空间转录组学和单核多组学分析揭示大量补充母体叶酸对后代大脑发育的影响

bioRxiv Pub Date : 2024-07-16 DOI:10.1101/2024.07.12.603269
Xiguang Xu, Yu Lin, Liduo Yin, Priscila da Silva Serpa, Benjamin Conacher, Christina Pacholac, Francisco Carvallo, Terry Hrubec, Shannon Farris, Kurt Zimmerman, Xiaobin Wang, Hehuang Xie
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引用次数: 0

摘要

叶酸是人体必需的维生素 B9,对包括神经发生在内的多种生物过程至关重要。孕期补充叶酸(FA)是预防神经管畸形(NTD)的标准做法。然而,人们对母体摄入过量叶酸的潜在风险越来越关注。在这里,我们采用小鼠模型、空间转录组学和单核多组学方法研究了围孕期母体补充高浓度脂肪酸对后代大脑发育的影响。母体高脂肪酸补充影响了多个脑区与神经发生和神经元轴突髓鞘化相关的基因通路,以及丘脑和脑室区域与学习和记忆相关的基因表达改变。单核多组学分析表明,齿状回(DG)中的成熟兴奋性神经元特别容易受到母体高脂肪酸摄入量的影响,从而导致基因表达异常和染色质可及性改变,而染色质可及性改变是影响核糖体生物发生的关键因素。我们的研究结果为了解母体高脂肪酸补充可能影响的特定脑区、细胞类型、基因表达和通路提供了新的视角。
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Spatial Transcriptomics and Single-Nucleus Multi-omics Analysis Revealing the Impact of High Maternal Folic Acid Supplementation on Offspring Brain Development
Folate, an essential vitamin B9, is crucial for diverse biological processes including neurogenesis. Folic acid (FA) supplementation during pregnancy is a standard practice for preventing neural tube defects (NTDs). However, concerns are growing over the potential risks of excessive maternal FA intake. Here, we employed mouse model and spatial transcriptomics and single-nucleus multi-omics approaches to investigate the impact of high maternal FA supplementation during the periconceptional period on offspring brain development. Maternal high FA supplementation affected gene pathways linked to neurogenesis and neuronal axon myelination across multiple brain regions, as well as gene expression alterations related to learning and memory in thalamic and ventricular regions. Single-nucleus multi-omics analysis revealed that maturing excitatory neurons in the dentate gyrus (DG) are particularly vulnerable to high maternal FA intake, leading to aberrant gene expressions and chromatin accessibility in pathways governing ribosomal biogenesis critical for synaptic formation. Our findings provide new insights into specific brain regions, cell types, gene expressions and pathways that can be affected by maternal high FA supplementation.
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