Agrochemicals increase trematode infections in a declining amphibian species

Rohr, Jason R.; Schotthoefer, Anna M.; Raffel, Thomas R.; Carrick, Hunter J.; Halstead, Neal T.; Hoverman, Jason T.; Johnson, Catherine M.; Johnson, Lucinda B.; Lieske, Camilla; Piwoni, Marvin D.; Schoff, Patrick K.; Beasley, Val R.

doi:10.1038/nature07281

Cited by 405 publications

(417 citation statements)

References 24 publications

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“…Past amphibian studies have also suggested scenarios that may lead to evolutionary responses to parasites. For example, high‐nutrient agricultural run‐off may indirectly facilitate trematode abundance by increasing the amount of algal resources available to the first intermediate hosts (snails) of trematodes (Koprivnikar & Redfern, 2012; Koprivnikar et al., 2006; Rohr, Schotthoefer, et al., 2008). Higher abundances of Echinoparyphium may select for increased resistance or tolerance to Echinoparyphium in amphibian populations near agriculture.…”

Section: Discussionmentioning

confidence: 99%

Evolved pesticide tolerance influences susceptibility to parasites in amphibians

Hua

Wuerthner

Jones

et al. 2017

Evolutionary Applications

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Because ecosystems throughout the globe are contaminated with pesticides, there is a need to understand how natural populations cope with pesticides and the implications for ecological interactions. From an evolutionary perspective, there is evidence that pesticide tolerance can be achieved via two mechanisms: selection for constitutive tolerance over multiple generations or by inducing tolerance within a single generation via phenotypic plasticity. While both mechanisms can allow organisms to persist in contaminated environments, they might result in different performance trade‐offs including population susceptibility to parasites. We have identified 15 wood frog populations that exist along a gradient from close to agriculture and high, constitutive pesticide tolerance to far from agriculture and inducible pesticide tolerance. Using these populations, we investigated the relationship between evolutionary responses to the common insecticide carbaryl and host susceptibility to the trematode Echinoparyphium lineage 3 and ranavirus using laboratory exposure assays. For Echinoparyphium, we discovered that wood frog populations living closer to agriculture with high, constitutive tolerance experienced lower loads than populations living far from agriculture with inducible pesticide tolerance. For ranavirus, we found no relationship between the mechanism of evolved pesticide tolerance and survival, but populations living closer to agriculture with high, constitutive tolerance experienced higher viral loads than populations far from agriculture with inducible tolerance. Land use and mechanisms of evolved pesticide tolerance were associated with susceptibility to parasites, but the direction of the relationship is dependent on the type of parasite, underscoring the complexity between land use and disease outcomes. Collectively, our results demonstrate that evolved pesticide tolerance can indirectly influence host–parasite interactions and underscores the importance of including evolutionary processes in ecotoxicological studies.

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Section: Discussionmentioning

confidence: 99%

Evolved pesticide tolerance influences susceptibility to parasites in amphibians

Hua

Wuerthner

Jones

et al. 2017

Evolutionary Applications

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“…We suspect that, to thoroughly understand climatic effects on Bd-related declines, investigators will need to explicitly test how climate affects interactions between Bd and amphibian hosts, as well as consider other factors altering host-parasite dynamics or host fitness directly (39,(42)(43)(44). Additionally, the influence of climate on amphibians will almost certainly depend on the local scales at which organisms experience climatic conditions.…”

Section: Discussionmentioning

confidence: 99%

Linking global climate and temperature variability to widespread amphibian declines putatively caused by disease

Rohr

Raffel

2010

Proc. Natl. Acad. Sci. U.S.A.

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The role of global climate change in the decline of biodiversity and the emergence of infectious diseases remains controversial, and the effect of climatic variability, in particular, has largely been ignored. For instance, it was recently revealed that the proposed link between climate change and widespread amphibian declines, putatively caused by the chytrid fungus Batrachochytrium dendrobatidis ( Bd ), was tenuous because it was based on a temporally confounded correlation. Here we provide temporally unconfounded evidence that global El Niño climatic events drive widespread amphibian losses in genus Atelopus via increased regional temperature variability, which can reduce amphibian defenses against pathogens. Of 26 climate variables tested, only factors associated with temperature variability could account for the spatiotemporal patterns of declines thought to be associated with Bd . Climatic predictors of declines became significant only after controlling for a pattern consistent with epidemic spread (by temporally detrending the data). This presumed spread accounted for 59% of the temporal variation in amphibian losses, whereas El Niño accounted for 59% of the remaining variation. Hence, we could account for 83% of the variation in declines with these two variables alone. Given that global climate change seems to increase temperature variability, extreme climatic events, and the strength of Central Pacific El Niño episodes, climate change might exacerbate worldwide enigmatic declines of amphibians, presumably by increasing susceptibility to disease. These results suggest that changes to temperature variability associated with climate change might be as significant to biodiversity losses and disease emergence as changes to mean temperature.

