Serial Disparity in the Carnivoran Backbone Unveils a Complex Adaptive Role in Metameric Evolution

Overview

Journal Commun Biol

Specialty Biology

Date 2021 Jul 16

PMID 34267313

Citations 10

Authors

Borja Figueirido

Alberto Martin-Serra

Alejandro Perez-Ramos

David Velasco

Francisco J Pastor

Roger J Benson

Affiliations

Soon will be listed here.

Abstract

Organisms comprise multiple interacting parts, but few quantitative studies have analysed multi-element systems, limiting understanding of phenotypic evolution. We investigate how disparity of vertebral morphology varies along the axial column of mammalian carnivores - a chain of 27 subunits - and the extent to which morphological variation have been structured by evolutionary constraints and locomotory adaptation. We find that lumbars and posterior thoracics exhibit high individual disparity but low serial differentiation. They are pervasively recruited into locomotory functions and exhibit relaxed evolutionary constraint. More anterior vertebrae also show signals of locomotory adaptation, but nevertheless have low individual disparity and constrained patterns of evolution, characterised by low-dimensional shape changes. Our findings demonstrate the importance of the thoracolumbar region as an innovation enabling evolutionary versatility of mammalian locomotion. Moreover, they underscore the complexity of phenotypic macroevolution of multi-element systems and that the strength of ecomorphological signal does not have a predictable influence on macroevolutionary outcomes.

Citing Articles

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The influence of the land-to-sea macroevolutionary transition on vertebral column disparification in Pinnipedia.

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