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Pantestudines

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Pantestudines
Temporal range:Middle Triassic-Holocene,240–0MaPossible mid-Permian record[1]
Fossil specimen ofOdontochelys semitestacea
Scientific classificationEdit this classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Class: Reptilia
Clade: Archelosauria
Clade: Pantestudines
Joyce&Parham&Gauthier,2004
Subgroups

PantestudinesorPan-Testudinesis the proposed group of allreptilesmore closely related toturtlesthan to any other living animal. It includes both modern turtles (crown groupturtles, also known as Testudines) and all of their extinct relatives (also known asstem-turtles).[2]Pantestudines with a complete shell are placed in the cladeTestudinata.

Classification

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The identity of the ancestors and closest relatives of the turtle lineage was a longstanding scientific mystery, though new discoveries and better analyses in the early 21st century began to clarify turtle relationships. They had traditionally been considered relatives of thecaptorhinids,which also possessed ananapsidskull configuration. Later, the consensus shifted towards Testudinata's placement withinParareptilia,another "anapsid" clade.[3]

Analysis of fossil data has shown that turtles are likelydiapsidreptiles, most closely related either to thearchosaurs(crocodiles, bird, and relatives) or thelepidosaurs(lizards, tuatara, and relatives). An early proponent of this scenario wasGoodrich(1916), who defended a diapsid origin of turtles based on morphological evidence.[4]Genetic analysis strongly favors the hypothesis that turtles are the closest relatives of the archosaurs, though studies using only fossil evidence often continue to recover them as relatives of lepidosaurs or as non-diapsids. Studies using only fossils, as well as studies using a combination of fossil and genetic evidence, both suggest thatsauropterygians,the group of prehistoric marine reptiles including theplesiosaursand the often superficially turtle-likeplacodonts,are themselves stem-turtles.[1]This hypothesis had been previously investigated in the 19th century.[5]

Lee (2001) found that forcing the turtle group to cluster with archosauromorphs resulted inRhynchosauriabecoming Testudinata's sister clade. Forcing a relationship with lepidosaurs resulted in turtles being close relatives of sauropterygians within Lepidosauromorpha. The anapsid hypothesis was still better supported, although an archosauromorph affinity could not be rejected.[6]

Although morphology-based analyses usually do not support a turtle-archosaur clade (Archelosauria), Bhullar & Bever (2009) identified a laterosphenoid bone, typical ofArchosauriformes,in the stem-turtleProganochelys.It may serve as a synapomorphy for this proposed clade.[7]

The cladogram shown below follows the most likely result found by an analysis of turtle relationships using both fossil and genetic evidence by M.S. Lee, in 2013. This study foundEunotosaurus,usually regarded as a turtle relative, to be only very distantly related to turtles in the cladeParareptilia.However, Lee discusses the necessity to investigate the possibility that parareptiles are actually archelosaurs instead of non-saurian sauropsids.[8]

Sauria(=Ankylopoda)

The cladogram below follows the most likely result found by another analysis of turtle relationships, this one using only fossil evidence, published by Rainer Schoch and Hans-Dieter Sues in 2015. This study foundEunotosaurusto be an actual early stem-turtle, though other versions of the analysis found weak support for it as a parareptile.[1]

Beveret al.(2015) redescribed the skull ofEunotosaurus,identifying a lower temporal fenestra, with a juvenile specimen also having visible upper temporal fenestrae. This instigated a reinterpretation of this taxon as a diapsid instead of an anapsid. Their phylogenetic analyses strongly supportedEunotosaurus's state as a stem-turtle and the placement of Pantestudines in Diapsida, though they couldn't determine a well-defined position within that clade. Sauropterygia andAcerosodontosaurusalso end up as possible stem-turtles in some of the trees.[9]

Benton (2015) compiled 2 synapomorphies of Ankylopoda (which would also include Sauropterygia,ThalattosauriaandIchthyosauriaclose to lepidosaurs): prootic-parietal contact and hooked fifth metatarsal.[10]

Time-calibrated phylogeny recovered by Shafferet al.(2017) dated the split of Pantestudines from its sister clade (the clade containing archosaurs and all tetrapods more closely related to archosaurs than to any other living animals) to mid-Carboniferous.[11]

Laurin and Piñeiro (2017) placed turtles close to pareiasaurs among parareptiles once more. However, parareptiles were considered derived diapsids in this analysis. The authors interpreted these results as an indication that there might be no conflict between the hypotheses of a parareptilian origin and a diapsid origin.[3]However, this study was criticised in a response paper, which charged that the matrix the paper used was outdated and did not take into account the previous two decades of literature about parareptiles.[12]

The cladogram below follows the analysis of Liet al.(2018). It agrees with the placement of turtles within Diapsida but finds them outside of Sauria (the Lepidosauromorpha + Archosauromorpha clade).[13]

Gardner & Van Franken (2020) criticized the analysis by Liet al., citing problems with the data set and observing that their proposed phylogeny was not supported once the issues were corrected.[14]

Lichtig & Lucas (2021) proposedPappochelyswas related to sauropterygians,Eunotosauruswas acaseidsynapsid,and turtles were derived pareiasaur parareptiles close toAnthodon.According to this hypothesis, the turtle shell evolved from a fusion of the ribs to dorsal osteoderms.Odontocheys,which lacked a carapace, is seen as a highly derived taxon instead of a representative of the ancestral state of turtles.[15]The reliability of the molecular support for Archelosauria was also questioned, although Simõeset al.(2022) found morphological support for this hypothesis. In their analysis,Pappochelysis the basalmost pantestudine butEunotosaurusis a basal neodiapsid instead of a stem-turtle, parareptile or synapsid.[16]

