连接蛋白30.3中的错义突变G12D可导致门德斯·达·科斯塔变异性红斑角皮病和戈特龙进行性对称性红斑角皮病。

The missense mutation G12D in connexin30.3 can cause both erythrokeratodermia variabilis of Mendes da Costa and progressive symmetric erythrokeratodermia of Gottron.

作者信息

van Steensel M A M, Oranje A P, van der Schroeff J G, Wagner A, van Geel M

机构信息

Department of Dermatology, Maastricht University Medical Center, Maastricht, The Netherlands.

出版信息

Am J Med Genet A. 2009 Feb 15;149A(4):657-61. doi: 10.1002/ajmg.a.32744.

DOI:10.1002/ajmg.a.32744

PMID:19291775

Abstract

Progressive symmetric erythrokeratoderma of Gottron (PSEK) is commonly distinguished from erythrokeratodermia variabilis Mendes da Costa (EKV). However, conclusive proof that the disorders are identical is still lacking. We performed mutation analysis and microsatellite haplotyping in two independently referred patients with PSEK and three patients from a previously published family with EKV. All patients had the same mutation in the GJB4 gene causing the amino acid substitution p.Gly12Asp (G12D). Haplotype analysis showed that all five patients had the same allelic haplotype over 2 Mb covering the disease locus. Apparently, the same GJB4 mutation may cause either an EKV or a PSEK phenotype. A single ancestral founder might have introduced EKV in the Netherlands.

摘要

戈特龙进行性对称性红斑角化病（PSEK）通常与门德斯·达·科斯塔可变红斑角化病（EKV）相区分。然而，仍缺乏确凿证据证明这两种疾病完全相同。我们对两名独立转诊的PSEK患者以及先前发表的一个EKV家族中的三名患者进行了突变分析和微卫星单倍型分析。所有患者的GJB4基因均发生相同突变，导致氨基酸替换p.Gly12Asp（G12D）。单倍型分析表明，所有五名患者在覆盖疾病位点的2 Mb区域内具有相同的等位基因单倍型。显然，相同的GJB4突变可能导致EKV或PSEK表型。一个单一的始祖可能将EKV引入了荷兰。

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连接蛋白30.3中的错义突变G12D可导致门德斯·达·科斯塔变异性红斑角皮病和戈特龙进行性对称性红斑角皮病。

The missense mutation G12D in connexin30.3 can cause both erythrokeratodermia variabilis of Mendes da Costa and progressive symmetric erythrokeratodermia of Gottron.

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