斑马鱼
转录组
生物
表型
代谢组学
细胞生物学
热应力
代谢物
细胞应激反应
基因
遗传学
生物化学
基因表达
战斗或逃跑反应
生物信息学
动物科学
作者
Lauric Feugere,Adam Bates,Timothy Emagbetere,Emma Chapman,Linsey E. Malcolm,Kathleen Bulmer,Jörg D. Hardege,Pedro Beltrán-Álvarez,Katharina C. Wollenberg Valero
出处
期刊:PNAS nexus
[Oxford University Press]
日期:2023-05-01
卷期号:2 (5): pgad137-pgad137
被引量:19
标识
DOI:10.1093/pnasnexus/pgad137
摘要
Abstract Heat alters biology from molecular to ecological levels, but may also have unknown indirect effects. This includes the concept that animals exposed to abiotic stress can induce stress in naive receivers. Here, we provide a comprehensive picture of the molecular signatures of this process, by integrating multiomic and phenotypic data. In individual zebrafish embryos, repeated heat peaks elicited both a molecular response and a burst of accelerated growth followed by a growth slowdown in concert with reduced responses to novel stimuli. Metabolomes of the media of heat treated vs. untreated embryos revealed candidate stress metabolites including sulfur-containing compounds and lipids. These stress metabolites elicited transcriptomic changes in naive receivers related to immune response, extracellular signaling, glycosaminoglycan/keratan sulfate, and lipid metabolism. Consequently, non-heat-exposed receivers (exposed to stress metabolites only) experienced accelerated catch-up growth in concert with reduced swimming performance. The combination of heat and stress metabolites accelerated development the most, mediated by apelin signaling. Our results prove the concept of indirect heat-induced stress propagation toward naive receivers, inducing phenotypes comparable with those resulting from direct heat exposure, but utilizing distinct molecular pathways. Group-exposing a nonlaboratory zebrafish line, we independently confirm that the glycosaminoglycan biosynthesis-related gene chs1 and the mucus glycoprotein gene prg4a, functionally connected to the candidate stress metabolite classes sugars and phosphocholine, are differentially expressed in receivers. This hints at the production of Schreckstoff-like cues in receivers, leading to further stress propagation within groups, which may have ecological and animal welfare implications for aquatic populations in a changing climate.
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