Emergent infectious diseases are a major driver of the accelerated rates of biodiversity loss that are being documented around the world. Global losses of amphibians provide evidence of this, especially those associated with chytridiomycosis, a lethal skin disease caused by the fungus Batrachochytrium dendrobatidis (Bd). Amphibian skin can harbor diverse bacterial communities that, in some cases, can inhibit the growth of Bd. Thus, there is interest in using skin bacteria as probiotics to mitigate Bd infections in amphibians. However, experiments testing this conservation approach have yielded mixed results, suggesting a lack of understanding about the ecology of these microbial communities. My dissertation research aimed to assess basic ecological questions in microbial ecology and to contribute to the development of probiotics using amphibian skin bacteria. First, to assess whether environmental conditions influence the function of amphibian skin bacterial communities, I conducted a field survey across low and high elevation populations of an amphibian host to assess their skin bacterial communities and metabolite profiles. I found that similar bacterial communities produced different metabolites at different locations, implying a potential functional plasticity. Second, since culturing is critical for characterizing bacteria, I aimed to identify the culture media (low vs high nutrient concentration) that recovers the most representative fraction of the amphibian skin bacterial community. I found that media with low nutrient concentrations cultured a higher diversity and recovered a more representative fraction of the diversity occurring on amphibian skin. I also determined that sampling more individuals is critical to maximize culture collections. Third, I assessed the diversity of the amphibian skin fungal community in relation to Bd infection across eight amphibian species. I determined that amphibian species was the most important predictor of fungal diversity and community structure, and that Bd infection did not have a strong impact. My dissertation highlights the importance of environmental conditions in the function of amphibian skin bacteria, expands our knowledge of the understudied fungal component of the amphibian skin microbiome, and complements current efforts in amphibian conservation. / Ph. D. / In light of the global losses of amphibian diversity due to, in part, the skin disease chytridiomycosis (caused by the fungus Batrachochytrium dendrobatidis [Bd]); the discovery that some amphibian-skin bacteria can inhibit Bd growth provides hope for amphibian conservation via their use as probiotics to control Bd infections. However, experiments testing these bacteria have yielded inconsistent results, suggesting a limited understanding about the factors influencing the diversity of amphibian-skin microbes and their ability to inhibit Bd. Also, efforts to identify effective candidates for probiotic therapy are still premature. Thus, my dissertation had an ecological emphasis and focused on complementing conservation efforts focused on probiotics. First, I assessed whether environmental conditions influence bacteriallyproduced products, which can have antifungal properties. Specifically, I surveyed low and highelevation populations of an amphibian species to assess the skin-bacteria and their products. I determined that, while skin bacterial communities were similar across an environmental gradient, their products differed, suggesting potential different antifungal properties. Second, I assessed the ability of different culture media types (low vs high nutrient concentrations) to grow a high portion and most representative fraction of the amphibian-skin bacteria. I found that culture media with low nutrient concentrations allowed the growth of a higher diversity of the bacteria occurring on the amphibian-skin, including the abundant members, and also determined that including a large number of amphibians is the best way to improve culture collections. Third, I assessed the fungal diversity occurring in the skin of different amphibian species and how it might response to Bd infections, and examined whether skin-fungi interact with co-occurring bacteria. I found that the amphibian species was the most important driver of the fungal diversity, and that Bd infection did not influence the diversity of these communities. Moreover, I identified the most diverse fungal phyla occurring in the amphibian-skin and determined that these fungi might interact with co-occurring bacteria. My dissertation contributes to our understanding about the influence of the environmental conditions in the amphibian-skin bacteria, expands our limited knowledge on the amphibian-skin fungi, and complement current amphibian conservation efforts.
Identifer | oai:union.ndltd.org:VTETD/oai:vtechworks.lib.vt.edu:10919/84855 |
Date | 17 August 2018 |
Creators | Medina Lopez, Daniel Christofer |
Contributors | Biological Sciences, Belden, Lisa K., Hawley, Dana M., Walters, Jeffrey R., Badgley, Brian D. |
Publisher | Virginia Tech |
Source Sets | Virginia Tech Theses and Dissertation |
Detected Language | English |
Type | Dissertation |
Format | ETD, application/pdf, application/pdf, application/pdf |
Rights | In Copyright, http://rightsstatements.org/vocab/InC/1.0/ |
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