Functional tests of the competitive exclusion hypothesis for multituberculate extinction

• Published in: Royal Society open science Vol. 6; no. 3; p. 181536
• Main Authors: Adams, Neil F, Rayfield, Emily J, Cox, Philip G, Cobb, Samuel N, Corfe, Ian J
• Format: Journal Article
• Language: English
• Published: England The Royal Society 01.03.2019
• Subjects: Biology (Whole Organism); digital reconstruction; finite-element analysis; macroevolution; mammalian evolution; multituberculata; rodentia; digital reconstruction; macroevolution; Multituberculata; finite-element analysis; mammalian evolution; Rodentia
• ISSN: 2054-5703; 2054-5703
• DOI: 10.1098/rsos.181536

Multituberculate mammals thrived during the Mesozoic, but their diversity declined from the mid-late Paleocene onwards, becoming extinct in the late Eocene. The radiation of superficially similar, eutherian rodents has been linked to multituberculate extinction through competitive exclusion. However, characteristics providing rodents with a supposed competitive advantage are currently unknown and comparative functional tests between the two groups are lacking. Here, a multifaceted approach to craniomandibular biomechanics was taken to test the hypothesis that superior skull function made rodents more effective competitors. Digital models of the skulls of four extant rodents and the Upper Cretaceous multituberculate were constructed and used (i) in finite-element analysis to study feeding-induced stresses, (ii) to calculate metrics of bite force production and (iii) to determine mechanical resistances to bending and torsional forces. Rodents exhibit higher craniomandibular stresses and lower resistances to bending and torsion than the multituberculate, apparently refuting the competitive exclusion hypothesis. However, rodents optimize bite force production at the expense of higher skull stress and we argue that this is likely to have been more functionally and selectively important. Our results therefore provide the first functional lines of evidence for potential reasons behind the decline of multituberculates in the changing environments of the Paleogene.