Anatomical and Ontogenetic Reassessment of the Ediacaran Frond Arborea Arborea and Its Placement Within Total Group Eumetazoa

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Anatomical and Ontogenetic Reassessment of the Ediacaran Frond Arborea Arborea and Its Placement Within Total Group Eumetazoa Dunn, F., Liu, A. G. S. C., & Gehling, J. G. (2019). Anatomical and ontogenetic reassessment of the Ediacaran frond Arborea arborea and its placement within total group Eumetazoa. Palaeontology. https://doi.org/10.1111/pala.12431 Publisher's PDF, also known as Version of record License (if available): CC BY Link to published version (if available): 10.1111/pala.12431 Link to publication record in Explore Bristol Research PDF-document This is the final published version of the article (version of record). It first appeared online via Wiley at https://onlinelibrary.wiley.com/doi/full/10.1111/pala.12431 . Please refer to any applicable terms of use of the publisher. University of Bristol - Explore Bristol Research General rights This document is made available in accordance with publisher policies. Please cite only the published version using the reference above. Full terms of use are available: http://www.bristol.ac.uk/red/research-policy/pure/user-guides/ebr-terms/ [Palaeontology, 2019, pp. 1–15] ANATOMICAL AND ONTOGENETIC REASSESSMENT OF THE EDIACARAN FROND ARBOREA ARBOREA AND ITS PLACEMENT WITHIN TOTAL GROUP EUMETAZOA by FRANCES S. DUNN1,2,* , ALEXANDER G. LIU3 and JAMES G. GEHLING4 1School of Earth Sciences, Life Sciences Building, Tyndall Avenue, Bristol, BS8 1TQ, UK; [email protected] 2British Geological Survey, Nicker Hill, Keyworth, NG12 5GG, UK 3Department of Earth Sciences, Downing Street, Cambridge, CB2 3EQ, UK 4South Australia Museum, North Terrace, Adelaide, SA 5000, Australia *Corresponding author Typescript received 31 August 2018; accepted in revised form 15 February 2019 Abstract: Organisms in possession of a frondose body housed on those branches. The observed fascicled branching plan are amongst the oldest and most enigmatic members of arrangement, which seemingly connects individual units to the soft-bodied Ediacaran macrobiota. Appraisal of speci- the main body of the organism, is consistent with a biologi- mens from the late Ediacaran Ediacara Member of South cally modular construction for Arborea, and raises the possi- Australia reveals that the frondose taxon Arborea arborea bility of a colonial organization. In conjunction with probably possessed a fluid-filled holdfast disc, the size and morphological characters previously recognized by other form of which could vary within populations. Mouldic authors, including apical-basal and front-back differentiation, preservation of internal anatomical features provides evi- we propose that to the exclusion of all alternative known dence for tissue differentiation, and for bundles of tubular possibilities, Arborea can be resolved as a total group structures within the stalk of the organism. These structures eumetazoan. connect in a fascicled arrangement to individual lateral branches, before dividing further into individual units Key words: Ediacaran, Eumetazoa, frondose, modularity. F OSSILS of macroscopic, soft-bodied organisms are found lived was covered by benthic microbial mat communities globally in late Ediacaran rocks of ~570–541 million years (Gehling & Droser 2009; Tarhan et al. 2017; Droser et al. in age. These fossils are considered to document a poly- 2019). phyletic assemblage of diverse and morphologically com- Fossil assemblages of the Ediacara Member are perhaps plex marine organisms (Fedonkin et al. 2007; Budd & most widely known for possessing some of the oldest can- Jensen 2017; though see Hoyal-Cuthill & Han 2018). The didate bilaterian animals (Gold et al. 2015; Cunningham Flinders Ranges of South Australia (Dunn et al. 2019, fig. et al. 2017), including Kimberella (Gehling et al. 2014; S1) offer an exceptional record of these taxa within fine Droser & Gehling 2015), Parvancorina (Paterson et al. to coarse-grained sandstones of the Ediacara Member of 2017; Darroch et al. 2017; Coutts et al. 2017) and Dickin- the Rawnsley Quartzite (Droser et al. 2019). This unit sonia (Evans et al. 2017; Hoekzema et al. 2017; Bobrovs- documents a variety of shallow-marine and deltaic depo- kiy et al. 2018; though see Sperling & Vinther 2010). sitional environments (Gehling 2000; Gehling & Droser Alongside these taxa, frondose organisms (Glaessner 2013; Callow et al. 2013; Tarhan et al. 2017) and contains 1971) assigned to the unranked morphogroups Rangeo- the impressions of thousands of organisms representing morpha and Arboreomorpha (Erwin et al. 2011) repre- at least 30 distinct macrofossil taxa. Although the precise sent a comparatively little-studied component of the mechanism by which these fossils are preserved is a mat- Australian Ediacaran assemblages. Frondose