整合全球基因组分析和多组学 QTLs 发现未表征的 COVID-19 基因生物特征和表型关联

Meritxell Oliva, Emily King, Reza Hammond, John S. Lee, Bridget Riley-Gillis, Justyna Resztak, Jacob Degner
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摘要

为了更好地了解 COVID-19 的病理生物学并确定治疗目标的优先次序,我们试图确定影响遗传驱动的疾病风险和严重程度的人类基因,并确定受多向 COVID-19 相关基因组位点影响的其他生物体级表型。为此,我们进行了祖先感知、跨层、多组学分析,通过共定位分析将来自非洲、美洲印第安、南亚、东亚、欧洲和元祖先等六个祖先终点的最新 COVID-19 宿主遗传学计划全基因组关联(GWAS)数据与定量性状位点(QTL)和 GWAS 终点整合在一起。我们确定了 47 个 COVID-19 基因座与 307 个 GWAS 性状终点的共定位,观察到每个 COVID-19 基因座的多向性程度差异很大(1-435 个终点共定位),但肺部性状的代表性很高。对于这些特征,映射到 COVID-19 病理等位基因上的效应的方向性指向了慢性阻塞性肺病的系统保护效应、肺腺癌的有害效应以及 IPF 的位点依赖效应。在64个QTL-COVID-19共定位位点中,我们发现了与大多数已报道(47/53)和半数未报道(19/38)COVID-19相关位点的关联,包括在非欧洲队列中发现的9个位点。我们生成了共定位证据度量和可视化工具,并整合了肺特异性 QTL 信号,以帮助识别推定的因果基因和肺细胞。例如,在以前未与 COVID-19 联系在一起的可能致病基因中,我们发现了肺泡细胞中由去瘤素驱动的 IPF 共享遗传扰动。总之,我们通过确定与 COVID-19 风险和严重性表型的遗传结构相关的分子和表型,提供了对 COVID-19 生物学的见解;进一步描述了以前报告的基因位点的特征,并为未描述的基因位点提供了新的见解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Integration of GWAS and multi-omic QTLs identifies uncharacterized COVID-19 gene-biotype and phenotype associations
To better understand COVID-19 pathobiology and to prioritize treatment targets, we sought to identify human genes influencing genetically driven disease risk and severity, and to identify additional organismal-level phenotypes impacted by pleiotropic COVID-19-associated genomic loci. To this end, we performed ancestry-aware, trans-layer, multi-omic analyses by integrating recent COVID-19 Host Genetics Initiative genome-wide association (GWAS) data from six ancestry endpoints - African, Amerindian, South Asian, East Asian, European and meta-ancestry - with quantitative trait loci (QTL) and GWAS endpoints by colocalization analyses. We identified colocalizations for 47 COVID-19 loci with 307 GWAS trait endpoints and observed a highly variable (1-435 endpoint colocalizations) degree of pleiotropy per COVID-19 locus but a high representation of pulmonary traits. For those, directionality of effect mapped to COVID-19 pathological alleles pinpoints to systematic protective effects for COPD, detrimental effects for lung adenocarcinoma, and locus-dependent effects for IPF. Among 64 QTL-COVID-19 colocalized loci, we identified associations with most reported (47/53) and half of unreported (19/38) COVID-19-associated loci, including 9 loci identified in non-European cohorts. We generated colocalization evidence metrics and visualization tools, and integrated pulmonary-specific QTL signal, to aid the identification of putative causal genes and pulmonary cells. For example, among likely causal genes not previously linked to COVID-19, we identified desmoplakin-driven IPF-shared genetic perturbations in alveolar cells. Altogether, we provide insights into COVID-19 biology by identifying molecular and phenotype links to the genetic architecture of COVID-19 risk and severity phenotypes; further characterizing previously reported loci and providing novel insights for uncharacterized loci.
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