Where Does All the Poison Go? Investigating Toxicokinetics of Newt (Taricha) Tetrodotoxin (TTX) in Garter Snakes (Thamnophis).

IF 2.2 3区环境科学与生态学 Q4 BIOCHEMISTRY & MOLECULAR BIOLOGY

Journal of Chemical Ecology Pub Date : 2024-10-01 Epub Date: 2024-06-06 DOI:10.1007/s10886-024-01517-7

Kelly E Robinson, Haley A Moniz, Amber N Stokes, Chris R Feldman

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Abstract

Animals that consume toxic diets provide models for understanding the molecular and physiological adaptations to ecological challenges. Garter snakes (Thamnophis) in western North America prey on Pacific newts (Taricha), which employ tetrodotoxin (TTX) as an antipredator defense. These snakes possess mutations in voltage-gated sodium channels (Na_v), the molecular targets of TTX, that decrease the binding ability of TTX to sodium channels (target-site resistance). However, genetic variation at these loci that cannot explain all the phenotypic variation in TTX resistance in Thamnophis. We explored a separate means of resistance, toxin metabolism, to determine if TTX-resistant snakes either rapidly remove TTX or sequester TTX. We examined the metabolism and distribution of TTX in the body (toxicokinetics), to determine differences between TTX-resistant and TTX-sensitive snakes in the rates at which TTX is eliminated from organs and the whole body (using TTX half-life as our metric). We assayed TTX half-life in snakes from TTX-resistant and TTX-sensitive populations of three garter snake species with a coevolutionary history with newts (T. atratus, T. couchii, T. sirtalis), as well as two non-resistant "outgroup" species (T. elegans, Pituophis catenifer) that seldom (if ever) engage newts. We found TTX half-life varied across species, populations, and tissues. Interestingly, TTX half-life was shortest in T. elegans and P. catenifer compared to all other snakes. Furthermore, TTX-resistant populations of T. couchii and T. sirtalis eliminated TTX faster (shorter TTX half-life) than their TTX-sensitive counterparts, while populations of TTX-resistant and TTX-sensitive T. atratus showed no difference rates of TTX removal (same TTX half-life). The ability to rapidly eliminate TTX may have permitted increased prey consumption, which may have promoted the evolution of additional resistance mechanisms. Finally, snakes still retain substantial amounts of TTX, and we projected that snakes could be dangerous to their own predators days to weeks following the ingestion of a single newt. Thus, aspects of toxin metabolism may have been key in driving predator-prey relationships, and important in determining other ecological interactions.

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毒药都去哪儿了？探究蝾螈（Taricha）河豚毒素（TTX）在眼镜蛇（Thamnophis）体内的毒代动力学。

食用有毒食物的动物为了解生态挑战的分子和生理适应提供了模型。北美洲西部的短吻蛇（Thamnophis）捕食太平洋蝾螈（Taricha），而太平洋蝾螈则利用河豚毒素（TTX）来抵御捕食者。这些蛇体内的电压门控钠通道（Nav）是 TTX 的分子靶标，它们的突变会降低 TTX 与钠通道的结合能力（靶点抗性）。然而，这些基因位点的遗传变异并不能解释TTX抗性在Thamnophis中的所有表型变异。我们探索了另一种抗性手段--毒素代谢，以确定抗 TTX 的蛇是否能快速清除 TTX 或封存 TTX。我们研究了 TTX 在体内的代谢和分布（毒物动力学），以确定抗 TTX 蛇和对 TTX 敏感蛇在 TTX 从器官和全身排出的速度上的差异（以 TTX 半衰期作为衡量标准）。我们对三个与蝾螈有共同进化史的带蛇物种（T. atratus、T. couchii、T. sirtalis）以及两个很少（甚至从未）与蝾螈接触的非抗性 "外群 "物种（T. elegans、Pituophis catenifer）的抗 TTX 和对 TTX 敏感种群中的蛇进行了 TTX 半衰期测定。我们发现 TTX 的半衰期因物种、种群和组织而异。有趣的是，与其他所有蛇类相比，TTX 在蝾螈和 P. catenifer 中的半衰期最短。此外，耐 TTX 的 T. couchii 和 T. sirtalis 种群比对 TTX 敏感的同类消除 TTX 的速度更快（TTX 半衰期更短），而耐 TTX 的 T. atratus 种群和对 TTX 敏感的 T. atratus 种群消除 TTX 的速度没有差异（TTX 半衰期相同）。快速消除 TTX 的能力可能使猎物的消耗量增加，从而促进了更多抗性机制的进化。最后，蛇体内仍残留着大量的 TTX，我们预测蛇在摄入一只蝾螈数天到数周后，可能会对自己的捕食者造成危害。因此，毒素代谢的各个方面可能是驱动捕食者-猎物关系的关键，也是决定其他生态相互作用的重要因素。

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来源期刊

Journal of Chemical Ecology 环境科学-生化与分子生物学

CiteScore

5.10

自引率

4.30%

发文量

审稿时长

4 months

期刊介绍： Journal of Chemical Ecology is devoted to promoting an ecological understanding of the origin, function, and significance of natural chemicals that mediate interactions within and between organisms. Such relationships, often adaptively important, comprise the oldest of communication systems in terrestrial and aquatic environments. With recent advances in methodology for elucidating structures of the chemical compounds involved, a strong interdisciplinary association has developed between chemists and biologists which should accelerate understanding of these interactions in nature. Scientific contributions, including review articles, are welcome from either members or nonmembers of the International Society of Chemical Ecology. Manuscripts must be in English and may include original research in biological and/or chemical aspects of chemical ecology. They may include substantive observations of interactions in nature, the elucidation of the chemical compounds involved, the mechanisms of their production and reception, and the translation of such basic information into survey and control protocols. Sufficient biological and chemical detail should be given to substantiate conclusions and to permit results to be evaluated and reproduced.