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Dickinsonia: mobile and adhered

Published online by Cambridge University Press:  12 April 2021

Andrey Ivantsov*
Affiliation:
Borissiak Paleontological Institute, Russian Academy of Sciences, Moscow117997, Russia
Maria Zakrevskaya
Affiliation:
Borissiak Paleontological Institute, Russian Academy of Sciences, Moscow117997, Russia
*
Author for correspondence: Andrey Ivantsov, Email: ivancov@paleo.ru

Abstract

The classical genus of Ediacaran macroorganisms, Dickinsonia, was part of an extensive benthic marine community inhabiting the fields of microbial mats. The remains of Dickinsonia are commonly preserved in the position of adhesion to the habitat substrate. However, these were mobile organisms. In addition to the already known feeding traces of Dickinsonia, structures described as traces of motor activity are reported. Long parallel furrows, extending from the posterior end of the body imprint, are interpreted as imprints of ridges left by an organism moving along the surface of the substrate. Groups of differently shaped grooves laying in the depression that enhalo the Dickinsonia body imprints or accompany their individual areas are interpreted as imprints of ridges and cords of mucous material. They are considered to represent structures of self-determined stretching and lift-off of the body margins from the substrate. The rings and arcs of silt- and sand-sized mineral particles bordering the body imprints are composed of material that was supposedly brushed off from the surface of the microbial mat by Dickinsonia. They are considered traces of the adhesion of these organisms to the substrate. Accumulations of multidirectional pulling and tear-off structures, lacking the body imprint but accompanied by the joint plane passing into the overlying sediment and cutting through the bedding, are interpreted as escape traces. The dual modality of the behaviour (attachment and mobility) could indicate the adaptability of Dickinsonia to life in extremely shallow-water environments.

Type
Original Article
Copyright
© The Author(s), 2021. Published by Cambridge University Press

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References

Bobkov, NI, Kolesnikov, AV, Maslov, AV and Grazhdankin, DV (2019) The occurrence of Dickinsonia in non-marine facies. Estudios Geológicos 75, e096.CrossRefGoogle Scholar
Bobrovskiy, I, Hope, JM, Ivantsov, AY, Nettersheim, BJ, Hallman, C and Brocks, JJ (2018) Ancient steroids establish the Ediacaran fossil Dickinsonia as one of the earliest animals. Science 361, 1246–49.CrossRefGoogle ScholarPubMed
Bobrovskiy, I, Krasnova, A, Ivantsov, AY, Luzhnaya (Serezhnikova), EA and Brocks, JJ (2019) Simple sediment rheology explains the Ediacara biota preservation. Nature Ecology & Evolution 3, 582–9.CrossRefGoogle ScholarPubMed
Bottjer, DJ and Clapham, ME (2006) Evolutionary paleoecology of Ediacaran benthic marine organisms. In Neoproterozoic Geobiology and Paleobiology (eds Xiao, S and Kaufman, AJ), pp. 91114. Netherlands: Kluwer Press.CrossRefGoogle Scholar
Brasier, MD and Antcliffe, JB (2008) Dickinsonia from Ediacara: a new look at morphology and body construction. Palaeogeography, Palaeoclimatology, Palaeoecology 270, 311–23.CrossRefGoogle Scholar
Callow, RH and Brasier, MD (2009) Remarkable preservation of microbial mats in Neoproterozoic siliciclastic settings: implications for Ediacaran taphonomic models. Earth Science Reviews 96, 207–19.CrossRefGoogle Scholar
Callow, RH, Brasier, MD and McIlroy, D (2013) Discussion: ‘Were the Ediacaran siliciclastics of South Australia coastal or deep marine?’ by Retallack et al., Sedimentology 59, 1208–36. Sedimentology 60, 624–7.Google Scholar
Conway Morris, S (1989) Early metazoans. Science Progress 3, 8199.Google Scholar
