Exploring the complexity of systemic sclerosis etiology by trio whole genome sequencing

候选基因 全基因组关联研究 遗传学 生物 基因 拷贝数变化 遗传关联 基因组 转录组 单核苷酸多态性 多发性硬化 基因型 免疫学 基因表达
作者
Hongzheng Dai,Shamika Ketkar,Taotao Tan,Elizabeth G. Atkinson,Lindsay C. Burrage,Kim C. Worley,Brian Christopher,Marka A. Lyons,Shervin Assassi,Maureen D. Mayes,Brendan Lee
出处
期刊:Human Molecular Genetics [Oxford University Press]
卷期号:33 (19): 1643-1647
标识
DOI:10.1093/hmg/ddae105
摘要

Abstract Systemic sclerosis (SSc) is a heterogeneous rare autoimmune fibrosing disorder affecting connective tissue. The etiology of systemic sclerosis is largely unknown and many genes have been suggested as susceptibility loci of modest impact by genome-wide association study (GWAS). Multiple factors can contribute to the pathological process of the disease, which makes it more difficult to identify possible disease-causing genetic alterations. In this study, we have applied whole genome sequencing (WGS) in 101 indexed family trios, supplemented with transcriptome sequencing on cultured fibroblast cells of four patients and five family controls where available. Single nucleotide variants (SNVs) and copy number variants (CNVs) were examined, with emphasis on de novo variants. We also performed enrichment test for rare variants in candidate genes previously proposed in association with systemic sclerosis. We identified 42 exonic and 34 ncRNA de novo SNV changes in 101 trios, from a total of over 6000 de novo variants genome wide. We observed higher than expected de novo variants in PRKXP1 gene. We also observed such phenomenon along with increased expression in patient group in NEK7 gene. Additionally, we also observed significant enrichment of rare variants in candidate genes in the patient cohort, further supporting the complexity/multi-factorial etiology of systemic sclerosis. Our findings identify new candidate genes including PRKXP1 and NEK7 for future studies in SSc. We observed rare variant enrichment in candidate genes previously proposed in association with SSc, which suggest more efforts should be pursued to further investigate possible pathogenetic mechanisms associated with those candidate genes.

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