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Correlates of substitution rate variation in a robust Procellariiform seabird phylogeny

Estandia, Andrea1; Chesser, Terry2; James, Helen3; Levy, Max1; Ferrer-Obiol, Joan4; Bretagnolle, Vincent5; González-Solís, Jacob4; Welch, Andreanna1

Published Aug 04, 2021; Updated Mar 31, 2022 on Dryad. https://doi.org/10.5061/dryad.h18931zm5

Data files

Aug 04, 2021 version files 290.24 MB
Mar 31, 2022 version files 274.44 MB

Abstract

Molecular substitution rates vary among branches and can lead to inaccurate reconstructions of evolutionary relationships and obscure the true phylogeny of affected clades. Body mass is often assumed to have a major influence on substitution rate, though other factors such as population size, life history traits, and flight demands are also thought to have an influence. Birds of the order Procellariiformes—which encompasses petrels, storm-petrels and albatrosses—show a striking 900-fold difference in body mass between the smallest and largest members, divergent life history traits, and substantial heterogeneity in mitochondrial substitution rates. Here, we used genome-scale nuclear DNA sequence data from 4365 ultraconserved element loci (UCEs) in 51 procellariiform species to examine whether phylogenetic reconstruction using genome-wide datasets is robust to the presence of rate heterogeneity, and to identify predictors of substitution rate variation. Our results provide a backbone phylogeny for procellariiform seabirds and resolves several controversies about the evolutionary history of the order, demonstrating that albatrosses are basal, storm-petrels are paraphyletic and diving petrels nestled within the Procellariidae. We find evidence of rate variation; however, all phylogenetic analyses using both concatenation and multispecies coalescent approaches recovered the same branching topology, including analyses implementing different clock models, and analyses of the most and least clock-like loci. Overall, we find that rate heterogeneity is little impacted by body mass and age at first breeding, but moderately impacted by longevity and hand-wing index, a proxy for wing shape and flight efficiency. Our results indicate that substitution rate may be the product of interactions among many, potentially taxon-specific, variables.