Abstract
Organic contaminants are known to affect a suite of physiological processes across vertebrate clades. However, despite their ancient lineage and important roles in maintaining healthy ecosystems, elasmobranchs (sharks, skates, and rays) are understudied with regard to sublethal effects of contaminant exposure on metabolic processes. Perturbations resulting from contaminant exposure can divert energy away from maintaining physiological homeostasis, particularly during energetically challenging life stages, such as pregnancy and embryonic development. Using the round stingray (Urobatis halleri) as a model elasmobranch species, we captured adult males and pregnant females (matrotrophic histotrophy) and their embryos from two populations differing in their environmental exposure to organic contaminants (primarily polychlorinated biphenyls (PCBs)). Pregnant females from the PCB-exposed population experienced significant decreases from early- to late-pregnancy in tissue mass and quality not seen in reference females. PCB-exposed pregnant females also failed to maintain plasma urea concentrations as pregnancy progressed, which was accompanied by a loss in muscle protein content. Despite the energetic demands of late-term pregnancy, females had significantly greater liver lipid content than reproductively inactive adult males. PCB-exposed adult males also had high metabolic capacity (i.e., enzyme activity) for most substrate groupings of all sex-site groups, suggesting that males may be even more negatively impacted by contaminant exposure than pregnant females. Evidence that in utero exposure to PCBs via maternal offloading impairs embryo outcomes is accumulating. Embryos from the PCB-contaminated site had lower tissue quality measures and indications that sex-based differences were manifesting in utero as males had higher metabolic capacities than females. This study indicates that accumulated PCB contaminants are not physiologically inert in the stingray.
Highlights
IntroductionEnergetic fuels (i.e., carbohydrates, lipids, proteins) are needed to maintain physiological functioning for survival and reproduction and for homeostasis for all living organisms
Energetic fuels are needed to maintain physiological functioning for survival and reproduction and for homeostasis for all living organisms
The current research used this two-site comparison between mainland southern California (PCB-exposed site; 33.731 N, 118.064 W) and Santa Catalina Island as a natural study system to make potential inferences about polychlorinated biphenyls (PCBs) effects on elasmobranch physiology using the round stingray as a model
Summary
Energetic fuels (i.e., carbohydrates, lipids, proteins) are needed to maintain physiological functioning for survival and reproduction and for homeostasis for all living organisms. Any energetically demanding physiological process, such as growth, reproduction, immune function, or behavior, could potentially be impacted when organisms are exposed to toxicants (Adams et al 1989; Little and Finger 1990; Feist et al 2005). Further challenges arise when contaminant effects are explored in nonmodel species, as physiological response to contaminant. Toxicology studies on biochemical responses of contaminant exposure tend to focus on mammalian species, such as rats (Abdel-Daim et al 2020; AlBasher et al 2020) and mice (AlKahtane et al 2020; Matelski et al 2020), that serve as well-established models for understanding human health outcomes. Examining effects of contaminant exposure in non-model species is valuable for holistic understanding of human impacts on ecosystem health
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