Variation in metal tolerance associated with population exposure history in Southern toads (Anaxyrus terrestris)

•Offspring of parents from a copper (Cu) contaminated site were more tolerant Cu than those from reference sites.•Population exposure history to other metal contaminants was not associated with Cu tolerance.•Cu tolerance not associated with maternal factors, including transfer of metals to eggs or e...

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Bibliographic Details
Published in:Aquatic toxicology 2019-02, Vol.207 (C), p.163-169
Main Authors: Flynn, R. Wesley, Love, Cara N., Coleman, Austin, Lance, Stacey L.
Format: Article
Language:English
Subjects:
Amphibian
Copper
Marine & Freshwater Biology
Maternal transfer
Metal tolerance
Toxicology
Trace element
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Summary:•Offspring of parents from a copper (Cu) contaminated site were more tolerant Cu than those from reference sites.•Population exposure history to other metal contaminants was not associated with Cu tolerance.•Cu tolerance not associated with maternal factors, including transfer of metals to eggs or egg size.•Patterns of tolerance suggestive of adaptation, rather than acclimatization, to a common environmental contaminant. Human activities have radically shaped the global landscape, affecting the structure and function of ecosystems. Habitat loss is one of the most visible changes to the landscape and a primary driver of species declines; however, anthropogenic environmental contamination also threatens population persistence, but is not as readily observed. Aquatic organisms are especially susceptible to chemical perturbations, which can negatively impact survival and fitness related traits. Some populations have evolved tolerance to chemical stressors, which could mitigate the consequences associated with contamination. Amphibians are experiencing global declines due to multiple stressors and are particularly at risk to aquatic chemical stressors due to their permeable skin and reliance on wetlands for reproduction and larval development. However, amphibians also have substantial plasticity in response to environmental variation. We designed our study to examine whether tolerance to heavy metals is greater in Southern toad (Anaxyrus terrestris) larvae from wetlands with a history of contamination. Considering many of the most common trace elements elicit acute toxicity by disrupting osmotic- and ionic-regulation, we hypothesized that alterations to these aspects of physiology resulting from multigenerational exposure to trace element mixtures would be the most likely routes by which tolerance would evolve. We used copper (Cu) as a proxy for heavy metal exposure because it is a widely distributed aquatic stressor known to cause osmotic stress that can also cause mortality at levels commonly encountered in the environment. We found considerable within and among population variation in Cu tolerance, as measured by time to death. Larvae from populations living in sites contaminated with mixtures of heavy metals associated with coal fly ash were no more tolerant to Cu than those from reference sites. However, larvae from a population inhabiting a constructed wetland complex with high Cu levels were significantly more tolerant; having half the risk of mortality
ISSN:0166-445X
1879-1514
DOI:10.1016/j.aquatox.2018.12.009