Animals, protists and bacteria share marine biogeographic patterns

Over millennia, ecological and evolutionary mechanisms have shaped macroecological patterns across the tree of life. Research describing these patterns at both regional and global scales has traditionally focused on the study of metazoan species. Consequently, there is a limited understanding of cross-phylum biogeographic structuring and an escalating need to understand the macroecology of both microscopic and macroscopic organisms. Here we used environmental DNA (eDNA) metabarcoding to explore the biodiversity of marine metazoans, protists and bacteria along an extensive and highly heterogeneous coastline. Our results showed remarkably consistent biogeographic structure across the kingdoms of life despite billions of years of evolution. Analyses investigating the drivers of these patterns for each taxonomic kingdom found that environmental conditions (such as temperature) and, to a lesser extent, anthropogenic stressors (such as fishing pressure and pollution) explained some of the observed variation. Additionally, metazoans displayed biogeographic patterns that suggested regional biotic homogenization. Against the backdrop of global pervasive anthropogenic environmental change, our work highlights the importance of considering multiple domains of life to understand the maintenance and drivers of biodiversity patterns across broad taxonomic, ecological and geographical scales. Despite the fact that large animals and microorganisms face different environmental and anthropogenic pressures, this study finds that marine biogeographic patterns are similar for organisms in different kingdoms.

Automated summary

This study utilized environmental DNA (eDNA) technology to explore the biodiversity of marine organisms and found remarkably consistent biogeographic structure across different kingdoms of life. The main drivers of these patterns were environmental conditions and to a lesser extent, anthropogenic stressors. Additionally, animals displayed biogeographic patterns suggesting regional biotic homogenization.