Integrative modeling of transmitted and de novo variants identifies novel risk genes for congenital heart disease.

IF 0.6 4区生物学 Q4 MATHEMATICAL & COMPUTATIONAL BIOLOGY Quantitative Biology Pub Date : 2021-06-01 DOI:10.15302/j-qb-021-0248

Mo Li, Xue Zeng, Chentian Jin, S. Jin, W. Dong, Martina Brueckner, R. Lifton, Q. Lu, Hongyu Zhao

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引用次数: 4

Abstract

Background Whole-exome sequencing (WES) studies have identified multiple genes enriched for de novo mutations (DNMs) in congenital heart disease (CHD) probands. However, risk gene identification based on DNMs alone remains statistically challenging due to heterogenous etiology of CHD and low mutation rate in each gene. Methods In this manuscript, we introduce a hierarchical Bayesian framework for gene-level association test which jointly analyzes de novo and rare transmitted variants. Through integrative modeling of multiple types of genetic variants, gene-level annotations, and reference data from large population cohorts, our method accurately characterizes the expected frequencies of both de novo and transmitted variants and shows improved statistical power compared to analyses based on DNMs only. Results Applied to WES data of 2,645 CHD proband-parent trios, our method identified 15 significant genes, half of which are novel, leading to new insights into the genetic bases of CHD. Conclusion These results showcase the power of integrative analysis of transmitted and de novo variants for disease gene discovery.

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传播和新发变异的综合建模确定了先天性心脏病的新风险基因。

全外显子组测序(WES)研究已经在先天性心脏病(CHD)先显子中发现了多个富集新发突变(dnm)的基因。然而，由于冠心病的病因异质性和每个基因的低突变率，仅基于dnm的风险基因识别在统计上仍然具有挑战性。方法引入层次贝叶斯关联检验框架，对新发变异和罕见遗传变异进行联合分析。通过对多种类型的遗传变异、基因水平注释和来自大群体队列的参考数据的综合建模，我们的方法准确地表征了新生和传播变异的预期频率，与仅基于dnm的分析相比，显示出更高的统计能力。结果应用于2645例冠心病先证父母三人组的WES数据，我们的方法鉴定出15个重要基因，其中一半是新的基因，为冠心病的遗传基础提供了新的见解。结论这些结果显示了遗传变异和新生变异的综合分析在疾病基因发现中的作用。

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来源期刊

Quantitative Biology MATHEMATICAL & COMPUTATIONAL BIOLOGY-

CiteScore

5.00

自引率

3.20%

发文量

264

期刊介绍： Quantitative Biology is an interdisciplinary journal that focuses on original research that uses quantitative approaches and technologies to analyze and integrate biological systems, construct and model engineered life systems, and gain a deeper understanding of the life sciences. It aims to provide a platform for not only the analysis but also the integration and construction of biological systems. It is a quarterly journal seeking to provide an inter- and multi-disciplinary forum for a broad blend of peer-reviewed academic papers in order to promote rapid communication and exchange between scientists in the East and the West. The content of Quantitative Biology will mainly focus on the two broad and related areas: ·bioinformatics and computational biology, which focuses on dealing with information technologies and computational methodologies that can efficiently and accurately manipulate –omics data and transform molecular information into biological knowledge. ·systems and synthetic biology, which focuses on complex interactions in biological systems and the emergent functional properties, and on the design and construction of new biological functions and systems. Its goal is to reflect the significant advances made in quantitatively investigating and modeling both natural and engineered life systems at the molecular and higher levels. The journal particularly encourages original papers that link novel theory with cutting-edge experiments, especially in the newly emerging and multi-disciplinary areas of research. The journal also welcomes high-quality reviews and perspective articles.