Abstract
BackgroundThe skin microbiome serves as a first line defense against pathogens in vertebrates. In amphibians, it has the potential to protect against the chytrid fungus Batrachochytrium dendrobatis (Bd), a likely agent of amphibian declines. Alteration of the microbiome associated with unfavorable environmental changes produced by anthropogenic activities may make the host more susceptible to pathogens. Some amphibian species that were thought to be “extinct” have been rediscovered years after population declines in the late 1980s probably due to evolved Bd-resistance and are now threatened by anthropogenic land-use changes. Understanding the effects of habitat disturbance on the host skin microbiome is relevant for understanding the health of these species, along with its susceptibility to pathogens such as Bd. Here, we investigate the influence of habitat alteration on the skin bacterial communities as well as specifically the putative Bd-inhibitory bacterial communities of the montane frog Lithobates vibicarius. This species, after years of not being observed, was rediscovered in small populations inhabiting undisturbed and disturbed landscapes, and with continuous presence of Bd.ResultsWe found that cutaneous bacterial communities of tadpoles and adults differed between undisturbed and disturbed habitats. The adults from disturbed habitats exhibited greater community dispersion than those from undisturbed habitats. We observed a higher richness of putative Bd-inhibitory bacterial strains in adults from disturbed habitats than in those from undisturbed habitats, as well as a greater number of these potential protective bacteria with a high relative abundance.ConclusionsOur findings support the microbial “Anna Karenina principle”, in which disturbance is hypothesized to cause greater microbial dispersion in communities, a so-called dysbiosis, which is a response of animal microbiomes to stress factors that decrease the ability of the host or its microbiome to regulate community composition. On the positive side, the high richness and relative abundance of putative Bd-inhibitory bacteria may indicate the development of a defense mechanism that enhances Bd-protection, attributed to a co-occurrence of more than 30-years of host and pathogen in these disturbed habitats. Our results provide important insight into the influence of human-modified landscapes on the skin microbiome and health implications of Bd-survivor species.
Highlights
The skin microbiome serves as a first line defense against pathogens in vertebrates
The skin microbiome of frog samples from undisturbed and disturbed habitats were used for investigating the influence of habitat disturbance on the skin bacterial communities in tadpoles and adults of L. vibicarius
Skin bacterial alpha and beta diversity in tadpoles and adults of Lithobates vibicarius between undisturbed and disturbed habitats Habitat type explained significant variation in the number of observed Amplicon sequence variant (ASV) (χ2 = 6.54, p = 0.01) and the Shannon diversity (χ2 = 6.83, p = 0.008) in tadpoles (Additional file 2: Table S2). Both measures of alpha diversity were higher in undisturbed habitats than in disturbed habitats (number of observed ASVs: odds ratio (OR) = 1.36, 95% confidence intervals not overlapping 1, Shannon diversity: OR = 1.16, 95% CI not overlapping 1, Additional file 2: Fig. S1A-B)
Summary
The skin microbiome serves as a first line defense against pathogens in vertebrates. In amphibians, it has the potential to protect against the chytrid fungus Batrachochytrium dendrobatis (Bd), a likely agent of amphibian declines. We investigate the influence of habitat alteration on the skin bacterial communities as well as the putative Bd-inhibitory bacterial communities of the montane frog Lithobates vibicarius This species, after years of not being observed, was rediscovered in small populations inhabiting undisturbed and disturbed landscapes, and with continuous presence of Bd. All vertebrates are hosts to numerous symbiotic microorganisms that reside on their skin [1, 2]. Dysbiosis caused by adverse factors can disrupt the performance benefits of hostassociated microbiota and may contribute to unwanted collateral damage to hosts [7] This means that it can threaten the survival of individuals and the growth of populations due to a cascade of negative health effects [10,11,12,13]. Several recent studies have documented how skin and gut microbiomes from different wildlife species can be sensitive to habitat fragmentation and contaminants attributed to human activities [14,15,16,17,18]
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