Cryptic connections illuminate pathogen transmission within community networks

Authors

Joseph R. Hoyt, University of California, Santa Cruz
Kate E. Langwig, Virginia Polytechnic Institute and State University
J. Paul White, Wisconsin Department Natural Resources
Heather M. Kaarakka, Wisconsin Department Natural Resources
Jennifer A. Redell, Wisconsin Department Natural Resources
Allen Kurta, Eastern Michigan University
John E. DePue, State of Michigan
William H. Scullon, State of Michigan
Katy L. Parise, University of New Hampshire Durham
Jeffrey T. Foster, University of New Hampshire Durham
Winifred F. Frick, University of California, Santa Cruz
A. Marm Kilpatrick, University of California, Santa Cruz

Document Type

Article

Publication Date

2018

Department/School

Biology

Publication Title

Nature

Abstract

Understanding host interactions that lead to pathogen transmission is fundamental to the prediction and control of epidemics1–5. Although the majority of transmissions often occurs within social groups6–9, the contribution of connections that bridge groups and species to pathogen dynamics is poorly understood10–12. These cryptic connections—which are often indirect or infrequent—provide transmission routes between otherwise disconnected individuals and may have a key role in large-scale outbreaks that span multiple populations or species. Here we quantify the importance of cryptic connections in disease dynamics by simultaneously characterizing social networks and tracing transmission dynamics of surrogate-pathogen epidemics through eight communities of bats. We then compared these data to the invasion of the fungal pathogen that causes white-nose syndrome, a recently emerged disease that is devastating North American bat populations13–15. We found that cryptic connections increased links between individuals and between species by an order of magnitude. Individuals were connected, on average, to less than two per cent of the population through direct contact and to only six per cent through shared groups. However, tracing surrogate-pathogen dynamics showed that each individual was connected to nearly fifteen per cent of the population, and revealed widespread transmission between solitarily roosting individuals as well as extensive contacts among species. Connections estimated from surrogate-pathogen epidemics, which include cryptic connections, explained three times as much variation in the transmission of the fungus that causes white-nose syndrome as did connections based on shared groups. These findings show how cryptic connections facilitate the community-wide spread of pathogens and can lead to explosive epidemics.

Link to Published Version

10.1038/s41586-018-0720-z

Recommended Citation

Hoyt, J. R., Langwig, K. E., White, J. P., Kaarakka, H. M., Redell, J. A., Kurta, A., DePue, J. E., Scullon, W. H., Parise, K. L., Foster, J. T., Frick, W. F., & Kilpatrick, A. M. (2018). Cryptic connections illuminate pathogen transmission within community networks. Nature, 563(7733), 710–713. https://doi.org/10.1038/s41586-018-0720-z