During the Mesozoic, Crocodylomorpha had a much higher taxonomic and morphological diversity than today. Members of one particularly successful clade, Thalattosuchia, are well-known for being longirostrine: having long, slender snouts. It has generally been assumed that Thalattosuchia owed their success in part to the evolution of longirostry, leading to a feeding ecology similar to that of the living Indian gharial, Gavialis. Here, we compare form and function of the skulls of the thalattosuchian Pelagosaurus and Gavialis using digital reconstructions of the skull musculoskeletal anatomy and finite element models to show that they had different jaw muscle arrangements and biomechanical behaviour. Additionally, the relevance of feeding-related mandibular traits linked to longirostry in the radiation of crocodylomorph clades was investigated by conducting an evolutionary rates analysis under the variable rates model. We find that, even though Pelagosaurus and Gavialis share similar patterns of stress distribution in their skulls, the former had lower mechanical resistance. This suggests that compared to Gavialis, Pelagosaurus was unable to process large, mechanically less tractable prey, instead operating as a specialised piscivore that fed on softer and smaller prey. Secondly, innovation of feeding strategies was achieved by rate acceleration of functional characters of the mandible, a key mechanism for the diversification of certain clades like thalattosuchians and eusuchians. Different rates of functional evolution suggest divergent diversification dynamics between teleosaurids and metriorhynchids in the Jurassic.
Pelagosaurus cranium model
Surface model of the cranium of Pelagosaurus.
pelagosaurus-cranium.stl
Pelagosaurus mandible model
Surface model of the mandible of Pelagosaurus
pelagosaurus-mand.stl
Gavialis cranium model
Surface model of the cranium of Gavialis. (Note: not original size as the model was originally scaled to skull length)
gavialis_cranium.stl
Gavialis mandible model
Surface model of the mandible of Gavialis. (Note: not original size as the model was originally scaled to skull length)
gavialis_mand.stl
Gavialis cranium bilateral anterior
Abaqus input file of Gavialis cranium simulating a bilateral anterior bite.
gav_cr_bi_ant.inp
Gavialis cranium bilateral middle
Abaqus input file of Gavialis cranium simulating a bilateral middle bite.
gav_cr_bi_mid.inp
Gavialis cranium bilateral posterior
Abaqus input file of Gavialis cranium simulating a bilateral posterior bite.
gav_cr_bi_pos.inp
Gavialis cranium unilateral anterior
Abaqus input file of Gavialis cranium simulating an unilateral anterior bite.
gav_cr_uni_ant.inp
Gavialis cranium unilateral posterior
Abaqus input file of Gavialis cranium simulating an unilateral posterior bite.
gav_cr_uni_pos.inp
Gavialis mandible bilateral anterior
Abaqus input file of Gavialis mandible simulating a bilateral anterior bite.
gav_mand_bi_ant.inp
Gavialis mandible bilateral middle
Abaqus input file of Gavialis mandible simulating a bilateral middle bite.
gav_mand_bi_mid.inp
Gavialis mandible bilateral posterior
Abaqus input file of Gavialis mandible simulating a bilateral posterior bite.
gav_mand_bi_pos.inp
Gavialis mandible unilateral anterior
Abaqus input file of Gavialis mandible simulating an unilateral anterior bite.
gav_mand_uni_ant.inp
Gavialis mandible unilateral posterior
Abaqus input file of Gavialis mandible simulating an unilateral posterior bite.
gav_mand_uni_pos.inp
Pelagosaurus cranium bilateral anterior
Abaqus input file of Pelagosaurus cranium simulating a bilateral anterior bite.
pel_cr_bi_ant.inp
Pelagosaurus cranium bilateral middle
Abaqus input file of Pelagosaurus cranium simulating a bilateral middle bite.
pel_cr_bi_mid.inp
Pelagosaurus cranium bilateral posterior
Abaqus input file of Pelagosaurus cranium simulating a bilateral posterior bite.
pel_cr_bi_pos.inp
Pelagosaurus cranium unilateral anterior
Abaqus input file of Pelagosaurus cranium simulating an unilateral anterior bite.
pel_cr_uni_ant.inp
Pelagosaurus cranium unilateral posterior
Abaqus input file of Pelagosaurus cranium simulating an unilateral posterior bite.
pel_cr_uni_pos.inp
Pelagosaurus mandible bilateral anterior
Abaqus input file of Pelagosaurus mandible simulating a bilateral anterior bite.
pel_mand_bi_ant.inp
Pelagosaurus mandible bilateral middle
Abaqus input file of Pelagosaurus mandible simulating a bilateral middle bite.
pel_mand_bi_mid.inp
Pelagosaurus mandible bilateral posterior
Abaqus input file of Pelagosaurus mandible simulating a bilateral posterior bite.
pel_mand_bi_pos.inp
Pelagosaurus mandible unilateral anterior
Abaqus input file of Pelagosaurus mandible simulating an unilateral anterior bite.
pel_mand_uni_ant.inp
Pelagosaurus mandible unilateral posterior
Abaqus input file of Pelagosaurus mandible simulating an unilateral posterior bite.
pel_mand_uni_pos.inp
Lower jaws images
Images of crocodylomorph mandibles that were used to measure the mandibular functional characters. For sources, see Supplementary Information file.
Crocodylomorpha lower jaws.zip
Supporting Information
Includes median Von Mises stress values, details of FE models, list of taxa studied in the rates analyses, additional rates trees and randomisation tests results
Pelagosaurus CT data
Specimen: Pelagosaurus typus BRLSI M1413. Scanned in a Nikon XT H 225ST lCT scanner. Scan parameters: 210 kV, 130 lA, 27.3 W, 0.5 mm copper filter, 1 s exposure time, no binning, ultrafocus reflection target, 3141 projections, 2 frames per projection. Scanned in two parts. Scan data were joined in VGStudio Max v2. The CT data consists of 3419 slices of 0.0956 mm pixel size and 0.0956 mm thickness.
BRLSI_M1413.zip