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孕期过量补充叶酸会改变皮质基因表达网络和电生理。

Excess prenatal folic acid supplementation alters cortical gene expression networks and electrophysiology.

作者信息

Haghani Viktoria, Ali Sara Mohsen, Cannizzaro Noemi, Patil Mandar M, Sullivan Paula Dm, Rehamn Ammara, Green Ralph, Ben-Shalom Roy, LaSalle Janine M, Zarbalis Konstantinos

机构信息

Department of Medical Microbiology and Immunology, Genome Center, University of California, Davis. Davis, CA, USA.

Department of Molecular and Cellular Biology, Genome Center, University of California, Davis. Davis, CA, USA.

出版信息

bioRxiv. 2025 May 11:2025.05.07.652681. doi: 10.1101/2025.05.07.652681.

DOI:10.1101/2025.05.07.652681
PMID:40654749
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12248018/
Abstract

Folate is crucial for various biological processes, with deficiencies during pregnancy being linked to increased risk for neural tube defects and neurodevelopmental disorders. As a proactive measure, folic acid fortification in foods has been mandated in many countries, in addition to dietary supplementation recommendations during pregnancy. However, the risks of excess prenatal folic acid supply have yet to be fully understood. To better appreciate molecular changes in mouse brain exposed to 5-fold folic acid excess over normal supplementation, we investigated the transcriptome and methylome for alterations in gene networks. RNA-seq analysis of cerebral cortex collected at birth, revealed significant expression differences in 646 genes with major roles in protein translation. Whole genome bisulfite sequencing revealed 910 significantly differentially methylated regions with functions enriched in glutamatergic synapse and glutathione pathways. To explore the physiological consequences of excess prenatal folic acid exposure, we applied high-density microelectrode arrays to record network-level firing patterns of dissociated cortical neurons. Folic acid excess-derived cortical neurons exhibited significantly altered network activity, characterized by reduced burst amplitude and increased burst frequency, indicating compromised network synchronization. These functional deficits align with the observed molecular alterations in glutamatergic synapse pathways, underscoring the potential for excess prenatal folic acid exposure to disrupt developing metabolic and neurological pathways.

摘要

叶酸对各种生物过程至关重要,孕期缺乏叶酸与神经管缺陷和神经发育障碍的风险增加有关。作为一项积极措施,除了孕期膳食补充建议外,许多国家还强制要求在食品中强化叶酸。然而,产前叶酸供应过量的风险尚未完全了解。为了更好地了解在正常补充量基础上暴露于5倍过量叶酸的小鼠大脑中的分子变化,我们研究了转录组和甲基化组,以寻找基因网络中的变化。对出生时采集的大脑皮层进行RNA测序分析,发现646个在蛋白质翻译中起主要作用的基因存在显著表达差异。全基因组亚硫酸氢盐测序揭示了910个显著差异甲基化区域,其功能富集于谷氨酸能突触和谷胱甘肽途径。为了探究产前叶酸暴露过量的生理后果,我们应用高密度微电极阵列记录解离的皮层神经元的网络水平放电模式。叶酸过量导致的皮层神经元表现出明显改变的网络活动,其特征是爆发幅度降低和爆发频率增加,表明网络同步受损。这些功能缺陷与在谷氨酸能突触途径中观察到的分子改变一致,强调了产前叶酸暴露过量可能破坏发育中的代谢和神经通路。

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本文引用的文献

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Invited Perspective: Protect and Serve-The Potential Role of Folate in Lead Risk Reduction.特邀观点:保护与服务——叶酸在降低铅风险中的潜在作用。
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