Conservation genomics of an endangered montane amphibian reveals low population structure, low genomic diversity, and selection pressure from disease

Wildlife diseases are a major global threat to biodiversity. Boreal toads (Anaxyrus [Bufo] boreas) are a state-endangered species in the southern Rocky Mountains of Colorado and New Mexico, and a species of concern in Wyoming, largely due to lethal skin infections caused by the amphibian chytrid fungus Batrachochytrium dendrobatidis (Bd). We performed conservation and landscape genomic analyses using single nucleotide polymorphisms from double-digest, restriction site-associated DNA sequencing in combination with the development of the first boreal toad (and first North American toad) reference genome to investigate population structure, genomic diversity, landscape connectivity, and adaptive divergence. Genomic diversity (π=0.00034–0.00040) and effective population sizes (Ne=8.9 –38.4) were low, likely due to post-Pleistocene founder effects and Bd-related population crashes over the last three decades, respectively. Population structure was also low, likely due to formerly-high connectivity among a higher density of geographically-proximate populations. Boreal toad gene flow was facilitated by low precipitation, cold minimum temperatures, less tree canopy cover, low heat load, and less urbanization. We also found >8X more putatively-adaptive loci related to Bd intensity than to all other environmental factors combined, as well as evidence for genes under selection related to immune response, heart development and regulation, and skin function. These data suggest boreal toads in habitats with Bd have experienced stronger selection pressure from disease than from other, broad-scale environmental variation. These findings can now be used by managers to conserve and recover the species through actions such as reintroduction and supplementation of populations that have declined due to Bd.