Fine mapping of candidate effector genes for heart rate.

IF 3.8 2区生物学 Q2 GENETICS & HEREDITY

Human Genetics Pub Date : 2024-10-01 Epub Date: 2024-07-06 DOI:10.1007/s00439-024-02684-z

Julia Ramírez, Stefan van Duijvenboden, William J Young, Yutang Chen, Tania Usman, Michele Orini, Pier D Lambiase, Andrew Tinker, Christopher G Bell, Andrew P Morris, Patricia B Munroe

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引用次数: 0

Abstract

An elevated resting heart rate (RHR) is associated with increased cardiovascular mortality. Genome-wide association studies (GWAS) have identified > 350 loci. Uniquely, in this study we applied genetic fine-mapping leveraging tissue specific chromatin segmentation and colocalization analyses to identify causal variants and candidate effector genes for RHR. We used RHR GWAS summary statistics from 388,237 individuals of European ancestry from UK Biobank and performed fine mapping using publicly available genomic annotation datasets. High-confidence causal variants (accounting for > 75% posterior probability) were identified, and we collated candidate effector genes using a multi-omics approach that combined evidence from colocalisation with molecular quantitative trait loci (QTLs), and long-range chromatin interaction analyses. Finally, we performed druggability analyses to investigate drug repurposing opportunities. The fine mapping pipeline indicated 442 distinct RHR signals. For 90 signals, a single variant was identified as a high-confidence causal variant, of which 22 were annotated as missense. In trait-relevant tissues, 39 signals colocalised with cis-expression QTLs (eQTLs), 3 with cis-protein QTLs (pQTLs), and 75 had promoter interactions via Hi-C. In total, 262 candidate genes were highlighted (79% had promoter interactions, 15% had a colocalised eQTL, 8% had a missense variant and 1% had a colocalised pQTL), and, for the first time, enrichment in nervous system pathways. Druggability analyses highlighted ACHE, CALCRL, MYT1 and TDP1 as potential targets. Our genetic fine-mapping pipeline prioritised 262 candidate genes for RHR that warrant further investigation in functional studies, and we provide potential therapeutic targets to reduce RHR and cardiovascular mortality.

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精细绘制心率候选效应基因图谱

静息心率（RHR）升高与心血管死亡率增加有关。全基因组关联研究（GWAS）发现了超过 350 个基因位点。与众不同的是，在本研究中，我们利用组织特异性染色质分割和共定位分析进行了基因精细图谱绘制，以确定 RHR 的因果变异和候选效应基因。我们使用了英国生物库中 388,237 名欧洲血统个体的 RHR GWAS 统计摘要，并利用公开的基因组注释数据集进行了精细图谱绘制。我们确定了高置信度的因果变异（后验概率大于 75%），并使用多组学方法整理了候选效应基因，该方法结合了与分子数量性状位点 (QTL) 共定位的证据以及长程染色质相互作用分析。最后，我们进行了可药性分析，以研究药物再利用的机会。精细图谱管道显示了 442 个不同的 RHR 信号。在 90 个信号中，有一个变体被鉴定为高置信度的因果变体，其中 22 个被注释为错义变体。在性状相关组织中，39 个信号与顺式表达 QTLs（eQTLs）共定位，3 个信号与顺式蛋白 QTLs（pQTLs）共定位，75 个信号通过 Hi-C 与启动子相互作用。总共有 262 个候选基因被突出显示（79% 的候选基因有启动子相互作用，15% 的候选基因有共定位 eQTL，8% 的候选基因有错义变异，1% 的候选基因有共定位 pQTL），并首次在神经系统通路中出现富集。可药用性分析突出表明，ACHE、CALCRL、MYT1 和 TDP1 是潜在的靶点。我们的基因精细图谱管道确定了 262 个 RHR 候选基因的优先顺序，这些基因值得在功能研究中进一步调查，我们还提供了降低 RHR 和心血管死亡率的潜在治疗靶点。

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

Human Genetics 生物-遗传学

CiteScore

10.80

自引率

3.80%

发文量

审稿时长

1 months

期刊介绍： Human Genetics is a monthly journal publishing original and timely articles on all aspects of human genetics. The Journal particularly welcomes articles in the areas of Behavioral genetics, Bioinformatics, Cancer genetics and genomics, Cytogenetics, Developmental genetics, Disease association studies, Dysmorphology, ELSI (ethical, legal and social issues), Evolutionary genetics, Gene expression, Gene structure and organization, Genetics of complex diseases and epistatic interactions, Genetic epidemiology, Genome biology, Genome structure and organization, Genotype-phenotype relationships, Human Genomics, Immunogenetics and genomics, Linkage analysis and genetic mapping, Methods in Statistical Genetics, Molecular diagnostics, Mutation detection and analysis, Neurogenetics, Physical mapping and Population Genetics. Articles reporting animal models relevant to human biology or disease are also welcome. Preference will be given to those articles which address clinically relevant questions or which provide new insights into human biology. Unless reporting entirely novel and unusual aspects of a topic, clinical case reports, cytogenetic case reports, papers on descriptive population genetics, articles dealing with the frequency of polymorphisms or additional mutations within genes in which numerous lesions have already been described, and papers that report meta-analyses of previously published datasets will normally not be accepted. The Journal typically will not consider for publication manuscripts that report merely the isolation, map position, structure, and tissue expression profile of a gene of unknown function unless the gene is of particular interest or is a candidate gene involved in a human trait or disorder.