Davies, MS and Case, CM (1997) Tenacity of attachment in two species of littorinid, Littorina littorea (L.) and Littorina obtusata (L.). Journal of Molluscan Studies 63, 235–44.CrossRefGoogle Scholar
Droser, ML and Gehling, JG (2015) The advent of animals: the view from the Ediacaran. Proceedings of the National Academy of Sciences 112, 4865–70.CrossRefGoogle ScholarPubMed
Droser, ML, Gehling, JG and Jensen, SR (2006) Assemblage palaeoecology of the Ediacara biota: the unabridged edition. Palaeogeography, Palaeoclimatology, Palaeoecology 232, 131–47.CrossRefGoogle Scholar
Droser, ML, Tarhan, LG, Evans, SD, Surprenant, RL and Gehling, JG (2020) Biostratinomy of the Ediacara Member (Rawnsley Quartzite, South Australia): implications for depositional environments, ecology and biology of Ediacara organisms. Interface Focus 10, 20190100.CrossRefGoogle ScholarPubMed
Droser, ML, Tarhan, LG and Gehling, JG (2017) The rise of animals in a changing environment: global ecological innovation in the Late Ediacaran. Annual Review of Earth and Planetary Sciences 45, 593617.CrossRefGoogle Scholar
Dunn, FS, Liu, AG and Donoghue, PCJ (2018) Ediacaran developmental biology. Biological Reviews 93, 914–32.CrossRefGoogle ScholarPubMed
Dzik, J (2000) The origin of the mineral skeleton in chordates. Journal of Evolutionary Biology 31, 105–54.CrossRefGoogle Scholar
Dzik, J and Ivantsov, AY (2002) Internal anatomy of a new Precambrian dickinsoniid dipleurozoan from northern Russia. Neues Jahrbuch für Geologie und Paläontologie 7, 385–96.CrossRefGoogle Scholar
Evans, SD, Droser, ML and Gehling, JG (2015) Dickinsonia lift-off: evidence of current derived morphologies. Palaeogeography, Palaeoclimatology, Palaeoecology 434, 2833.CrossRefGoogle Scholar
Evans, SD, Droser, ML and Gehling, JG (2017) Highly regulated growth and development of the Ediacara macrofossil Dickinsonia costata . Plos One 12, 115.CrossRefGoogle ScholarPubMed
Evans, SD, Gehling, JG and Droser, ML (2019a) Slime travelers: early evidence of animal mobility and feeding in an organic mat world. Geobiology 17, 490509.CrossRefGoogle Scholar
Evans, SD, Huang, W, Gehling, JG, Kisailus, D and Droser, ML (2019b) Stretched, mangled, and torn: responses of the Ediacaran fossil Dickinsonia to variable forces. Geology 47, 1049–53.CrossRefGoogle Scholar
Fedonkin, MA (1981) White Sea Vendian biota. Proceedings of the Geological Institute of the Academy of Sciences of the USSR 342, Nauka, 100 pp [in Russian].Google Scholar
Fedonkin, MA (1983) Non-skeletal fauna of Podolian Dniester area. In The Vendian of Ukraine (eds Velikanov, VA, Aseeva, EA and Fedonkin, MA), pp. 128–39. Kiev: Naukova Dumka [in Russian].Google Scholar
Fedonkin, MA (1990) Systematic description of the Vendian Metazoa. In The Vendian System 1. Paleontology (eds Sokolov, BS and Iwanowski, A), pp. 71120. Berlin, Heidelberg: Springer-Verlag.Google Scholar
Fedonkin, MA (2002) Andiva ivantsovi gen. et sp. nov. and related carapace-bearing Ediacaran fossils from the Vendian of the Winter Coast, White Sea, Russia. Italian Journal of Zoology 69, 175–81.CrossRefGoogle Scholar
Fedonkin, MA, Ivantsov, AYu, Leonov, MV and Serezhnikova, EA (2007) Dynamics of evolution and biodiversity in Late Vendian: a view from the White Sea. In The Rise and Fall of the Vendian (Ediacaran) Biota. Origin of the Modern Biosphere: Transaction of the International Conference of the IGCP Project 493 (ed. Semikhatov, MA), pp. 6–9. Moscow, GEOS.Google Scholar
Gehling, JG (1991) The case for Ediacaran fossil roots to the metazoan tree. Memoir of the Geological Society of India 20, 181224.Google Scholar
Gehling, JG (1999) Microbial mats in terminal Proterozoic siliciclastics: Ediacaran death masks. Palaios 14, 4057.CrossRefGoogle Scholar
