Population genetics as a tool to elucidate pathogen reservoirs: Lessons from Pseudogymnoascus destructans, the causative agent of white-nose disease in bats

AbstractEmerging infectious diseases pose a major threat to human, animal, and plant health. The risk of species-extinctions increases when pathogens can survive in the absence of the host, for example in environmental reservoirs. However, identifying such reservoirs and modes of infection is often highly challenging. In this study, we investigated the presence and nature of an environmental reservoir for the ascomycete fungus Pseudogymnoascus destructans, the causative agent of white-nose disease. We also characterised the modes and timing of transmission of the pathogen; key elements to better understand the disease dynamics. Using 18 microsatellite markers, we determined the genotypic and genic (based on allele frequencies) differentiation between 1,497 P. destructans isolates collected from nine closely situated hibernacula in North-Eastern Germany. One hibernaculum was the focus of intensive sampling in which both the bats and walls of the site were sampled at regular intervals over five consecutive winter seasons (1,062 isolates). We found significant genic differentiation between sites and few multi-locus genotypes shared across hibernacula (genotypic differentiation). This demonstrates that each hibernaculum has an essentially unique population of the fungus. This would be expected if bats purge viable P. destructans over the summer, preventing the mixing and exchange of the pathogen in maternity colonies, where bats from all of the studied hibernacula meet. Results from the intensively sampled site show higher measures of genotypic richness on walls compared to bats, the absence of genic differentiation between bats and walls, and stable relative abundance of multi-locus genotypes over multiple winter seasons. This clearly implicates hibernacula walls as the main environmental reservoir of the pathogen, from which bats become re-infected annually.