chamber shape (width to length ratio, angle of the sides/apical angle, slight terminal apertural constriction), the shallow ventral hyponomic sinus, the broadly rounded dorsal projection, and the narrow mid-ventral siphuncle (interpreted as fin support by1). The phragmocone, fragmentarily preserved in the specimen described in1, is only slightly longer than the body chamber and has closely spaced, simply dome-shaped septa. The head of both specimens carries an arm-crown with ten moderately strong and rather short arms of similar length, possibly with small circular suckers1, probably in double rows per arm. Tentacles are absent. The oesophagus extends about 30 to 50% of the body chamber length. An ink sac is unknown; the position and proportions of the buccal mass and beak remains, the length and shape of the oesophagus (interpreted as ink sac by1) and the overall mode of preservation are nearly identical.
The holotypes of G. beargulchensis and S. bideni are preserved with slightly darker colour of the arm crown, present as a very shallow imprint (due to being entirely soft bodied), the completely demineralized hard parts, the orientation and approximate number of fractures in the shell of the body chamber (including those running parallel to the plain of symmetry), and the phosphatic remains on the phragmocone (supplementary figs. 1–3 in refs. 15,16; “presumed connective tissues” sensu supplementary figs. 4, 7 in ref. 1). The longitudinal structure along the midline in S. bideni is similarly preserved in some specimens of G. beargulchensis (supplementary fig. 1 in ref. 9) and is here interpreted as a median crack formed by compaction. These factors lead us to consider the hypothesis as the most parsimonious that the new specimen1 was identified incorrectly as a new taxon, because of the largely missing phragmocone and rostrum; however, it is likely that these parts were lost, probably during extraction (attached to the counterslab?). Further, there is a possibility that these body parts are absent due to taphonomic reasons; dissolution of the aragonitic phragmocone might seem odd but has been documented for ammonoids while organic remains are preferentially preserved in the same specimens from the same locality. Whalen and Landman1 also argued that two of the arms might be elongated in their specimen but could not exclude this was a taphonomic artefact; moreover, they did not provide any direct evidence for the hypotheses that these are indeed parts of the animal. They did not find support for other differences between the elongated and shorter arms so either these structures are random folds in the sediment (no evidence for organic remains) or a taphonomic imprint (such as, e.g., a landing mark10). It is important to note that the currently oldest fossil evidence for forms with specialised arms derives from the Toarcian stage of the Lower Jurassic17.
Another issue with the interpretation of S. bideni is that Whalen & Landman1 did not explain the peculiar position of what they interpreted as “terminal fin support”. The presence of unpaired fin cartilages enveloping the gladius apex (as suggested by these authors) is unknown in octobrachians. All Mesozoic gladius-bearing octobrachians as well as extant Vampyroteuthis are characterized by paired fin cartilages, which are located on both sides of the median field. An apical position behind the conus is only known from few modern squids, namely highly adapted fast swimmers of the decabrachian order Oegopsida. The assumption of an apical unpaired fin cartilage is at odds with our current knowledge about the evolution of fin cartilage and also cephalopod locomotion15.
There are several outstanding issues indicating that S.bideni is a subjective junior synonym of Gordoniconus beargulchensis. Accordingly, we doubt that the morphological characters present in this fossil are sufficient evidence to accurately upend the well-established phylogenetic hypothesis placing the divergence of Octobrachia and Decabrachia between the Middle Permian and the Late Triassic, as it is also corroborated by molecular clock studies3,6. We highlight the need to exert caution when analysing soft bodied fossils as taphonomic factors may result in anatomical variation due to decay and timing of preservation. There is a danger of misinterpreting fragmentary, singular specimens lacking a counterpart without proper comparative anatomical and taphonomic analyses.
Methods
We compared the holotypes of the two coleoids by tracing visible structures in published photos. First, we gently enhanced the contrast using the raster graphics editor Adobe PhotoShop CS6. We saved the photos as single-layer tif-files and imported them into the vector graphic software CorelDraw X8. There, we traced all visible structures independent of their meaning. Subsequently, we homologized those structures displaying sufficient detail. Finally, we overlaid those drawings by adapting their scales to each other to demonstrate the great degree of morphological similarity.
Reporting summary
Further information on research design is available in the Nature Portfolio Reporting Summary linked to this article.
References
Whalen, C. D. & Landman, N. H. Fossil coleoid cephalopod from the Mississippian Bear Gulch Lagerstätte sheds light on early vampyropod evolution. Nat. Commun. 13, 1107 (2022).
Grogan, E. D. & Lund, R. The geological and biological environment of the Bear Gulch Limestone (Mississippian of Montana, USA) and a model for its deposition. Geodiversitas 24, 295–315 (2002).