Gehling, JG and Droser, ML (2009) Textured organic surfaces associated with the Ediacara biota in South Australia. Earth Science Reviews 96, 196206.CrossRefGoogle Scholar
Gehling, JG, Droser, ML, Jensen, SR and Runnegar, BN (2005) Ediacara organisms: relating form to function. In Evolving Form and Function: Fossils and Development (ed. Briggs, D), pp. 4366. New Haven: Yale University Press.Google Scholar
Glaessner, MF (1959) The oldest fossil faunas in South Australia. Geologische Rundschau 47, 522–31.CrossRefGoogle Scholar
Glaessner, MF and Wade, M (1966) The Late Precambrian fossils from Ediacara, South Australia. Palaeontology 9, 599628.Google Scholar
Gold, DA, Runnegar, B, Gehling, JG and Jacobs, DK (2015) Ancestral state reconstruction of ontogeny supports a bilaterian affinity for Dickinsonia . Evolution & Development 17, 315–24.CrossRefGoogle ScholarPubMed
Grazhdankin, DV (2003) Structure and depositional environment of the Vendian Complex in the Southeastern White Sea area. Stratigraphy and Geological Correlation 11, 313–31.Google Scholar
Grazhdankin, DV (2004) Patterns of distribution in the Ediacaran biotas: facies versus biogeography and evolution. Paleobiology 30, 203–21.2.0.CO;2>CrossRefGoogle Scholar
Harrington, HJ and Moore, RC (1956) Medusa of the Hydroidea. In Treatise on Invertebrate Paleontology, Part F: Coelenterata (ed. Moore, RC), pp. 7780. Geological Society of America and University of Kansas Press.Google Scholar
Hoekzema, RS, Brasier, MD, Dunn, FS and Liu, AG (2017) Quantitative study of developmental biology confirms Dickinsonia as a metazoan. Proceedings of the Royal Society B: Biological Sciences 284, 19.Google ScholarPubMed
Ivantsov, AY (2001a) Traces of active moving of large Late Vendian Metazoa over the sediment surface. In Ecosystem Restructure and the Evolution of the Biosphere (eds Ponomarenko, AG, Rozanov, AY and Fedonkin, MA), pp. 119–20. Moscow, PIN RAS vol. 4 [in Russian].Google Scholar
Ivantsov, AY (2001b) Vendia and other Precambrian ‘arthropods’. Paleontological Journal 35, 335–43.Google Scholar
Ivantsov, AY (2008) Proarticulata—a phylum of Metazoan animals that became extinct in the Precambrian. In Evolutionary Morphology of Animals. A Contribution to the 100th Anniversary of the Birth of Academician AV Ivanov. Part I: Proceedings of the St. Petersburg Society of Naturalists, pp. 3242. St Petersburg: St Petersburg University series 1, volume 97 [in Russian].Google Scholar
Ivantsov, AY (2009) New reconstruction of Kimberella, problematic Vendian metazoan. Paleontological Journal 43, 601–11.CrossRefGoogle Scholar
Ivantsov, AY (2010) Paleontological evidence for the supposed Precambrian evolution of mollusks. Paleontological Journal 44, 1552–59.CrossRefGoogle Scholar
Ivantsov, AY (2011a) Feeding traces of Proarticulata – the Vendian Metazoa. Paleontological Journal 45, 237–48.CrossRefGoogle Scholar
Ivantsov, AY (2011b) The Zimnie Gory locality of imprints of Vendian Metazoa, a unique natural site of global importance. Geologist of Ukraine 3–4, 8998 [in Russian].Google Scholar
Ivantsov, AY (2012) Paleontological data on the possibility of Precambrian existence of mollusks. In Mollusks: Morphology, Behavior and Ecology (eds Fyodorov, A and Yakovlev, H), pp. 153–79. New York: Nova Science Publishers.Google Scholar
Ivantsov, AY (2013) Trace fossils of Precambrian metazoans ‘Vendobionta’ and ‘Mollusks’. Stratigraphy and Geological Correlation 21, 252–64.CrossRefGoogle Scholar
Ivantsov, AY and Fedonkin, MA (2001) Traces of active movement – final evidence for the animal nature of Ediacaran organisms. In Proceedings of the International Symposium ‘Evolution of Life on the Earth’. pp. 133–7. Tomsk: NTL [in Russian].Google Scholar
Ivantsov, AY, Fedonkin, MA, Nagovitsyn, AL and Zakrevskaya, MA (2019a) Cephalonega, a new generic name and the system of Vendian Proarticulata. Palaeontological Journal 53, 1134–46.CrossRefGoogle Scholar
