Population genetic structure and disease in montane boreal toads: more heterozygous individuals are more likely to be infected with amphibian chytrid

Addis, Brett R.; Lowe, Winsor H.; Hossack, Blake R.; Allendorf, Fred W.

doi:10.1007/s10592-015-0704-6

Cited by 21 publications

(18 citation statements)

References 81 publications

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“…The global impacts of chytridiomycosis (Skerratt et al 2007) coupled with local extirpations and differential susceptibility of amphibian populations (Schloegel et al 2006, Murphy et al 2009), make identifying the factors that lead to extinction a conservation priority (Wilber et al 2017). Geographic isolation of populations, host species community richness, variation in climate, and habitat differences across sites have all been suggested to influence amphibian-Bd dynamics (Searle et al 2011, Heard et al 2013, Addis et al 2015, Clare et al 2016. Assessing the relative contributions of these factors to host-pathogen dynamics will improve our ability to successfully manage landscapes, species, and populations challenged by chytridiomycosis (Venesky et al 2014b, Garner et al 2016.…”

Section: Introductionmentioning

confidence: 99%

Host–pathogen metapopulation dynamics suggest high elevation refugia for boreal toads

Mosher

Bailey

Muths

et al. 2018

Ecological Applications

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Emerging infectious diseases are an increasingly common threat to wildlife. Chytridiomycosis, caused by the fungal pathogen Batrachochytrium dendrobatidis (Bd), is an emerging infectious disease that has been linked to amphibian declines around the world. Few studies exist that explore amphibian-Bd dynamics at the landscape scale, limiting our ability to identify which factors are associated with variation in population susceptibility and to develop effective in situ disease management. Declines of boreal toads (Anaxyrus boreas boreas) in the southern Rocky Mountains are largely attributed to chytridiomycosis but variation exists in local extinction of boreal toads across this metapopulation. Using a large-scale historic data set, we explored several potential factors influencing disease dynamics in the boreal toad-Bd system: geographic isolation of populations, amphibian community richness, elevational differences, and habitat permanence. We found evidence that boreal toad extinction risk was lowest at high elevations where temperatures may be suboptimal for Bd growth and where small boreal toad populations may be below the threshold needed for efficient pathogen transmission. In addition, boreal toads were more likely to recolonize high elevation sites after local extinction, again suggesting that high elevations may provide refuge from disease for boreal toads. We illustrate a modeling framework that will be useful to natural resource managers striving to make decisions in amphibian-Bd systems. Our data suggest that in the southern Rocky Mountains high elevation sites should be prioritized for conservation initiatives like reintroductions.

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Section: Introductionmentioning

confidence: 99%

Host–pathogen metapopulation dynamics suggest high elevation refugia for boreal toads

Mosher

Bailey

Muths

et al. 2018

Ecological Applications

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“…Landscape genetic clustering and assignment methods have largely built upon classical methods from population genetics (e.g., principal components analysis, STRUCTURE, Pritchard, Stephens, & Donnelly, ) by incorporating spatial information (e.g., GENELAND, Guillot, Mortier, & Estoup, ; sPCA, Jombart, Devillard, Dufour, & Pontier, ) and environmental heterogeneity (e.g., constrained ordination, Anderson & Willis, ; POPS, Jay, ) into estimates of population structure and providing quantitative estimates of ancestry for each individual (François & Waits, ). Clustering methods have been relatively popular in studying pathogens and implemented for the inference of landscape barriers affecting both host (Addis, Lowe, Hossack, & Allendorf, ; Cote, Garant, Robert, Mainguy, & Pelletier, ; Cullingham, Kyle, Pond, Rees, & White, ; Frantz, Cellina, Krier, Schley, & Burke, ) and microparasite (Brar et al., ; Rieux et al., ) spatial genetic variation. Edge detection methods, such as Monmonier's maximum difference algorithm, (Monmonier, ) have also been used to detect landscape barriers to transmission in pathogen studies (Carrel et al., ; Joannon et al., ).…”

