Browsing by Author "DePue, John E."
Now showing 1 - 3 of 3
Results Per Page
Sort Options
- Continued preference for suboptimal habitat reduces bat survival with white-nose syndromeHopkins, Skylar R.; Hoyt, Joseph R.; White, J. Paul; Kaarakka, Heather M.; Redell, Jennifer A.; DePue, John E.; Scullon, William H.; Kilpatrick, A. Marm; Langwig, Kate E. (Springer Nature, 2021)Habitat alteration can influence suitability, creating ecological traps where habitat preference and fitness are mismatched. Despite their importance, ecological traps are notoriously difficult to identify and their impact on host–pathogen dynamics remains largely unexplored. Here we assess individual bat survival and habitat preferences in the midwestern United States before, during, and after the invasion of the fungal pathogen that causes white-nose syndrome. Despite strong selection pressures, most hosts continued to select habitats where disease severity was highest and survival was lowest, causing continued population declines. However, some individuals used refugia where survival was higher. Over time, a higher proportion of the total population used refugia than before pathogen arrival. Our results demonstrate that host preferences for habitats with high disease-induced mortality can create ecological traps that threaten populations, even in the presence of accessible refugia.
- Mobility and infectiousness in the spatial spread of an emerging fungal pathogenLangwig, Kate E.; White, J. Paul; Parise, Katy L.; Kaarakka, Heather M.; Redell, Jennifer A.; DePue, John E.; Scullon, William H.; Foster, Jeffrey T.; Kilpatrick, A. Marm; Hoyt, Joseph R. (2021-05)Emerging infectious diseases can have devastating effects on host communities, causing population collapse and species extinctions. The timing of novel pathogen arrival into naive species communities can have consequential effects that shape the trajectory of epidemics through populations. Pathogen introductions are often presumed to occur when hosts are highly mobile. However, spread patterns can be influenced by a multitude of other factors including host body condition and infectiousness. White-nose syndrome (WNS) is a seasonal emerging infectious disease of bats, which is caused by the fungal pathogen Pseudogymnoascus destructans. Within-site transmission of P. destructans primarily occurs over winter; however, the influence of bat mobility and infectiousness on the seasonal timing of pathogen spread to new populations is unknown. We combined data on host population dynamics and pathogen transmission from 22 bat communities to investigate the timing of pathogen arrival and the consequences of varying pathogen arrival times on disease impacts. We found that midwinter arrival of the fungus predominated spread patterns, suggesting that bats were most likely to spread P. destructans when they are highly infectious, but have reduced mobility. In communities where P. destructans was detected in early winter, one species suffered higher fungal burdens and experienced more severe declines than at sites where the pathogen was detected later in the winter, suggesting that the timing of pathogen introduction had consequential effects for some bat communities. We also found evidence of source-sink population dynamics over winter, suggesting some movement among sites occurs during hibernation, even though bats at northern latitudes were thought to be fairly immobile during this period. Winter emergence behaviour symptomatic of white-nose syndrome may further exacerbate these winter bat movements to uninfected areas. Our results suggest that low infectiousness during host migration may have reduced the rate of expansion of this deadly pathogen, and that elevated infectiousness during winter plays a key role in seasonal transmission. Furthermore, our results highlight the importance of both accurate estimation of the timing of pathogen spread and the consequences of varying arrival times to prevent and mitigate the effects of infectious diseases.
- Reducing environmentally mediated transmission to moderate impacts of an emerging wildlife diseaseHoyt, Joseph R.; Parise, Katy L.; DePue, John E.; Kaarakka, Heather M.; Redell, Jennifer A.; Scullon, William H.; O'Reskie, Rich; Foster, Jeffrey T.; Kilpatrick, A. Marm; Langwig, Kate E.; White, J. Paul (Wiley, 2023-05)Emerging infectious diseases have caused population declines and biodiversity loss. The ability of pathogens to survive in the environment, independent of their host, can exacerbate disease impacts and increase the likelihood of species extinction. Control of pathogens with environmental stages remains a significant challenge for conservation and effective management strategies are urgently needed.We examined the effectiveness of managing environmental exposure to reduce the impacts of an emerging infectious disease of bats, white-nose syndrome (WNS). We used a chemical disinfectant, chlorine dioxide (ClO2), to experimentally reduce Pseudogymnoascus destructans, the fungal pathogen causing WNS, in the environment. We combined laboratory experiments with 3 years of field trials at four abandoned mines to determine whether ClO2 could effectively remove P. destructans from the environment, reduce host infection and limit population impacts.ClO2 was effective at killing P. destructans in vitro across multiple concentrations. In field settings, higher concentrations of ClO2 treatment were needed to sufficiently reduce viable P. destructans conidia in the environment.The reduction in the environmental reservoir at treatment sites resulted in lower fungal loads on bats compared to untreated control populations. Survival following treatment was also higher in little brown bats (Myotis lucifugus), and trended higher for tricolored bats (Perimyotis subflavus).Synthesis and applications. Our results highlight that targeted management of sources for environmental transmission can be an effective control strategy for wildlife disease. We found that successfully reducing pathogen in the environment decreased disease severity and increased survival, but required higher treatment exposure than was effective in laboratory experiments, and the effects varied among species. More broadly, our findings have implications for other emerging wildlife diseases with free-living pathogen stages by highlighting how the degree of environmental contamination can have cascading impacts on hosts, presenting an opportunity for intervention.