Pathway Analysis Integrating Genome-Wide and Functional Data Identifies PLCG2 as a Candidate Gene for Age-Related Macular Degeneration.

Q4 Agricultural and Biological Sciences International Journal on Algae Pub Date : 2019-09-03 DOI:10.1167/iovs.19-27827

Andrea R Waksmunski, Michelle Grunin, Tyler G Kinzy, Robert P Igo, Jonathan L Haines, Jessica N Cooke Bailey

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Abstract

Purpose: Age-related macular degeneration (AMD) is the worldwide leading cause of blindness among the elderly. Although genome-wide association studies (GWAS) have identified AMD risk variants, their roles in disease etiology are not well-characterized, and they only explain a portion of AMD heritability.

Methods: We performed pathway analyses using summary statistics from the International AMD Genomics Consortium's 2016 GWAS and multiple pathway databases to identify biological pathways wherein genetic association signals for AMD may be aggregating. We determined which genes contributed most to significant pathway signals across the databases. We characterized these genes by constructing protein-protein interaction networks and performing motif analysis.

Results: We determined that eight genes (C2, C3, LIPC, MICA, NOTCH4, PLCG2, PPARA, and RAD51B) "drive" the statistical signals observed across pathways curated in the Kyoto Encyclopedia of Genes and Genomes (KEGG), Reactome, and Gene Ontology (GO) databases. We further refined our definition of statistical driver gene to identify PLCG2 as a candidate gene for AMD due to its significant gene-level signals (P < 0.0001) across KEGG, Reactome, GO, and NetPath pathways.

Conclusions: We performed pathway analyses on the largest available collection of advanced AMD cases and controls in the world. Eight genes strongly contributed to significant pathways from the three larger databases, and one gene (PLCG2) was central to significant pathways from all four databases. This is, to our knowledge, the first study to identify PLCG2 as a candidate gene for AMD based solely on genetic burden. Our findings reinforce the utility of integrating in silico genetic and biological pathway data to investigate the genetic architecture of AMD.

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整合全基因组和功能数据的通路分析发现 PLCG2 是老年性黄斑变性的候选基因

目的：年龄相关性黄斑变性（AMD）是全球老年人失明的主要原因。尽管全基因组关联研究（GWAS）已经发现了AMD风险变异，但它们在疾病病因学中的作用还没有得到很好的描述，而且它们只能解释AMD遗传性的一部分：我们利用国际AMD基因组学联盟2016年GWAS和多个通路数据库的汇总统计数据进行了通路分析，以确定AMD遗传关联信号可能聚集的生物通路。我们确定了哪些基因对数据库中的重要通路信号贡献最大。我们通过构建蛋白质-蛋白质相互作用网络和进行主题分析来确定这些基因的特征：我们确定了八个基因（C2、C3、LIPC、MICA、NOTCH4、PLCG2、PPARA 和 RAD51B）"驱动 "了在京都基因和基因组百科全书 (KEGG)、反应组 (Reactome) 和基因本体 (GO) 数据库策划的通路中观察到的统计信号。我们进一步完善了统计驱动基因的定义，将PLCG2确定为AMD的候选基因，因为它在KEGG、Reactome、GO和NetPath通路中具有显著的基因水平信号（P<0.0001）：我们对世界上最大的晚期AMD病例和对照进行了通路分析。八个基因对三个较大数据库中的重要通路做出了重大贡献，一个基因（PLCG2）是所有四个数据库中重要通路的核心基因。据我们所知，这是第一项完全基于遗传负荷将 PLCG2 确定为老年性痴呆候选基因的研究。我们的研究结果进一步证实了整合硅学遗传和生物通路数据来研究 AMD 遗传结构的实用性。

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来源期刊

International Journal on Algae Agricultural and Biological Sciences-Plant Science

CiteScore

0.40

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0.00%

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期刊介绍： The algae are heterogeneous assemblage of phytosynthetic organisms, one of the most vast and diverse groups of ancient photoautotrophic pro- and eukaryotic organisms (about 30 000 known species). They are micro- and macroscopic, unicellular, colonial, or multicellular, mobile and immobile, attached and free-living. Algae are widespread in water and soil habitats, at different geographic latitudes, and on all continents. They occur in waters with different degrees of salinity, trophicity, organic matter, and hydrogen ions, and at various temperatures. They include planktonic, periphytonic and benthic organisms. Algae are unique model organisms in evolutionary biology and also are used in various genetic, physiological, biochemical, cytological, and other investigations.