Section: Common Methodological Approaches In Landscape Genetics and Tmentioning

confidence: 99%

Pathogens in space: Advancing understanding of pathogen dynamics and disease ecology through landscape genetics

Kozakiewicz

Burridge

Funk

et al. 2018

Evolutionary Applications

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Landscape genetics has provided many insights into how heterogeneous landscape features drive processes influencing spatial genetic variation in free‐living organisms. This rapidly developing field has focused heavily on vertebrates, and expansion of this scope to the study of infectious diseases holds great potential for landscape geneticists and disease ecologists alike. The potential application of landscape genetics to infectious agents has garnered attention at formative stages in the development of landscape genetics, but systematic examination is lacking. We comprehensively review how landscape genetics is being used to better understand pathogen dynamics. We characterize the field and evaluate the types of questions addressed, approaches used and systems studied. We also review the now established landscape genetic methods and their realized and potential applications to disease ecology. Lastly, we identify emerging frontiers in the landscape genetic study of infectious agents, including recent phylogeographic approaches and frameworks for studying complex multihost and host‐vector systems. Our review emphasizes the expanding utility of landscape genetic methods available for elucidating key pathogen dynamics (particularly transmission and spread) and also how landscape genetic studies of pathogens can provide insight into host population dynamics. Through this review, we convey how increasing awareness of the complementarity of landscape genetics and disease ecology among practitioners of each field promises to drive important cross‐disciplinary advances.

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“…Our study capitalised on a unique opportunity for contrasting such populations, but we acknowledge that the number of unexposed sites is very low (only two such populations are known for this species), and the environmental factors that have kept them isolated from Bd exposure (low connectivity) may also influence levels of genetic diversity in those populations, as in a previous study of corroboree frogs (Pseudophryne corroboree, Pseudophryne pengilleyi) and boreal toads (Anaxyrus boreas) (Addis et al 2015, Morgan et al 2008. Indeed, the two populations where Bd was absent at the time of sampling were the only populations with no evidence of any admixture with other sampled populations (Figure 3).…”

Section: Genetic Diversity Of Bd-exposed Versus Unexposed Populationsmentioning

confidence: 99%

“…The few studies that have investigated the genetic impacts of chytridiomycosis on amphibian populations have yielded diverse and sometimes contrasting results for genetic diversity at the individual and population levels (Addis et al 2015, Luquet et al 2012, Savage and Zamudio 2011, Wagner et al 2017. For example, in lowland leopard frogs (Lithobates yavapaiensis) higher heterozygosity is associated with lower risk of Bd-associated mortality (Savage et al 2015).…”

Section: Introductionmentioning

confidence: 99%

“…For example, in lowland leopard frogs (Lithobates yavapaiensis) higher heterozygosity is associated with lower risk of Bd-associated mortality (Savage et al 2015). In contrast, in boreal toads (Bufo boreas) more heterozygous individuals had increased risk of Bd infection (Addis et al 2015). Variable species responses likely reflect that chytridiomycosis influences the demography and ecology of amphibian species in diverse ways, potentially leading to different genetic impacts, and different opportunities for evolutionary responses.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Chytrid fungus infection in alpine tree frogs is associated with individual heterozygosity and population isolation but not population-genetic diversity

Banks¹,

Scheele²,

Macris³

et al. 2020

Frontiers of Biogeography

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Population genetic structure and disease in montane boreal toads: more heterozygous individuals are more likely to be infected with amphibian chytrid

Cited by 21 publications

References 81 publications

Host–pathogen metapopulation dynamics suggest high elevation refugia for boreal toads

Host–pathogen metapopulation dynamics suggest high elevation refugia for boreal toads

Pathogens in space: Advancing understanding of pathogen dynamics and disease ecology through landscape genetics

Chytrid fungus infection in alpine tree frogs is associated with individual heterozygosity and population isolation but not population-genetic diversity

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