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在幼年褐鳟中,亲本对甲基化的影响比温度影响更强。

Stronger Parental Than Temperature Effects on Methylation in Juvenile Brown Trout ().

作者信息

Liu Shenglin, Jonsson Bror, Greenberg Larry, Hansen Michael M

机构信息

Department of Biology Aarhus University Aarhus C Denmark.

Norwegian Institute for Nature Research Oslo Norway.

出版信息

Ecol Evol. 2025 Sep 10;15(9):e72154. doi: 10.1002/ece3.72154. eCollection 2025 Sep.

DOI:10.1002/ece3.72154
PMID:40936595
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12422787/
Abstract

Epigenetic modifications, particularly DNA methylation, are increasingly recognized as mechanisms underlying phenotypic plasticity and potential mediators of transgenerational responses to environmental change. We investigated the persistence of early life temperature-induced DNA methylation changes and the role of parental life history in shaping methylation patterns in juvenile brown trout (). Fertilized eggs from crosses of anadromous and resident trout were incubated under natural or elevated temperatures (by +3°C) until first feeding, after which all fish were reared under common conditions. Whole-genome bisulfite pooled sequencing was conducted on juveniles 10.5 months post-fertilization. We found weak and inconsistent evidence for persistent temperature-induced methylation changes, with little overlap among different parental cross types. In contrast, parental life history, particularly maternal origin, significantly influenced offspring methylation patterns. Maternally derived differences were more extensive than paternal effects and were enriched for genes related to metabolism, nervous system function, and digestion, suggesting potential adaptive relevance. These findings suggest a limited long-term impact of early-life thermal conditions on methylation and emphasize a stronger role of transgenerational epigenetic effects in brown trout. Given that climate change is expected to alter thermal regimes in future aquatic ecosystems, our results, along with other recent publications, suggest that parental environmental history may be a more significant driver of epigenetic variability than the temperature experienced during early life. Understanding such mechanisms is critical for predicting how populations may respond to ongoing and future climate change.

摘要

表观遗传修饰,尤其是DNA甲基化,越来越被认为是表型可塑性的潜在机制以及对环境变化的跨代反应的介导因素。我们研究了早期生活温度诱导的DNA甲基化变化的持续性,以及亲代生活史在塑造幼年褐鳟甲基化模式中的作用。将溯河洄游型和定居型鳟鱼杂交的受精卵在自然温度或升高温度(+3°C)下孵化至初次摄食,之后所有鱼均在相同条件下饲养。在受精后10.5个月的幼鱼中进行了全基因组亚硫酸氢盐池测序。我们发现温度诱导的甲基化变化持续存在的证据微弱且不一致,不同亲代杂交类型之间几乎没有重叠。相比之下,亲代生活史,尤其是母本来源,对后代甲基化模式有显著影响。母本来源的差异比父本效应更广泛,并且与代谢、神经系统功能和消化相关的基因富集,表明可能具有适应性相关性。这些发现表明早期生活热条件对甲基化的长期影响有限,并强调了跨代表观遗传效应在褐鳟中的更强作用。鉴于气候变化预计将改变未来水生生态系统的热状况,我们的结果以及其他近期出版物表明,亲代环境史可能比早期生活中经历的温度更能驱动表观遗传变异。了解这些机制对于预测种群如何应对当前和未来的气候变化至关重要。

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本文引用的文献

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