References

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  1. ^abcSchoch, Rainer R.; Sues, Hans-Dieter (24 June 2015). "A Middle Triassic stem-turtle and the evolution of the turtle body plan".Nature.523(7562): 584–587.Bibcode:2015Natur.523..584S.doi:10.1038/nature14472.PMID26106865.S2CID205243837.
  2. ^Joyce, W. G.; Parham, J. F.; Gauthier, J. A. (2004). "Developing a protocol for the conversion of rank-based taxon names to phylogenetically defined clade names, as exemplified by turtles".Journal of Paleontology.78(5): 989–1013.CiteSeerX10.1.1.325.7353.doi:10.1666/0022-3360(2004)078<0989:dapftc>2.0.co;2.S2CID15078337.
  3. ^abLaurin, Michel; Piñeiro, Graciela H. (2017-11-02)."A Reassessment of the Taxonomic Position of Mesosaurs, and a Surprising Phylogeny of Early Amniotes".Frontiers in Earth Science.5:88.Bibcode:2017FrEaS...5...88L.doi:10.3389/feart.2017.00088.hdl:20.500.12008/33548.ISSN2296-6463.
  4. ^Goodrich, Edwin S. (1916)."On the classification of the reptilia".Proceedings of the Royal Society of London. Series B, Containing Papers of a Biological Character.89(615): 261–276.doi:10.1098/rspb.1916.0012.ISSN0950-1193.S2CID128565450.
  5. ^Baur, G. (1887)."On the phylogenetic arrangement of the Sauropsida".Journal of Morphology.1(1): 93–104.doi:10.1002/jmor.1050010106.ISSN0362-2525.S2CID86222218.
  6. ^Lee, Michael S.Y. (2001)."Molecules, morphology, and the monophyly of diapsid reptiles".Contributions to Zoology.70(1): 1–22.doi:10.1163/18759866-07001001.ISSN1383-4517.
  7. ^Bhullar, Bhart-Anjan S.; Bever, Gabe S. (2009)."An Archosaur-Like Laterosphenoid in Early Turtles (Reptilia: Pantestudines)".Breviora.518(1): 1–11.doi:10.3099/0006-9698-518.1.1.ISSN0006-9698.S2CID42333056.Retrieved2022-12-02.
  8. ^Lee, M. S. Y. (2013)."Turtle origins: Insights from phylogenetic retrofitting and molecular scaffolds".Journal of Evolutionary Biology.26(12): 2729–2738.doi:10.1111/jeb.12268.PMID24256520.S2CID2106400.
  9. ^Bever, G. S.; Lyson, Tyler R.; Field, Daniel J.; Bhullar, Bhart-Anjan S. (2015)."Evolutionary origin of the turtle skull".Nature.525(7568): 239–242.doi:10.1038/nature14900.ISSN1476-4687.
  10. ^Benton, Michael (2015).Vertebrate Paleontology(4th ed.). John Wiley & Sons.ISBN978-1-118-40755-4.
  11. ^H. Bradley Shaffer; Evan McCartney-Melstad; Thomas J. Near; Genevieve G. Mount; Phillip Q. Spinks (2017). "Phylogenomic analyses of 539 highly informative loci dates a fully resolved time tree for the major clades of living turtles (Testudines)".Molecular Phylogenetics and Evolution.115:7–15.doi:10.1016/j.ympev.2017.07.006.PMID28711671.
  12. ^MacDougall, Mark J.; Modesto, Sean P.; Brocklehurst, Neil; Verrière, Antoine; Reisz, Robert R.; Fröbisch, Jörg (2018-07-25)."Commentary: A Reassessment of the Taxonomic Position of Mesosaurs, and a Surprising Phylogeny of Early Amniotes".Frontiers in Earth Science.6:99.doi:10.3389/feart.2018.00099.ISSN2296-6463.
  13. ^Li, Chun; Fraser, Nicholas C.; Rieppel, Olivier; Wu, Xiao-Chun (August 2018)."A Triassic stem turtle with an edentulous beak".Nature.560(7719): 476–479.Bibcode:2018Natur.560..476L.doi:10.1038/s41586-018-0419-1.ISSN0028-0836.PMID30135526.S2CID52067286.
  14. ^Gardner, Nicholas M.; Van Vranken, Nathan E. (2020-04-29)."The Permian diapsid reptiles Acerosodontosaurus and Claudiosaurus are not stem-turtles: Morphological and fossil phylogenetic analyses must take a cautious, holistic approach toward turtle origins".Proceedings of the West Virginia Academy of Science.92(1).doi:10.55632/pwvas.v92i1.626.ISSN2473-0386.S2CID248952833.
  15. ^Lichtig, Asher; Lucas, Spencer (2021)."Chinlechelys from the Upper Triassic of New Mexico, USA, and the origin of turtles".Palaeontologia Electronica.doi:10.26879/886.S2CID233454789.
  16. ^Simões, Tiago R.; Kammerer, Christian F.; Caldwell, Michael W.; Pierce, Stephanie E. (2022-08-19)."Successive climate crises in the deep past drove the early evolution and radiation of reptiles".Science Advances.8(33): eabq1898.doi:10.1126/sciadv.abq1898.ISSN2375-2548.PMC9390993.PMID35984885.