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Genome Sequencing Reveals the Role of Rare Genomic Variants in Chinese Patients with Symptomatic Intracranial Atherosclerotic Disease

Overview

Overview

Journal Stroke Vasc Neurol

Specialty Cardiology & Vascular Diseases

Date 2021 Dec 9

PMID 34880113

Citations 2

Authors

Authors

Mengmeng Shi

Xinyi Leng

Ying Li

Zihan Chen

Ye Cao

Tiffany Chung

Bonaventure Ym Ip

Vincent Hl Ip

Yannie Oy Soo

Florence Sy Fan

Sze Ho Ma

Karen Ma

Anne Y Y Chan

Lisa Wc Au

Howan Leung

Alexander Y Lau

Vincent Ct Mok

Kwong Wai Choy

Zirui Dong

Thomas W Leung

Affiliations

Affiliations

Soon will be listed here.

Abstract

Objectives: The predisposition of intracranial atherosclerotic disease (ICAD) to East Asians over Caucasians infers a genetic basis which, however, remains largely unknown. Higher prevalence of vascular risk factors (VRFs) in Chinese over Caucasian patients who had a stroke, and shared risk factors of ICAD with other stroke subtypes indicate genes related to VRFs and/or other stroke subtypes may also contribute to ICAD.

Methods: Unrelated symptomatic patients with ICAD were recruited for genome sequencing (GS, 60-fold). Rare and potentially deleterious single-nucleotide variants (SNVs) and small insertions/deletions (InDels) were detected in genome-wide and correlated to genes related to VRFs and/or other stroke subtypes. Rare aneuploidies, copy number variants (CNVs) and chromosomal structural rearrangements were also investigated. Lastly, candidate genes were used for pathway and gene ontology enrichment analysis.

Results: Among 92 patients (mean age at stroke onset 61.0±9.3 years), GS identified likely ICAD-associated rare genomic variants in 54.3% (50/92) of patients. Forty-eight patients (52.2%, 48/92) had 59 rare SNVs/InDels reported or predicted to be deleterious in genes related to VRFs and/or other stroke subtypes. None of the 59 rare variants were identified in local subjects without ICAD (n=126). 31 SNVs/InDels were related to conventional VRFs, and 28 were discovered in genes related to other stroke subtypes. Our study also showed that rare CNVs (n=7) and structural rearrangement (a balanced translocation) were potentially related to ICAD in 8.7% (8/92) of patients. Lastly, candidate genes were significantly enriched in pathways related to lipoprotein metabolism and cellular lipid catabolic process.

Conclusions: Our GS study suggests a role of rare genomic variants with various variant types contributing to the development of ICAD in Chinese patients.

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