taxa are more ter of considerable debate (Gehling 1999; Retallack 2007; typically known from older, deep-marine Ediacaran Tarhan et al. 2016, 2018; Bobrovskiy et al. 2019; Liu palaeoenvironments in Newfoundland (Canada) and Eng- 2019), there is a general consensus that Ediacara Member land (Liu et al. 2015), but in the Ediacara Member they palaeoenvironments were reasonably high-energy marine occur in shallow-marine facies interpreted to reflect settings, and that the seafloor upon which the organisms deposition in delta front, sheet-flow and mass-flow © 2019 The Authors. doi: 10.1111/pala.12431 1 Palaeontology published by John Wiley & Sons Ltd on behalf of The Palaeontological Association. This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited. 2 PALAEONTOLOGY depositional environments (Gehling & Droser 2013; see eukaryotes (summarized in Dunn et al. 2018), Arborea also Tarhan et al. 2016). Frondose taxa represented in the has only seriously been proposed to fall within either the Ediacara Member include Charnia (Gehling & Droser hypothetical phyla Petalonamae (Pflug 1970, 1972; Hoyal- 2013), Bradgatia sp. (Droser & Gehling 2015) and Pam- Cuthill & Han 2018) or Vendobionta (formerly Kingdom bikalbae (Jenkins & Nedin 2007), and their facies distri- Vendozoa, more recently considered to be a class or order butions contrast with the shoreface and wave-base sand of rhizoid protists; Seilacher 1989, 2007; Buss & Seilacher settings in which non-frondose taxa are most abundant 1994; Seilacher et al. 2003), or the Cnidaria (Jenkins & (Gehling & Droser 2013). However, numerous discoidal Gehling 1978). We here reassess the morphology of mul- impressions, initially interpreted as medusoids (Glaessner tiple Arborea specimens from South Australia, and build 1984) but more recently reinterpreted as holdfast struc- upon recent studies (Laflamme et al. 2018) to propose a tures of frondose organisms (Tarhan et al. 2015), may new model for Arborea anatomy. indicate that frondose taxa were reasonably abundant within all Ediacara Member palaeoenvironments. Tapho- nomic variation in disc expression currently precludes METHOD identification of original taxa in situations where the frond is absent (Gehling et al. 2000; Burzynski & Nar- We assessed 56 specimens that have either been histori- bonne 2015; Tarhan et al. 2015). cally assigned to Arborea, or recently synonymized with The most common frondose taxon in the Ediacara that taxon (Laflamme et al. 2018), in the collections of the Member is Arborea arborea (Glaessner & Daily 1959), the South Australia Museum (SAM; Figs 1–5). Specimens organism after which the morphogroup Arboreomorpha were collected from South Australian fossil localities is named (Laflamme & Narbonne 2008; Erwin et al. 2011; within the Ediacara Member of the Rawnsley Quartzite Laflamme et al. 2018). Arborea arborea can be abundant between 1957 and 2015; namely the Ediacara Conservation on individual bedding surfaces within wave-base, sheet- Park, the Flinders Ranges National Park, and National flow and mass-flow facies (Laflamme et al. 2018; see Heritage Site Nilpena (Dunn et al. 2019, fig. S1). Many of Charniodiscus in Gehling & Droser 2013), and also occurs the studied specimens are incomplete, and when originally in low densities alongside more typical components of catalogued by their discoverers (who include M. Wade, M. the Ediacaran biota (Coutts et al. 2016). Some Arborea Glaessner, W. Sun, R. Jenkins and J. Gehling), they were specimens may have exceeded lengths of two metres assigned to several different taxa. We follow recent syn- (Dunn et al. 2019, fig. S2), making this one of the largest onymization (Laflamme et al. 2018) of these specimens, known Ediacaran macro-organisms. A detailed reassess- but note that we cannot categorically reject the possibility ment of frondose taxa in South Australia synonymized that some specimens may derive from a different taxon. specimens previously assigned to Charniodiscus oppositus, Care has been taken to base the principal findings of this Charniodiscus arboreus, Rangea arborea, A. arborea, and study only on specimens we are confident derive from a even some Charnia sp. within A. arborea, following deter- single taxon conforming to the most recent diagnosis of mination of the three-dimensional structure of Arborea A. arborea (Laflamme et al. 2018). branches (Laflamme et al. 2018). That study diagnosed Most of the studied specimens are preserved as positive Arborea as a bifoliate frond with second order branches hyporelief impressions on the bases of sandstone beds, that lack rangeomorph sub-divisions (consistent with but some reflect composite impressions of original Laflamme & Narbonne 2008; Erwin et al. 2011; Brasier external as well as internal anatomy. A small number of et al. 2012; Laflamme et al. 2018): an
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