Development and function explain the modular evolution of phalanges in gecko lizards

• Published in: Proceedings of the Royal Society. B, Biological sciences Vol. 289; no. 1966; p. 20212300
• Main Authors: Rothier, Priscila S, Simon, Monique N, Marroig, Gabriel, Herrel, Anthony, Kohlsdorf, Tiana
• Format: Journal Article
• Language: English
• Published: England Royal Society, The 12.01.2022; The Royal Society
• Subjects: Animals; Biological Evolution; Bone and Bones - anatomy & histology; Evolution; Extremities; Life Sciences; Lizards - anatomy & histology; Locomotion; phalanges; modularity; autopodium; morphology; toepad
• ISSN: 0962-8452; 1471-2954
• DOI: 10.1098/rspb.2021.2300

Selective regimes favouring the evolution of functional specialization probably affect covariation among phenotypic traits. Phalanges of most tetrapods develop from a conserved module that constrains their relative proportions. In geckos, however, biomechanical specializations associated with adhesive toepads involve morphological variation in the autopodium and might reorganize such modular structures. We tested two hypotheses to explain the modular architecture of hand bones in geckos, one based on developmental interactions and another incorporating functional associations related to locomotion, and compared the empirical support for each hypothetical module between padded and padless lineages. We found strong evidence for developmental modules in most species, which probably reflects embryological constraints during phalangeal formation. Although padded geckos exhibit a functional specialization involving the hyperextension of the distal phalanges that is absent in padless species, the padless species are the ones that show a distal functional module with high integration. Some ancestrally padless geckos apparently deviate from developmental predictions and present a relatively weak developmental module of phalanges and a strongly integrated distal module, which may reflect selective regimes involving incipient frictional adhesion in digit morphology. Modularity of digit elements seems dynamic along the evolutionary history of geckos, being associated with the presence/absence of adhesive toepads.