Abstract
Bats are atypical small mammals. Size is crucial for bats because it affects most aerodynamic variables and several key echolocation parameters. In turn, scaling relationships of both flight and echolocation have been suggested to constrain bat body size evolution. Previous studies have found a large phylogenetic effect and the inclusion of early Eocene fossil bats contributed to recover idiosyncratic body size change patterns in bats. Here, we test these previous hypotheses of bat body size evolution using a large, comprehensive supermatrix phylogeny (+800 taxa) to optimize body size and examine changes reconstructed along branches. Our analysis provides evidence of rapid stem phyletic nanism, an ancestral value stabilized at 12 g for crown-clade Chiroptera followed by backbone stasis, low-magnitude changes inside established families, and massive body size increase at accelerated rate in pteropodid subclades. Total variation amount explained by pteropodid subclades was 86.3%, with most changes reconstructed as phyletic increases but also apomorphic decreases. We evaluate these macroevolutionary patterns in light of the constraints hypothesis, and in terms of both neutral and adaptive evolutionary models. The reconstructed macroevolution of bat body size led us to propose that echolocation and flight work as successive, nested constraints limiting bat evolution along the body size scale.
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Acknowledgements
We thank Santiago Catalano for his help with handling TNT in the body mass optimization analyses. We thank the support from Consejo Nacional de Investigaciones Científicas y Técnicas (CONICET), Argentina, PICT 2015-2389 and PICT 2016-3682.
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Moyers Arévalo, R.L., Amador, L.I., Almeida, F.C. et al. Evolution of Body Mass in Bats: Insights from a Large Supermatrix Phylogeny. J Mammal Evol 27, 123–138 (2020). https://doi.org/10.1007/s10914-018-9447-8
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DOI: https://doi.org/10.1007/s10914-018-9447-8