Per/polyfluoroalkyl
substances (PFASs) are persistent organic contaminants
that are ubiquitous in surface waters. To date, their effects on aquatic
systems, especially amphibians, are poorly understood. We examined
the uptake and depuration of perfluorooctanesulfonate (PFOS), perfluorohexanesulfonate
(PFHxS), perfluorooctanoic acid (PFOA), and 6:2 fluorotelomer sulfonate
(6:2 FTS) in northern leopard frog (Rana pipiens) tadpoles. Whole-body concentrations were examined every 10 d during
constant aqueous exposure to targeted concentrations of 10, 100, and
1000 μg/L for 40 d and for 30 d during depuration. Effects of
PFAS exposure on length and development were also examined. Rapid
uptake led to steady state concentrations by 10 d for most exposures.
PFOS accumulated to the highest levels with whole-body bioconcentration
factor (BCF) values at 40 d ranging from 19.6 to 119.3. The remaining
PFASs were not found to bioconcentrate (BCF < 1.0 at 40 d). Furthermore,
some BCF values decreased during the exposure phase, suggesting dilution
due to growth and/or changes in toxicokinetics over ontogeny. During
depuration, half-lives ranged from 1.2 to 3.3 d for all compounds.
All PFASs tended to induce developmental delays, though statistical
significance was only seen for PFOS and PFHxS. These sublethal effects
observed at environmentally relevant concentrations are concerning
and merit further study.
Life‐history tradeoffs are common across taxa, but growth‐survival tradeoffs—usually enhancing survival at a cost to growth—are less frequently investigated. Increased salinity (NaCl) is a prevalent anthropogenic disturbance that may cause a growth‐survival tradeoff for larval amphibians. Although physiological mechanisms mediating tradeoffs are seldom investigated, hormones are prime candidates. Corticosterone (CORT) is a steroid hormone that independently influences survival and growth and may provide mechanistic insight into growth‐survival tradeoffs. We conducted a 24‐day experiment to test effects of salinity (<32–4000 mg/L) on growth, development, survival, CORT responses, and tradeoffs among traits of larval Northern Leopard Frogs (Rana pipiens). We also experimentally suppressed CORT signaling to determine whether CORT signaling mediates effects of salinity and a growth‐survival tradeoff. Increased salinity reduced survival, growth, and development. Suppressing CORT signaling in conjunction with salinity reduced survival further but also attenuated the negative effects of salinity on growth, development, and water content. CORT of control larvae increased or was stable with growth and development but decreased with growth and development for those exposed to salinity. Therefore, salinity dysregulated CORT physiology. Across all treatments, larvae that survived had higher CORT than larvae that died. By manipulating CORT signaling, we provide strong evidence that CORT physiology mediates the outcome of a growth‐survival tradeoff and enhances survival. To our knowledge, this is the first study to concomitantly measure tradeoffs between growth and survival and experimentally link these changes to CORT physiology. Identifying mechanistic links between stressors and fitness‐related outcomes is critical to enhance our understanding of tradeoffs.
A fundamental goal of disease ecology is to determine the landscape and environmental processes that drive disease dynamics at different biological levels to guide management and conservation. Although ranaviruses (family ) are emerging amphibian pathogens, few studies have conducted comprehensive field surveys to assess potential drivers of ranavirus disease dynamics.We examined the factors underlying patterns in site-level ranavirus presence and individual-level ranavirus infection in 76 ponds and 1,088 individuals representing 5 amphibian species within the East Bay region of California.Based on a competing-model approach followed by variance partitioning, landscape and biotic variables explained the most variation in site-level presence. However, biotic and individual-level variables explained the most variation in individual-level infection.Distance to nearest ranavirus-infected pond (the landscape factor) was more important than biotic factors at the site-level; however, biotic factors were most influential at the individual-level. At the site level, the probability of ranavirus presence correlated negatively with distance to nearest ranavirus-positive pond, suggesting that the movement of water or mobile taxa (e.g., adult amphibians, birds, reptiles) may facilitate the movement of ranavirus between ponds and across the landscape.Taxonomic richness associated positively with ranavirus presence at the site-level, but vertebrate richness associated negatively with infection prevalence in the host population. This might reflect the contrasting influences of diversity on pathogen colonization versus transmission among hosts.Amphibian host species differed in their likelihood of ranavirus infection: American bullfrogs () had the weakest association with infection while rough-skinned newts () had the strongest. After accounting for host species effects, hosts with greater snout-vent length had a lower probability of infection.Our study demonstrates the array of landscape, environmental, and individual-level factors associated with ranavirus epidemiology. Moreover, our study helps illustrate that the importance of these factors varies with biological level.
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