Connecting intermediate phenotypes to disease using multi-omics in heart failure

Anni Moore, Rasika Venkatesh, Michael Levin, Scott M. Damrauer, Nosheen Reza, Thomas Cappola, Marylyn D Ritchie
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Abstract

Heart failure (HF) is one of the most common, complex, heterogeneous diseases in the world, with over 1-3% of the global population living with the condition. Progression of HF can be tracked via MRI measures of structural and functional changes to the heart, namely left ventricle (LV), including ejection fraction, mass, end-diastolic volume, and LV end-systolic volume. Moreover, while genome-wide association studies (GWAS) have been a useful tool to identify candidate variants involved in HF risk, they lack crucial tissue-specific and mechanistic information which can be gained from incorporating additional data modalities. This study addresses this gap by incorporating transcriptome-wide and proteome-wide association studies (TWAS and PWAS) to gain insights into genetically-regulated changes in gene expression and protein abundance in precursors to HF measured using MRI-derived cardiac measures as well as full-stage all-cause HF. We identified several gene and protein overlaps between LV ejection fraction and end-systolic volume measures. Many of the overlaps identified in MRI-derived measurements through TWAS and PWAS appear to be shared with all-cause HF. We implicate many putative pathways relevant in HF associated with these genes and proteins via gene-set enrichment and protein-protein interaction network approaches. The results of this study (1) highlight the benefit of using multi-omics to better understand genetics and (2) provide novel insights as to how changes in heart structure and function may relate to HF.
利用多组学技术将心力衰竭的中间表型与疾病联系起来
心力衰竭(HF)是世界上最常见、最复杂的异质性疾病之一,全球有超过 1%-3% 的人口患有此病。通过磁共振成像测量心脏(即左心室)的结构和功能变化,包括射血分数、质量、舒张末期容积和左心室收缩末期容积,可以追踪心力衰竭的进展。此外,虽然全基因组关联研究(GWAS)一直是确定与高频风险有关的候选变异体的有用工具,但它们缺乏关键的组织特异性和机理信息,而这些信息可以通过整合额外的数据模式获得。本研究通过结合全转录组和全蛋白质组关联研究(TWAS 和 PWAS)来深入了解受基因调控的基因表达和蛋白质丰度的变化,这些基因表达和蛋白质丰度的变化是通过核磁共振成像(MRI)获得的心脏测量数据以及全期全因高血压测量数据来测量高血压前兆的。我们在左心室射血分数和收缩末期容积测量之间发现了一些基因和蛋白质重叠。在通过 TWAS 和 PWAS 进行的磁共振成像测量中发现的许多重叠似乎与全因高血压相同。我们通过基因组富集和蛋白-蛋白相互作用网络方法,发现了许多与这些基因和蛋白相关的高房颤症潜在通路。这项研究的结果(1)突出了利用多组学技术更好地了解遗传学的益处,(2)为了解心脏结构和功能的变化与高血脂的关系提供了新的见解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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