Public health concerns about recent viral epidemics have motivated researchers to seek novel ways to understand pathogen infection in native, wildlife hosts. With its deep history of tools and perspectives for understanding the abundance and distribution of organisms, ecology can shed new light on viral infection dynamics. However, datasets allowing deep explorations of viral communities from an ecological perspective are lacking. We sampled 1,086 bats from two, adjacent Puerto Rican caves and tested them for infection by herpesviruses, resulting in 3,131 short, viral sequences. Using percent identity of nucleotides and a machine learning algorithm (affinity propagation), we categorized herpesviruses into 43 operational taxonomic units (OTUs), to be used in place of species in subsequent ecological analyses. Herpesvirus metacommunities demonstrated long-tailed rank frequency distributions at all analyzed levels of host organization (i.e., individual, population, and community). Although 13 herpesvirus OTUs were detected in more than one host species, OTUs generally exhibited host specificity by infecting a single core host species at a significantly higher prevalence than in all satellite species combined. We describes the natural history of herpesvirus metacommunities in Puerto Rican bats and suggest that viruses follow the general law that communities comprise few common and many rare species. To guide future efforts in the field of viral ecology, hypotheses are presented regarding mechanisms that contribute to these patterns.

Ecologists are increasingly interested in the deterministic factors that influence microbial communities. Yet in comparison to other microbes, our understanding of viral community ecology is limited. Here we investigated the factors influencing the community ecology of picobirnaviruses among wild rhesus macaques (Macaca mulatta) in Bangladesh. Using co-occurrence networks and species distribution models, we found that macaques’ social organisation and anthropogenic factors (human and livestock densities) had the greatest impact on picobirnavirus communities. Virus phylogenetic relationships, host demographics (sex, age), and host physiological stress (cortisol levels) had less of an impact. We also found a few significant biotic virus-virus associations that impacted community composition, more so at lower host social organisational levels (individual macaques within groups) compared to higher levels (macaque groups within sites). These findings advance our understanding of the deterministic factors shaping viral communities, and contribute to changing perceptions of viruses as embedded components of human-natural ecosystems.