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“…Pesticides have the potential to increase susceptibility (Mann et al, 2009) while elevated nutrient concentrations have the potential to increase the incidence of disease in amphibian populations (Johnson et al, 2007). On the other hand, studies have documented the relationship between pesticides and susceptibility to infections by trematodes (Rohr et al, 2008). These parasitic infections have the potential to negatively impact populations causing malformations (Reeves et al, 2013) which can lead to impaired mobility, decreased food intake, and an increased susceptibility to predators (Blaustein and Johnson, 2003).…”

Section: Potential Impacts To Amphibiansmentioning

confidence: 99%

“…Increased eutrophication due to nitrogen based fertilizers, coupled with pesticide application, may cause trophic cascades resulting in increased rates of parasitism in wetlands and has been linked to immunosuppression in amphibians (Brodkin et al, 2007;Johnson et al, 2007). Although a direct link has been made between pesticide exposure and infection by trematodes (Rohr et al, 2008;Kiesecker, 2002), a general understanding of these interactions in the field is lacking because results vary by species and land-use (King et al, 2007).…”

Section: Introductionmentioning

confidence: 99%

Pesticide concentrations in frog tissue and wetland habitats in a landscape dominated by agriculture

Smalling

Reeves

Muths

et al. 2015

Science of The Total Environment

121

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Habitat loss and exposure to pesticides are likely primary factors contributing to amphibian decline in agricultural landscapes. Conservation efforts have attempted to restore wetlands lost through landscape modifications to reduce contaminant loads in surface waters and providing quality habitat to wildlife. The benefits of this increased wetland area, perhaps especially for amphibians, may be negated if habitat quality is insufficient to support persistent populations. We examined the presence of pesticides and nutrients in water and sediment as indicators of habitat quality and assessed the bioaccumulation of pesticides in the tissue of twonative amphibian species Pseudacris maculata (chorus frogs) and Lithobates pipiens (leopard frogs) at six wetlands (3 restored and 3 reference) in Iowa, USA. Restored wetlands are positioned on the landscape to receive subsurface tile drainage water while referencewetlands receive water fromoverland run-off and shallow groundwater sources. Concentrations of the pesticides frequently detected inwater and sediment samples were not different between wetland types. The median concentration of atrazine in surface water was 0.2 μg/ L. Reproductive abnormalities in leopard frogs have been observed in other studies at these concentrations. Nutrient concentrations were higher in the restored wetlands but lower than concentrations thought lethal to frogs. Complex mixtures of pesticides including up to 8 fungicides, some previously unreported in tissue, were detected with concentrations ranging from 0.08 to 1500 μg/kg wet weight. No significant differences in pesticide concentrations were observed between species, although concentrations tended to be higher in leopard frogs compared to chorus frogs, possibly because of differences in life histories. Our results provide information on habitat quality in restored wetlands that will assist state and federal agencies, landowners, and resource managers in identifying and implementing conservation and management actions for these and similar wetlands in agriculturally dominated landscapes. RightsWorks produced by employees of the U.S. Government as part of their official duties are not copyrighted within the U.S. The content of this document is not copyrighted. H I G H L I G H T S• Habitat quality was similar between restored and reference wetlands in Iowa.• Complex mixtures of pesticides are detected in frog tissues (liver and whole body).• The number of fungicides (up to 8) in frog tissues is largest reported to date.• Life history has the potential to impact pesticide bioaccumulation in frogs. Habitat loss and exposure to pesticides are likely primary factors contributing to amphibian decline in agricultural landscapes. Conservation efforts have attempted to restore wetlands lost through landscape modifications to reduce contaminant loads in surface waters and providing quality habitat to wildlife. The benefits of this increased wetland area, perhaps especially for amphibians, may be negated if habitat quality is insufficient t...

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Agrochemicals increase trematode infections in a declining amphibian species

Cited by 405 publications

References 24 publications

Evolved pesticide tolerance influences susceptibility to parasites in amphibians

Evolved pesticide tolerance influences susceptibility to parasites in amphibians

Linking global climate and temperature variability to widespread amphibian declines putatively caused by disease

Pesticide concentrations in frog tissue and wetland habitats in a landscape dominated by agriculture

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