Palaeoclimate ocean conditions shaped the evolution of corals and their skeletons through deep time

Andrea M. Quattrini, Harvey Mudd College
Estefanía Rodríguez, American Museum of Natural History
Brant C. Faircloth, Louisiana State University
Peter F. Cowman, James Cook University
Mercer R. Brugler, American Museum of Natural History
Gabriela A. Farfan, Smithsonian National Museum of Natural History
Michael E. Hellberg, Louisiana State University
Marcelo V. Kitahara, Universidade Federal de Sao Paulo
Cheryl L. Morrison, USGS Leetown Science Center
David A. Paz-García, Centro de Investigaciones Biologicas Del Noroeste
James D. Reimer, University of the Ryukyus
Catherine S. McFadden, Harvey Mudd College

Abstract

© 2020, This is a U.S. government work and not under copyright protection in the U.S.; foreign copyright protection may apply. Identifying how past environmental conditions shaped the evolution of corals and their skeletal traits provides a framework for predicting their persistence and that of their non-calcifying relatives under impending global warming and ocean acidification. Here we show that ocean geochemistry, particularly aragonite–calcite seas, drives patterns of morphological evolution in anthozoans (corals, sea anemones) by examining skeletal traits in the context of a robust, time-calibrated phylogeny. The lability of skeletal composition among octocorals suggests a greater ability to adapt to changes in ocean chemistry compared with the homogeneity of the aragonitic skeleton of scleractinian corals. Pulses of diversification in anthozoans follow mass extinctions and reef crises, with sea anemones and proteinaceous corals filling empty niches as tropical reef builders went extinct. Changing environmental conditions will likely diminish aragonitic reef-building scleractinians, but the evolutionary history of the Anthozoa suggests other groups will persist and diversify in their wake.