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Mutational Spectrum and Clinical Features of Patients with Variants Identified in an 8074 Hearing Loss Patient Cohort.变异患者的突变谱和临床特征在一个 8074 例听力损失患者队列中被鉴定。
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Novel Mutations in KCNQ4, LHFPL5 and COCH Genes in Iranian Families with Hearing Impairment.伊朗听力障碍家族中 KCNQ4、LHFPL5 和 COCH 基因的新突变。
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10
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Coch 中的新型功能丧失突变导致常染色体隐性非综合征性听力损失。

Novel loss-of-function mutations in COCH cause autosomal recessive nonsyndromic hearing loss.

机构信息

Molecular Otolaryngology and Renal Research Laboratories, Department of Otolaryngology, University of Iowa, Iowa City, IA, USA.

Department of Neurobiology, Harvard Medical School, Boston, MA, USA.

出版信息

Hum Genet. 2020 Dec;139(12):1565-1574. doi: 10.1007/s00439-020-02197-5. Epub 2020 Jun 19.

DOI:10.1007/s00439-020-02197-5
PMID:32562050
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7572817/
Abstract

COCH is the most abundantly expressed gene in the cochlea. Unsurprisingly, mutations in COCH underly hearing loss in mice and humans. Two forms of hearing loss are linked to mutations in COCH, the well-established autosomal dominant nonsyndromic hearing loss, with or without vestibular dysfunction (DFNA9) via a gain-of-function/dominant-negative mechanism, and more recently autosomal recessive nonsyndromic hearing loss (DFNB110) via nonsense variants. Using a combination of targeted gene panels, exome sequencing, and functional studies, we identified four novel pathogenic variants (two nonsense variants, one missense, and one inframe deletion) in COCH as the cause of autosomal recessive hearing loss in a multi-ethnic cohort. To investigate whether the non-truncating variants exert their effect via a loss-of-function mechanism, we used minigene splicing assays. Our data showed both the missense and inframe deletion variants altered RNA splicing by creating an exon splicing silencer and abolishing an exon splicing enhancer, respectively. Both variants create frameshifts and are predicted to result in a null allele. This study confirms the involvement of loss-of-function mutations in COCH in autosomal recessive nonsyndromic hearing loss, expands the mutational landscape of DFNB110 to include coding variants that alter RNA splicing, and highlights the need to investigate the effect of coding variants on RNA splicing.

摘要

COCH 是耳蜗中表达最丰富的基因。毫不奇怪,COCH 的突变导致了小鼠和人类的听力损失。两种形式的听力损失与 COCH 的突变有关,一种是已确立的常染色体显性非综合征性听力损失,具有或不伴有前庭功能障碍(DFNA9),通过获得功能/显性负性机制,最近还有常染色体隐性非综合征性听力损失(DFNB110)通过无意义变异。我们使用靶向基因panel、外显子组测序和功能研究,在一个多民族队列中发现 COCH 的四个新的致病性变异(两个无意义变异,一个错义变异和一个框内缺失)是常染色体隐性听力损失的原因。为了研究非截断变异是否通过失活机制发挥作用,我们使用了小型基因拼接分析。我们的数据表明,错义变异和框内缺失变异通过创建外显子拼接沉默子和消除外显子拼接增强子分别改变 RNA 拼接。这两种变异都产生移码,并预测会导致无效等位基因。这项研究证实了 COCH 中的失活突变在常染色体隐性非综合征性听力损失中的作用,扩大了 DFNB110 的突变景观,包括改变 RNA 拼接的编码变异,并强调了需要研究编码变异对 RNA 拼接的影响。