利用相关工具变量集预测具有多向性基因调控效应的 GWAS 基因位点上的因果基因。

IF 4 2区 生物学 Q1 GENETICS & HEREDITY PLoS Genetics Pub Date : 2024-11-11 eCollection Date: 2024-11-01 DOI:10.1371/journal.pgen.1011473
Mariyam Khan, Adriaan-Alexander Ludl, Sean Bankier, Johan L M Björkegren, Tom Michoel
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引用次数: 0

摘要

多变量孟德尔随机化(Multivariate Mendelian randomization,MVMR)是一种统计技术,它利用成套的遗传工具来估计多种暴露因素对相关结果的直接因果效应。在具有多向基因调控效应的基因组位点,即相同的基因变异与附近多个基因相关的位点,MVMR 有可能用于预测候选因果基因。然而,该领域的共识规定,MVMR 中的遗传工具必须是独立的(不存在连锁不平衡),而在考虑来自同一基因座的一组候选基因时,这通常是不可能的。在这里,我们利用因果推理理论证明,具有相关工具的 MVMR 满足工具集条件。这是 Brito 和 Pearl(2002 年)针对结构方程模型得出的经典结果,它保证了在多种暴露共同而非单独地将一组工具变量与结果变量分开的情况下,个体因果效应的可识别性。大量的模拟证实了这些理论结果的有效性和实用性。重要的是,即使在工具高度相关的情况下,因果效应估计值仍然是无偏的,其方差也很小,而水平多效性或 LD 矩阵抽样误差带来的偏差与标准 MR 相当。我们利用 STARNET 研究中七个血管和代谢组织的表达定量性状位点(eQTL)数据,在冠状动脉疾病(CAD)风险的全基因组重要位点上应用了具有相关工具变量集的 MVMR。我们的方法预测了 12 个位点的因果基因,每个位点都与多个组织中的多个共位基因相关。我们证实了 PHACTR1 和 ADAMTS7 等基因在动脉组织中的因果作用。然而,由于不同组织间存在广泛的调控多效性,而每个基因位点上的因果变异体数量有限,因此 MVMR 仍需以组织为单位运行,在单一模型中测试特定基因位点上具有顺式-eQTL 关联的所有基因-组织对,以预测因果基因-组织组合仍不可行。我们的研究结果表明,在组织内,MVMR 与依赖性工具变量集(而非独立的工具变量集)大大扩展了预测具有多向调控效应的疾病风险基因座的因果基因的范围。然而,考虑具有跨组织多向调控效应的风险基因座仍然是一个尚未解决的问题。
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Prediction of causal genes at GWAS loci with pleiotropic gene regulatory effects using sets of correlated instrumental variables.

Multivariate Mendelian randomization (MVMR) is a statistical technique that uses sets of genetic instruments to estimate the direct causal effects of multiple exposures on an outcome of interest. At genomic loci with pleiotropic gene regulatory effects, that is, loci where the same genetic variants are associated to multiple nearby genes, MVMR can potentially be used to predict candidate causal genes. However, consensus in the field dictates that the genetic instruments in MVMR must be independent (not in linkage disequilibrium), which is usually not possible when considering a group of candidate genes from the same locus. Here we used causal inference theory to show that MVMR with correlated instruments satisfies the instrumental set condition. This is a classical result by Brito and Pearl (2002) for structural equation models that guarantees the identifiability of individual causal effects in situations where multiple exposures collectively, but not individually, separate a set of instrumental variables from an outcome variable. Extensive simulations confirmed the validity and usefulness of these theoretical results. Importantly, the causal effect estimates remained unbiased and their variance small even when instruments are highly correlated, while bias introduced by horizontal pleiotropy or LD matrix sampling error was comparable to standard MR. We applied MVMR with correlated instrumental variable sets at genome-wide significant loci for coronary artery disease (CAD) risk using expression Quantitative Trait Loci (eQTL) data from seven vascular and metabolic tissues in the STARNET study. Our method predicts causal genes at twelve loci, each associated with multiple colocated genes in multiple tissues. We confirm causal roles for PHACTR1 and ADAMTS7 in arterial tissues, among others. However, the extensive degree of regulatory pleiotropy across tissues and the limited number of causal variants in each locus still require that MVMR is run on a tissue-by-tissue basis, and testing all gene-tissue pairs with cis-eQTL associations at a given locus in a single model to predict causal gene-tissue combinations remains infeasible. Our results show that within tissues, MVMR with dependent, as opposed to independent, sets of instrumental variables significantly expands the scope for predicting causal genes in disease risk loci with pleiotropic regulatory effects. However, considering risk loci with regulatory pleiotropy that also spans across tissues remains an unsolved problem.

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PLoS Genetics
PLoS Genetics GENETICS & HEREDITY-
自引率
2.20%
发文量
438
期刊介绍: PLOS Genetics is run by an international Editorial Board, headed by the Editors-in-Chief, Greg Barsh (HudsonAlpha Institute of Biotechnology, and Stanford University School of Medicine) and Greg Copenhaver (The University of North Carolina at Chapel Hill). Articles published in PLOS Genetics are archived in PubMed Central and cited in PubMed.
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