Abstract
The emerging fungal pathogen, Batrachochytrium dendrobatidis (Bd), which can cause a fatal disease called chytridiomycosis, is implicated in the collapse of hundreds of host amphibian species. We describe chytridiomycosis dynamics in two co-occurring terrestrial salamander species, the Santa Lucia Mountains slender salamander, Batrachoseps luciae, and the arboreal salamander, Aneides lugubris. We (1) conduct a retrospective Bd-infection survey of specimens collected over the last century, (2) estimate present-day Bd infections in wild populations, (3) use generalized linear models (GLM) to identify biotic and abiotic correlates of infection risk, (4) investigate susceptibility of hosts exposed to Bd in laboratory trials, and (5) examine the ability of host skin bacteria to inhibit Bd in culture. Our historical survey of 2,866 specimens revealed that for most of the early 20th century (~1920–1969), Bd was not detected in either species. By the 1990s the proportion of infected specimens was 29 and 17% (B. luciae and A. lugubris, respectively), and in the 2010s it was 10 and 17%. This was similar to the number of infected samples from contemporary populations (2014–2015) at 10 and 18%. We found that both hosts experience signs of chytridiomycosis and suffered high Bd-caused mortality (88 and 71% for B. luciae and A. lugubris, respectively). Our GLM revealed that Bd-infection probability was positively correlated with intraspecific group size and proximity to heterospecifics but not to abiotic factors such as precipitation, minimum temperature, maximum temperature, mean temperature, and elevation, or to the size of the hosts. Finally, we found that both host species contain symbiotic skin-bacteria that inhibit growth of Bd in laboratory trials. Our results provide new evidence consistent with other studies showing a relatively recent Bd invasion of amphibian host populations in western North America and suggest that the spread of the pathogen may be enabled both through conspecific and heterospecific host interactions. Our results suggest that wildlife disease studies should assess host-pathogen dynamics that consider the interactions and effects of multiple hosts, as well as the historical context of pathogen invasion, establishment, and epizootic to enzootic transitions to better understand and predict disease dynamics.
Highlights
Amphibians are an ancient and diverse lineage of vertebrates [∼370 mya; currently 8,345 species; [1, 2]] that have survived the last four global mass extinction events [3,4,5]
When we compared the Batrachochytrium dendrobatidis (Bd) prevalence from the decade with the highest prevalence (1990s for both species) in the museum specimens to the prevalence in contemporary field samples, we found that Bd prevalence had decreased significantly from 29.23 to 9.87% in B. luciae (p < 0.01; X2 = 18.8), but showed no significant difference in A. lugubris (16.92% compared to 18.18%; p = 0.87; X2 = 0.03)
The results from our 90-year retrospective museum study suggest that Bd emerged in B. luciae and A. lugubris in the late 1960s and early 1970s, with prevalence and infection intensity steadily increasing into the 1990s
Summary
Amphibians are an ancient and diverse lineage of vertebrates [∼370 mya; currently 8,345 species; [1, 2]] that have survived the last four global mass extinction events [3,4,5]. An emerging infectious fungal disease, chytridiomycosis, has captured the attention of biologists and the general public because it has driven die-offs in hundreds of amphibian species around the world [3, 9,10,11,12,13]. This disease is caused by the chytridiomycete fungi, Batrachochytrium dendrobatidis (Bd) [14] and Batrachochytrium salamandrivorans (Bsal) [15], which infect and disrupt skin function, including osmoregulation, and can lead to death [15,16,17,18]. To predict the effects that Bd chytridiomycosis will continue to have on host species, it is essential to understand longitudinal patterns of Bd infection prevalence [e.g., temporal pattern of pathogen invasion, epizootic outbreak, and either establishment or loss; [19, 20]], host species susceptibility patterns (influenced by skin microbiomes, social behavior and interactions with heterospecifics), and host-Bd dynamics so that models can be used to understand and predict the interactions across a wide range of circumstances [20]
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