Kröger, B., Vinther, J. & Fuchs, D. Cephalopod origin and evolution: a congruent picture emerging from fossils, development and molecules. BioEssays 33, 602–613 (2011).
Clements, T., Colleary, C., De Baets, K. & Vinther, J. Buoyancy mechanisms limit preservation of coleoid cephalopod soft tissues in Mesozoic lagerstätten. Palaeontology 60, 1–14 (2016).
Fuchs, D. Homology problems in cephalopod morphology: deceptive (dis)similarities between different types of “caecum”. Swiss J. Palaeontol. 138, 49–63 (2019).
Tanner, A. R. et al. Molecular clocks indicate turnover and diversification of modern coleoid cephalopods during the Mesozoic Marine Revolution. Proc. R. Soc. B 284, 20162818 (2017).
Uribe, J. E. & Zardoya, R. Revisiting the phylogeny of Cephalopoda using complete mitochondrial genomes. J. Mollusca. Stud. 83, 133–144 (2017).
López-Córdova, D. A. et al. Mesozoic origin of coleoid cephalopods and their abrupt shifts of diversification patterns. Mol. Phylogenetics Evolution 166, 107331 (2022). 1-10.
Klug, C. et al. Anatomy of the first Coleoidea and character evolution in the Carboniferous. Commun. Biol. 2, 280, https://doi.org/10.1038/s42003-019-0523-2 (2019). 1–12.
Kluessendorf, J. & Doyle, P. Pohlsepia mazonensis, an early “octopus” from the Carboniferous of Illinois, USA. Palaeontology 43, 919–926 (2000).
Bather, F. A. Shell-growth in Cephalopoda (Siphonopoda). J. Nat. Hist. 1, 298–309 (1888).
Doguzhaeva L. A., Mapes, R. H., & Mutvei, H. A late Carboniferous coleoid cephalopod from the Mazon Creek (USA), with a radula, arm hooks, mantle tissue, and ink. In Landman, N. H., Davis, R. A., & Mapes, R., H. (eds.), Sixth International Symposium, Cephalopods – Present and Past. 121-143. Springer, Dordrecht (2007).
Mapes, R. H., Weller, E. A. & Doguzhaeva, L. A. Early Carboniferous (Late Namurian) coleoid cephalopods showing a tentacle with arm hooks and an ink sac from Montana, USA. In Tanabe, K., Shigeta, Y., Sasaki, T. & Hirano, H. (eds.), Cephalopods—Present and Past. 155‒170. Tokai University Press, Kanagawa (2010).
Landman, N. L. & Davis, R. A. Jaw and crop preserved in an orthoconic nautiloid cephalopod from the Bear Gulch Limestone (Mississippian, Montana). N. Mex. Bur. Mines Miner. Resour. 44, 103–107 (1988).
Fuchs, D., Iba, Y., Tischlinger, H., Keupp, H. & Klug, C. The locomotion system of Mesozoic Coleoidea (Cephalopoda) and its phylogenetic significance. Lethaia 49, 433–454 (2016).
Fuchs, D. Part M, Coleoidea, Chapter 23A: systematic descriptions: hematitida & donovaniconida. Treatise Online 154, 1–12 (2021).
Klug, C., Schweigert, G., De Baets, K. & Fuchs, D. Distraction sinking and fossilized coleoid predatory behaviour from the German Early Jurassic. Swiss J. Palaeontol. 140, 1–12 (2021).
Acknowledgements
CK was supported by the Swiss National Science Foundation (grant nr. 200021_169627), KDB by I.3.4 Action of the Excellence Initiative - Research University Programme at the University of Warsaw and MK by the Czech Science Foundation GACR 21-30418J, and TC by a Leverhulme Early career Fellowship (ECF-2019-097).
Author information
Authors and Affiliations
Contributions
C.K., D.F., R.H., K.S. and J.V. independently concluded that these cephalopod taxa are synonymous. All authors contributed to analysis and interpretation of preservation. All authors agree that the holotype of S. bideni is incomplete. C.K. made the figure. C.K., K.S., R.H., M.Z., T.C., M.K., R.W., K.D., J.L., J.V., and D.K. wrote parts of the text, proofread various versions of the text and approved of it.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing interests.
Peer review
Peer review information
Nature Communications thanks Catalina Perales-Raya and the other, anonymous, reviewer(s) for their contribution to the peer review of this work.
Additional information
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary information
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Klug, C., Stevens, K., Hoffmann, R. et al. Revisiting the identification of Syllipsimopodi bideni and timing of the decabrachian-octobrachian divergence. Nat Commun 14, 8094 (2023). https://doi.org/10.1038/s41467-023-42842-x
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41467-023-42842-x
This article is cited by
Comments
By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.