全面的全基因组序列分析为脑瘫的基因组结构提供了深入了解。

Comprehensive whole-genome sequence analyses provide insights into the genomic architecture of cerebral palsy.

机构信息

Division of Developmental Paediatrics, Holland Bloorview Kids Rehabilitation Hospital, Toronto, Ontario, Canada.

Department of Paediatrics, Faculty of Medicine, University of Toronto, Toronto, Ontario, Canada.

出版信息

Nat Genet. 2024 Apr;56(4):585-594. doi: 10.1038/s41588-024-01686-x. Epub 2024 Mar 29.

DOI:10.1038/s41588-024-01686-x

PMID:38553553

Abstract

We performed whole-genome sequencing (WGS) in 327 children with cerebral palsy (CP) and their biological parents. We classified 37 of 327 (11.3%) children as having pathogenic/likely pathogenic (P/LP) variants and 58 of 327 (17.7%) as having variants of uncertain significance. Multiple classes of P/LP variants included single-nucleotide variants (SNVs)/indels (6.7%), copy number variations (3.4%) and mitochondrial mutations (1.5%). The COL4A1 gene had the most P/LP SNVs. We also analyzed two pediatric control cohorts (n = 203 trios and n = 89 sib-pair families) to provide a baseline for de novo mutation rates and genetic burden analyses, the latter of which demonstrated associations between de novo deleterious variants and genes related to the nervous system. An enrichment analysis revealed previously undescribed plausible candidate CP genes (SMOC1, KDM5B, BCL11A and CYP51A1). A multifactorial CP risk profile and substantial presence of P/LP variants combine to support WGS in the diagnostic work-up across all CP and related phenotypes.

摘要

我们对 327 名脑瘫（CP）患儿及其亲生父母进行了全基因组测序（WGS）。我们将 327 名儿童中的 37 名（11.3%）归类为致病性/可能致病性（P/LP）变异，58 名（17.7%）归类为意义不明的变异。P/LP 变异的多个类别包括单核苷酸变异（SNVs）/插入缺失（6.7%）、拷贝数变异（3.4%）和线粒体突变（1.5%）。COL4A1 基因的 P/LP SNVs 最多。我们还分析了两个儿科对照队列（n=203 个三核苷酸和 n=89 个同胞对家庭），为新生突变率和遗传负担分析提供基线，后者表明新生有害变异与神经系统相关基因之间存在关联。富集分析揭示了以前未描述的可能的 CP 候选基因（SMOC1、KDM5B、BCL11A 和 CYP51A1）。多因素 CP 风险谱和大量 P/LP 变异的存在共同支持 WGS 在所有 CP 及其相关表型的诊断中应用。

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全面的全基因组序列分析为脑瘫的基因组结构提供了深入了解。

Comprehensive whole-genome sequence analyses provide insights into the genomic architecture of cerebral palsy.

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