Patterns of skeletal integration in birds reveal that adaptation of element shapes enables coordinated evolution between anatomical modules

Patterns of skeletal integration in birds reveal that adaptation of element shapes enables coordinated evolution between anatomical modules

Birds show tremendous ecological disparity in spite of strong biomechanical constraints imposed by flight. Modular skeletal evolution is generally accepted to have facilitated this, with distinct body regions showing semi-independent evolutionary trajectories. However, this hypothesis has received l...

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Veröffentlicht in:Nature ecology & evolution 2021-09, Vol.5 (9), p.1250-1258
Hauptverfasser: Orkney, Andrew, Bjarnason, Alex, Tronrud, Brigit C., Benson, Roger B. J.
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Sprache:eng
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631/158/857
631/181/2468
631/601/1332
Adaptation
Adaptation, Physiological
Animals
Biological and Physical Anthropology
Biological Evolution
Biomechanics
Biomedical and Life Sciences
Birds
Ecological adaptation
Ecology
Evolution
Evolutionary Biology
Head
Integration
Life Sciences
Modularity
Paleontology
Phylogeny
Skeleton
Skull
Three dimensional analysis
Three dimensional models
Zoology
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container_issue 9
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container_title Nature ecology & evolution
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creator Orkney, Andrew
Bjarnason, Alex
Tronrud, Brigit C.
Benson, Roger B. J.
description Birds show tremendous ecological disparity in spite of strong biomechanical constraints imposed by flight. Modular skeletal evolution is generally accepted to have facilitated this, with distinct body regions showing semi-independent evolutionary trajectories. However, this hypothesis has received little scrutiny. We analyse evolutionary modularity and ecomorphology using three-dimensional data from across the entire skeleton in a phylogenetically broad sample of extant birds. We find strongly modular evolution of skeletal element sizes within body regions (head, trunk, forelimb and hindlimb). However, element shapes show substantially less modularity, have stronger relationships to ecology, and provide evidence that ecological adaptation involves coordinated evolution of elements across different body regions. This complicates the straightforward paradigm in which modular evolution facilitated the ecological diversification of birds. Our findings suggest the potential for undetected patterns of morphological evolution in even well-studied groups, and advance the understanding of the interface between evolutionary integration and ecomorphology. Analysis of high-resolution three-dimensional models of 149 extant bird species reveals contrasting patterns of integration across the avian skeleton for size and shape: element sizes within body regions are strongly modular, but element shapes are less so and have stronger relationships with ecology.
doi_str_mv 10.1038/s41559-021-01509-w
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subjects 631/158/857
631/181/2468
631/601/1332
Adaptation
Adaptation, Physiological
Animals
Biological and Physical Anthropology
Biological Evolution
Biomechanics
Biomedical and Life Sciences
Birds
Ecological adaptation
Ecology
Evolution
Evolutionary Biology
Head
Integration
Life Sciences
Modularity
Paleontology
Phylogeny
Skeleton
Skull
Three dimensional analysis
Three dimensional models
Zoology
title Patterns of skeletal integration in birds reveal that adaptation of element shapes enables coordinated evolution between anatomical modules
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