Triassic stem caecilian supports dissorophoid origin of living amphibians

Kligman, Ben T.; Gee, Bryan M.; Marsh, Adam D.; Nesbitt, Sterling J.; Smith, Matthew E.; Parker, William G.; Stocker, Michelle R.

Triassic stem caecilian supports dissorophoid origin of living amphibians

Ben T. Kligman (), Bryan M. Gee (), Adam D. Marsh (), Sterling J. Nesbitt (), Matthew E. Smith (), William G. Parker () and Michelle R. Stocker ()
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Ben T. Kligman: Petrified Forest National Park
Bryan M. Gee: University of Washington
Adam D. Marsh: Petrified Forest National Park
Sterling J. Nesbitt: Virginia Tech
Matthew E. Smith: Petrified Forest National Park
William G. Parker: Petrified Forest National Park
Michelle R. Stocker: Virginia Tech

Nature, 2023, vol. 614, issue 7946, 102-107

Abstract: Abstract Living amphibians (Lissamphibia) include frogs and salamanders (Batrachia) and the limbless worm-like caecilians (Gymnophiona). The estimated Palaeozoic era gymnophionan–batrachian molecular divergence1 suggests a major gap in the record of crown lissamphibians prior to their earliest fossil occurrences in the Triassic period2–6. Recent studies find a monophyletic Batrachia within dissorophoid temnospondyls7–10, but the absence of pre-Jurassic period caecilian fossils11,12 has made their relationships to batrachians and affinities to Palaeozoic tetrapods controversial1,8,13,14. Here we report the geologically oldest stem caecilian—a crown lissamphibian from the Late Triassic epoch of Arizona, USA—extending the caecilian record by around 35 million years. These fossils illuminate the tempo and mode of early caecilian morphological and functional evolution, demonstrating a delayed acquisition of musculoskeletal features associated with fossoriality in living caecilians, including the dual jaw closure mechanism15,16, reduced orbits17 and the tentacular organ18. The provenance of these fossils suggests a Pangaean equatorial origin for caecilians, implying that living caecilian biogeography reflects conserved aspects of caecilian function and physiology19, in combination with vicariance patterns driven by plate tectonics20. These fossils reveal a combination of features that is unique to caecilians alongside features that are shared with batrachian and dissorophoid temnospondyls, providing new and compelling evidence supporting a single origin of living amphibians within dissorophoid temnospondyls.

Date: 2023
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DOI: 10.1038/s41586-022-05646-5

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