Yen Eugenie C, Gilbert James D, Balard Alice, Afonso Inês O, Fairweather Kirsten, Newlands Débora, Lopes Artur, Correia Sandra M, Taxonera Albert, Rossiter Stephen J, Martín-Durán José M, Eizaguirre Christophe
School of Biological and Behavioural Sciences Queen Mary University of London London UK.
Project Biodiversity, Mercado Municipal Santa Maria Ilha do Sal Cabo Verde.
Evol Appl. 2024 Sep 15;17(9):e70013. doi: 10.1111/eva.70013. eCollection 2024 Sep.
To date, studies of the impacts of climate warming on individuals and populations have mostly focused on mortality and thermal tolerance. In contrast, much less is known about the consequences of sublethal effects, which are more challenging to detect, particularly in wild species with cryptic life histories. This necessitates the development of molecular tools to identify their signatures. In a split-clutch field experiment, we relocated clutches of wild, nesting loggerhead sea turtles () to an in situ hatchery. Eggs were then split into two sub-clutches and incubated under shallow or deep conditions, with those in the shallow treatment experiencing significantly higher temperatures in otherwise natural conditions. Although no difference in hatching success was observed between treatments, hatchlings from the shallow, warmer treatment had different length-mass relationships and were weaker at locomotion tests than their siblings incubated in the deep, cooler treatment. To characterise the molecular signatures of these thermal effects, we performed whole genome bisulfite sequencing on blood samples collected upon emergence. We identified 287 differentially methylated sites between hatchlings from different treatments, including on genes with neurodevelopmental, cytoskeletal, and lipid metabolism functions. Taken together, our results show that higher incubation temperatures induce sublethal effects in hatchlings, which are reflected in their DNA methylation status at identified sites. These sites could be used as biomarkers of thermal stress, especially if they are retained across life stages. Overall, this study suggests that global warming reduces hatchling fitness, which has implications for dispersal capacity and ultimately a population's adaptive potential. Conservation efforts for these endangered species and similar climate-threatened taxa will therefore benefit from strategies for monitoring and mitigating exposure to temperatures that induce sublethal effects.
迄今为止,关于气候变暖对个体和种群影响的研究大多集中在死亡率和热耐受性方面。相比之下,对于亚致死效应的后果了解要少得多,亚致死效应更难检测,尤其是对于具有隐秘生活史的野生物种。这就需要开发分子工具来识别它们的特征。在一项分窝野外实验中,我们将野生蠵龟()的巢穴转移到一个原位孵化场。然后将卵分成两个子窝,并在浅层或深层条件下孵化,浅层处理的卵在其他自然条件下经历显著更高的温度。虽然在不同处理之间未观察到孵化成功率的差异,但来自浅层、较温暖处理的幼龟具有不同的体长 - 体重关系,并且在运动测试中比在深层、较凉爽处理中孵化的同胞幼龟更弱。为了表征这些热效应的分子特征,我们对幼龟出壳时采集的血液样本进行了全基因组亚硫酸氢盐测序。我们在不同处理的幼龟之间鉴定出287个差异甲基化位点,包括在具有神经发育、细胞骨架和脂质代谢功能的基因上。综合来看,我们的结果表明较高的孵化温度会在幼龟中诱导亚致死效应,这反映在它们在已识别位点的DNA甲基化状态上。这些位点可以用作热应激的生物标志物,特别是如果它们在整个生命阶段都能保留。总体而言,这项研究表明全球变暖会降低幼龟的适应性,这对扩散能力以及最终种群的适应潜力都有影响。因此,对这些濒危物种和类似受气候威胁的分类群的保护工作将受益于监测和减轻暴露于诱导亚致死效应温度的策略。
