The Influence of the Land-to-sea Macroevolutionary Transition on Vertebral Column Disparification in Pinnipedia

Overview

Journal Proc Biol Sci

Specialty Biology

Date 2024 Apr 9

PMID 38593849

Authors

Juan Miguel Esteban

Alberto Martin-Serra

Alejandro Perez-Ramos

Natalia Rybczynski

Katrina Jones

Borja Figueirido

Affiliations

Soon will be listed here.

Abstract

The repeated returns of vertebrates to the marine ecosystems since the Triassic serve as an evolutionary model to understand macroevolutionary change. Here we investigate the effects of the land-to-sea transition on disparity and constraint of the vertebral column in aquatic carnivorans (Carnivora; Pinnipedia) to assess how their functional diversity and evolutionary innovations influenced major radiations of crown pinnipeds. We use three-dimensional geometric morphometrics and multivariate analysis for high-dimensional data under a phylogenetic framework to quantify vertebral size and shape in living and extinct pinnipeds. Our analysis demonstrates an important shift in vertebral column evolution by 10-12 million years ago, from an unconstrained to a constrained evolutionary scenario, a point of time that coincides with the major radiation of crown pinnipeds. Moreover, we also demonstrate that the axial skeleton of phocids and otariids followed a different path of morphological evolution that was probably driven by their specialized locomotor strategies. Despite this, we found a significant effect of habitat preference (coastal versus pelagic) on vertebral morphology of crown taxa regardless of the family they belong. In summary, our analysis provides insights into how the land-to-sea transition influenced the complex evolutionary history of pinniped vertebral morphology.

Citing Articles

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

Esteban J, Martin-Serra A, Perez-Ramos A, Rybczynski N, Jones K, Figueirido B Proc Biol Sci. 2024; 291(2020):20232752.

PMID: 38593849 PMC: 11003777. DOI: 10.1098/rspb.2023.2752.

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