Dandan Huang, Wenlong Shang, Mengtong Xu, Qiangyou Wan, Jin Zhang, Xiaofeng Tang, Yujun Shen, Yan Wang, Ying Yu
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引用次数: 0
Abstract
Background: Despite advances in understanding hypertension's genetic structure, how noncoding genetic variants influence it remains unclear. Studying their interaction with DNA methylation is crucial to deciphering this complex disease's genetic mechanisms.
Methods: We investigated the genetic and epigenetic interplay in hypertension using whole-genome bisulfite sequencing. Methylation profiling in 918 males revealed allele-specific methylation and methylation quantitative trait loci. We engineered rs1275988T/C mutant mice using CRISPR (clustered regularly interspaced short palindromic repeats)/Cas9 (CRISPR-associated protein 9), bred them for homozygosity, and subjected them to a high-salt diet. Telemetry captured their cardiovascular metrics. Protein-DNA interactions were elucidated using DNA pull-downs, mass spectrometry, and Western blots. A wire myograph assessed vascular function, and analysis of the Kcnk3 gene methylation highlighted the mutation's role in hypertension.
Results: We discovered that DNA methylation-associated genetic effects, especially in non-cytosine-phosphate-guanine (non-CpG) island and noncoding distal regulatory regions, significantly contribute to hypertension predisposition. We identified distinct methylation quantitative trait locus patterns in the hypertensive population and observed that the onset of hypertension is influenced by the transmission of genetic effects through the demethylation process. By evidence-driven prioritization and in vivo experiments, we unearthed rs1275988 in a cell type-specific enhancer as a notable hypertension causal variant, intensifying hypertension through the modulation of local DNA methylation and consequential alterations in Kcnk3 gene expression and vascular remodeling. When exposed to a high-salt diet, mice with the rs1275988C/C genotype exhibited exacerbated hypertension and significant vascular remodeling, underscored by increased aortic wall thickness. The C allele of rs1275988 was associated with elevated DNA methylation levels, driving down the expression of the Kcnk3 gene by attenuating Nr2f2 (nuclear receptor subfamily 2 group F member 2) binding at the enhancer locus.
Conclusions: Our research reveals new insights into the complex interplay between genetic variations and DNA methylation in hypertension. We underscore hypomethylation's potential in hypertension onset and identify rs1275988 as a causal variant in vascular remodeling. This work advances our understanding of hypertension's molecular mechanisms and encourages personalized health care strategies.
背景:尽管在了解高血压的遗传结构方面取得了进展,但非编码基因变异如何影响高血压仍不清楚。研究非编码基因变异与 DNA 甲基化之间的相互作用对于破译这种复杂疾病的遗传机制至关重要:方法:我们利用全基因组亚硫酸氢盐测序技术研究了高血压的遗传和表观遗传相互作用。918名男性的甲基化图谱显示了等位基因特异性甲基化和甲基化数量性状位点。我们利用CRISPR/Cas9技术设计了rs1275988T/C突变小鼠,将它们进行同源繁殖,并让它们摄入高盐饮食。遥测技术捕获了它们的心血管指标。利用DNA牵引、质谱分析和Western印迹阐明了蛋白质与DNA之间的相互作用。线性肌电图评估了血管功能,Kcnk3基因甲基化分析突出了该基因突变在高血压中的作用:结果:我们发现,DNA甲基化相关遗传效应,尤其是非CpG岛和非编码远端调控区的甲基化效应,对高血压的易感性有重要影响。我们在高血压人群中发现了不同的甲基化数量性状位点模式,并观察到高血压的发病受遗传效应通过去甲基化过程传递的影响。通过证据驱动的优先排序和体内实验,我们发现细胞类型特异性增强子中的 rs1275988 是一个显著的高血压致病变异体,它通过调节局部 DNA 甲基化和随之而来的 Kcnk3 基因表达和血管重塑的改变来加剧高血压。当小鼠暴露于高盐饮食时,rs1275988C/C 基因型的小鼠表现出高血压加剧和明显的血管重塑,主动脉壁厚度增加更突出了这一点。rs1275988的C等位基因与DNA甲基化水平升高有关,通过减弱Nr2f2在增强子位点的结合,降低了Kcnk3基因的表达:我们的研究揭示了高血压基因变异与 DNA 甲基化之间复杂的相互作用。我们强调了低甲基化在高血压发病中的潜在作用,并确定 rs1275988 是血管重塑的一个因果变异。这项研究加深了我们对高血压分子机制的理解,有助于制定个性化的医疗保健策略。
期刊介绍:
Circulation Research is a peer-reviewed journal that serves as a forum for the highest quality research in basic cardiovascular biology. The journal publishes studies that utilize state-of-the-art approaches to investigate mechanisms of human disease, as well as translational and clinical research that provide fundamental insights into the basis of disease and the mechanism of therapies.
Circulation Research has a broad audience that includes clinical and academic cardiologists, basic cardiovascular scientists, physiologists, cellular and molecular biologists, and cardiovascular pharmacologists. The journal aims to advance the understanding of cardiovascular biology and disease by disseminating cutting-edge research to these diverse communities.
In terms of indexing, Circulation Research is included in several prominent scientific databases, including BIOSIS, CAB Abstracts, Chemical Abstracts, Current Contents, EMBASE, and MEDLINE. This ensures that the journal's articles are easily discoverable and accessible to researchers in the field.
Overall, Circulation Research is a reputable publication that attracts high-quality research and provides a platform for the dissemination of important findings in basic cardiovascular biology and its translational and clinical applications.
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