Ivantsov, AY and Malakhovskaya, YE (2002) Giant traces of Vendian animals. Doklady Earth Sciences 385A, 618–22.Google Scholar
Ivantsov, AY, Nagovitsyn, AL and Zakrevskaya, MA (2019b) Traces of locomotion of Ediacaran macroorganisms. Geosciences 9, 111.CrossRefGoogle Scholar
Ivantsov, AY and Zakrevskaya, MA (2018) The phenomenon of exclusive preservation of Late Precambrian macrofossils. In Proceedings of the Paleontological Society, pp. 4653. Moscow, PIN RAS vol. 1 [in Russian].Google Scholar
Ivantsov, AY, Zakrevskaya, MA and Nagovitsyn, AL (2019c) Morphology of integuments of the Precambrian animals, Proarticulata. Invertebrate Zoology 16, 1926.CrossRefGoogle Scholar
Ivantsov, AY, Zakrevskaya, MA, Nagovitsyn, AL, Krasnova, A, Bobrovskiy, I and Luzhnaya (Serezhnikova), EA (2020) Intravital damage to the body of Dickinsonia (Metazoa of the late Ediacaran). Journal of Paleontology 94, 1019–33.CrossRefGoogle Scholar
Jenkins, RJF (1992) Functional and ecological aspects of Ediacaran assemblages. In Origin and Early Evolution of the Metazoa (eds Lipps, J and Signor, P), pp. 131–76. New York: Plenum Press.CrossRefGoogle Scholar
Keller, BM and Fedonkin, MA (1976) New organic fossil finds in the Precambrian Valday Series along the Syuzma River. Izvestiya Akademii Nauk SSSR, Seriya Geologicheskaya 3, 3844 [in Russian].Google Scholar
Krivosheev, VI and Polenov, YA (2001) Nonskeletal fauna of the Sylvitsa group from the Middle Urals. In Materials of the II-nd International symposium ‘Evolution of life on the Earth’, pp. 148–50. Tomsk: Izdat, Nauchno-technich [in Russian].Google Scholar
Laflamme, M, Schiffbauer, JD, Narbonne, GM and Briggs, DE (2011) Microbial biofilms and the preservation of the Ediacara biota. Lethaia 44, 203–13.CrossRefGoogle Scholar
Lücking, R and Nelsen, MP (2018) Transformative paleobotany. In Papers to commemorate the life and legacy of Thomas N. Taylor, pp. 551–90. San Diego, CA: Academic Press.Google Scholar
Mitchell, EG, Bobkov, N, Bykova, N, Dhungana, A, Kolesnikov, AV, Hogarth, IRP, Liu, AG, Mustill, TMR, Sozonov, N, Rogov, VI, Xiao, S and Grazhdankin, DV (2020) The influence of environmental setting on the community ecology of Ediacaran organisms. Interface Focus 10, 20190109.CrossRefGoogle ScholarPubMed
Narbonne, GM (2005) The Ediacara biota: neoproterozoic origin of animals and their ecosystems. Annual Review of Earth and Planetary Science 33, 421–42.CrossRefGoogle Scholar
Retallack, GJ (1994) Were the Ediacaran fossils lichens? Paleobiology 20, 523–44.CrossRefGoogle Scholar
Retallack, GJ (2007) Growth, decay and burial compaction of Dickinsonia, an iconic Ediacaran fossil. Alcheringa 31, 215–40.CrossRefGoogle Scholar
Retallack, GJ (2012) Criteria for distinguishing microbial mats and earths. In Microbial Mats in Siliciclastic Sediments (eds Noffke, N and Chafetz, H), pp. 136–52. Tulsa Oklahoma, Society of Economic Paleontologists and Mineralogists, Special Paper no. 101.Google Scholar
Retallack, GJ (2013) Ediacaran life on land. Nature 493, 8992.CrossRefGoogle ScholarPubMed
Retallack, GJ (2014) Precambrian life on land. The Palaeobotanist 63, 115.Google Scholar
Retallack, GJ and Broz, AP (2020) Arumberia and other Ediacaran-Cambrian fossils of central Australia. Historical Biology, published online 13 May 2020, https://doi.org/10.1080/08912963.2020.1755281.CrossRefGoogle Scholar
Rozhnov, SV (2009) Development of the trophic structure of Vendian and Early Paleozoic marine communities. Paleontological Journal 43, 1364–77.CrossRefGoogle Scholar
Runnegar, B (1982) Oxygen requirements, biology and phylogenetic significance of the Late Precambrian worm Dickinsonia, and the evolution of the burrowing habit. Alcheringa 6, 223–39.CrossRefGoogle Scholar
