Heat stress-induced genomic instability in neural stem cells and its association with neuronal developmental deficits

IF 3.7 3区医学 Q2 NEUROSCIENCES

Brain Research Bulletin Pub Date : 2025-08-18 DOI:10.1016/j.brainresbull.2025.111517

Zeze Wang , Zhen Luo , Yulong Tan , Xue Luo , Xuesen Yang

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引用次数: 0

Abstract

Background

Maternal hyperthermia, an increasingly prevalent environmental stressor linked to global climate change, is epidemiologically associated with a higher risk of neurodevelopmental disorders, including autism and schizophrenia. However, the molecular mechanisms underlying this neurotoxicity, particularly those leading to long-term neurological deficits, remain poorly understood. This study tested the novel hypothesis that hyperthermia acts not only as an acute physiological stressor but also as a potent genotoxic agent, inducing persistent genomic alterations in neural progenitor cells.

Methods

We established an in vitro model using mouse embryonic neural stem cells (eNSCs) differentiated into developing neurons. These cells were subjected to acute hyperthermic stress (40–43°C for 2 h). We employed a multi-omics approach to assess the consequences, including high-content neuromorphometrics, strand-specific RNA sequencing (RNA-seq) for transcriptomic and genomic variant analysis, and immunofluorescence for DNA double-strand breaks (DSBs) using the γH2AX marker.

Results

Hyperthermia exposure at a clinically relevant temperature of 41°C induced a dose-dependent inhibition of neurite outgrowth and branching complexity. This morphological defect was underpinned by the induction of DNA DSBs, which triggered a robust p53-mediated DNA damage response, characterized by the upregulation of cell cycle arrest genes like Cdkn1a (p21). Critically, we uncovered evidence of lasting genomic damage. Hyperthermia-exposed neurons exhibited a significant increase in the frequency of single-nucleotide polymorphisms (SNPs), a lower transition-to-transversion (Ti/Tv) ratio indicative of genomic instability, and the formation of novel gene fusions. We identified a "heat stress signature" of unique mutations in key neurodevelopmental genes, including a missense variant in the inflammasome component Nlrp3 and structural rearrangements involving the axon guidance receptor Robo2 and the actin cytoskeleton regulator Cyth3.

Conclusion

Our findings reveal that hyperthermia impairs neuronal development through a "double-hit" mechanism. The "first hit" is an acute disruption of developmental programming via a p53-p21-mediated response to DNA damage. The "second hit" consists of permanent "genomic scars"—including SNPs and gene fusions—that can irreversibly alter the function of critical neurodevelopmental genes. By demonstrating that a transient environmental stressor can induce lasting genomic instability in neural progenitors, this study provides a compelling mechanistic framework linking maternal fever to the etiology of neurodevelopmental disorders and highlights a potentially crucial pathway for gene-environment interactions in brain development.

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热应激诱导的神经干细胞基因组不稳定性及其与神经元发育缺陷的关系

背景：与全球气候变化相关的产妇热疗是一种日益普遍的环境应激源，在流行病学上与神经发育障碍（包括自闭症和精神分裂症）的高风险相关。然而，这种神经毒性的分子机制，特别是那些导致长期神经功能障碍的分子机制，仍然知之甚少。这项研究验证了一种新的假设，即热疗不仅作为一种急性生理应激源，而且作为一种强效的基因毒性物质，诱导神经祖细胞持续的基因组改变。方法利用小鼠胚胎神经干细胞（eNSCs）分化成发育中的神经元，建立体外模型。这些细胞遭受急性高温应激（40-43°C 2 h）。我们采用了多组学方法来评估结果，包括高含量的神经形态计量学，用于转录组学和基因组变异分析的链特异性RNA测序（RNA-seq），以及使用γH2AX标记的DNA双链断裂（dsb）的免疫荧光。结果临床相关温度41°C的低温暴露诱导了神经突生长和分支复杂性的剂量依赖性抑制。这种形态缺陷是由DNA dsb的诱导所支持的，它触发了一个强大的p53介导的DNA损伤反应，其特征是细胞周期阻滞基因Cdkn1a的上调（p21）。重要的是，我们发现了持续的基因组损伤的证据。高温暴露的神经元显示出单核苷酸多态性（snp）的频率显著增加，较低的过渡-翻转（Ti/Tv）比率表明基因组不稳定，以及新基因融合的形成。我们在关键的神经发育基因中发现了独特突变的“热应激特征”，包括炎症小体成分Nlrp3的错义变异，以及涉及轴突引导受体Robo2和肌动蛋白细胞骨架调节因子Cyth3的结构重排。结论：我们的研究结果表明，高温通过“双重打击”机制损害神经元的发育。“第一次打击”是通过p53-p21介导的对DNA损伤的反应对发育程序的急性破坏。“第二次打击”包括永久性的“基因组伤痕”——包括snp和基因融合——它们可以不可逆转地改变关键神经发育基因的功能。通过证明短暂的环境应激源可以诱导神经祖细胞持续的基因组不稳定，本研究提供了一个令人信服的机制框架，将母体发烧与神经发育障碍的病因联系起来，并强调了大脑发育中基因-环境相互作用的潜在关键途径。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Brain Research Bulletin 医学-神经科学

CiteScore

6.90

自引率

2.60%

发文量

253

审稿时长

67 days

期刊介绍： The Brain Research Bulletin (BRB) aims to publish novel work that advances our knowledge of molecular and cellular mechanisms that underlie neural network properties associated with behavior, cognition and other brain functions during neurodevelopment and in the adult. Although clinical research is out of the Journal''s scope, the BRB also aims to publish translation research that provides insight into biological mechanisms and processes associated with neurodegeneration mechanisms, neurological diseases and neuropsychiatric disorders. The Journal is especially interested in research using novel methodologies, such as optogenetics, multielectrode array recordings and life imaging in wild-type and genetically-modified animal models, with the goal to advance our understanding of how neurons, glia and networks function in vivo.