小鼠母体营养不良会破坏调控区域的 DNA 甲基化,从而影响肾脏生成。

Yaniv Makayes, Eden Abergel, Athar Amleh, Dan Binyamin Varshavsky, Rimma Fok, Batia Azria, Ihab Ansari, Yehudit Bergman, Morris Nechama, Oded Volovelsky
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引用次数: 0

摘要

母亲在怀孕期间限制热量摄入会严重影响肾脏的发育,进而影响成年后患慢性肾病的几率。本研究探讨了热量限制导致的肾脏祖细胞DNA甲基化变化及其对肾脏健康的影响。在来自热量限制胚胎的肾小球祖细胞中观察到了全球性的DNA低甲基化,特定的基因组区域显示出不同的甲基化模式,包括低甲基化和高甲基化。不同的甲基化区域显示出染色质可及性的增强,表明了其生物学相关性。低甲基化区域富集了与发育过程相关的基因,反映了基因表达的变化,突出了它们在肾脏发育中的功能相关性。研究还发现,补充蛋氨酸(一种必需氨基酸)可恢复紊乱的 DNA 甲基化模式,尤其是在增强子区域,这强调了蛋氨酸在调节肾小球祖细胞表观遗传学和确保肾脏正常发育方面的关键作用。研究强调了母体营养、动态 DNA 甲基化和肾脏发育之间错综复杂的关系,强调了生命早期的营养挑战对肾脏功能的持久影响。这项研究阐明了母体热量限制对肾脏健康产生持久影响的表观遗传机制。这项研究对早期发育阶段慢性肾脏疾病的起源提供了宝贵的见解,为减轻不良后果提供了潜在的干预措施。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Maternal malnutrition in mice impairs nephrogenesis by disrupting DNA methylation of regulatory regions.

Maternal caloric restriction during pregnancy significantly impacts kidney development, influencing susceptibility to chronic kidney disease in adulthood. This study explores DNA methylation changes in nephron progenitor cells resulting from caloric restriction and their implications for kidney health. Global DNA hypomethylation is observed in nephron progenitors from caloric-restricted embryos, with specific genomic regions displaying distinct methylation patterns, including hypomethylation and hypermethylation. Differentially methylated regions exhibit enhanced chromatin accessibility, indicating biological relevance. Hypomethylated regions are enriched for genes associated with developmental processes, reflecting changes in gene expression and highlighting their functional relevance in kidney development. The study also reveals that supplementing methionine, an essential amino acid, restores disrupted DNA methylation patterns, particularly in enhancer regions, emphasizing methionine's critical role in regulating nephron progenitor cell epigenetics and ensuring proper kidney development. The intricate relationship between maternal nutrition, dynamic DNA methylation, and kidney development is highlighted, emphasizing the enduring impact of early-life nutritional challenges on kidney function. This research elucidates epigenetic mechanisms as mediators for the lasting effects of maternal caloric restriction on kidney health. The study contributes valuable insights into the origins of chronic kidney diseases during early developmental stages, offering potential interventions to mitigate adverse outcomes.NEW & NOTEWORTHY Our study establishes a direct link between maternal caloric restriction, DNA methylation patterns in nephron progenitor cells, and kidney development. We reveal consistent alterations in methylation patterns, coupled with corresponding shifts in the expression of genes related to kidney development and cell proliferation. Methionine supplementation emerges as a promising intervention, effectively restoring disrupted DNA methylation patterns. These findings pave the way for potential therapeutics, optimizing kidney development and mitigating the burden of chronic kidney disease in adulthood.

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