Schopf, KM and Baumiller, TK (1998) A biomechanical approach to Ediacaran hypotheses: how to weed the Garden of Ediacara. Lethaia 31, 8997.CrossRefGoogle Scholar
Seilacher, A (1989) Vendozoa: organismic construction in the Proterozoic biosphere. Lethaia 22, 229–39.CrossRefGoogle Scholar
Seilacher, A (1992) Vendobionta and Psammocorallia: lost constructions of Precambrian evolution. Journal of the Geological Society 149, 607–13.CrossRefGoogle Scholar
Seilacher, A (1999) Biomat related lifestyles in the Precambrian. Palaios 14, 8693.CrossRefGoogle Scholar
Seilacher, A (2007) The nature of vendobionts. In The Rise and Fall of the Ediacaran Biota (eds Vickers-Rich, P and Komarower, P), pp. 387–97. Geological Society of London, Special Publication no. 286.Google Scholar
Seilacher, A, Grazhdankin, D and Legouta, A (2003) Ediacaran biota: the dawn of animal life in the shadow of giant protists. Paleontological Research 7, 4354.CrossRefGoogle Scholar
Smith, AM (1991) The role of suction in the adhesion of limpets. Journal of Experimental Biology 161, 151–69.CrossRefGoogle Scholar
Smith, AM (1992) Alternation between attachment mechanisms by limpets in the field. Journal of Experimental Marine Biology and Ecology 160, 205–20.CrossRefGoogle Scholar
Sperling, EA and Vinther, J (2010) A placozoan affinity for Dickinsonia and the evolution of late Proterozoic metazoan feeding modes. Evolution and Development 12, 201–9.CrossRefGoogle ScholarPubMed
Sprigg, RC (1947) Early Cambrian (?) jellyfishes from the Flinders Ranges, South Australia. Transactions of the Royal Society of South Australia 71, 212–24.Google Scholar
Sprigg, RC (1949) Early Cambrian ‘jellyfishes’ of Ediacara, South Australia and Mouth John, Kimberley District, Western Australia. Transactions of the Royal Society of South Australia 73, 7299.Google Scholar
Stankovsky, AF, Verichev, EM and Dobeiko, IP (1985) The Vendian of Southeastern White Sea region. In The Vendian System, Stratigraphy and Geological Processes (eds Sokolov, B and Iwanowski, A), v. 2, pp. 67–76. Moscow, Nauka [in Russian].Google Scholar
Steiner, M and Reitner, J (2001) Evidence of organic structures in Ediacara type fossils and associated microbial mats. Geology 29, 1119–22.2.0.CO;2>CrossRefGoogle Scholar
Tarhan, LG, Droser, ML, Gehling, JG and Dzaugis, MP (2015) Taphonomy and morphology of the Ediacara form genus Aspidella . Precambrian Research 257, 124–36.CrossRefGoogle Scholar
Tarhan, LG, Droser, ML, Gehling, JG and Dzaugis, MP (2017) Microbial mat sandwiches and other anactualistic sedimentary features of the Ediacara Member (Rawnsley Quartzite, South Australia): implications for interpretation of the Ediacaran sedimentary record. Palaios 32, 181–94.CrossRefGoogle Scholar
Termier, H and Termier, G (1968) Evolution et Biocinése: les Invertébrés dans l’Histoire du Monde Vivant. Paris: Masson, 241 pp.Google Scholar
Wade, M (1968) Preservation of soft-bodied animals in Precambrian sandstones at Ediacara, South Australia. Lethaia 1, 238–67.CrossRefGoogle Scholar
Wade, M (1972) Dickinsonia: polychaete worms from the Late Precambrian Ediacara fauna, South Australia. Memoirs of the Queensland Museum 16, 171–90.Google Scholar
Waggoner, BM (1995) Ediacaran lichens: a critique. Paleobiology 21, 393–7.CrossRefGoogle Scholar
Whittington, ID and Cribb, BW (2001) Adhesive secretions in the Platyhelminthes. Advances in Parasitology 48, 101224.CrossRefGoogle ScholarPubMed
Xiao, S (2013) Mudding the waters. Nature 493, 28–9.CrossRefGoogle Scholar
Zakrevskaya, MA (2014) Paleoecological reconstruction of the Ediacaran benthic macroscopic communities of the White Sea (Russia). Palaeogeography, Palaeoclimatology, Palaeoecology 410, 2738.CrossRefGoogle Scholar
Zhuravlev, AY (1993) Were Ediacaran Vendobionta multicellulars? Neues Jahrbuch für Geologie und Paläontologie, Abhandlungen 190, 299314.Google Scholar