St John's Institute of Dermatology, School of Basic and Medical Biosciences, King's College London, London, UK.
Br J Dermatol. 2021 Apr;184(4):606-616. doi: 10.1111/bjd.19384. Epub 2021 Feb 1.
Discovering the genetic basis of inherited skin diseases is fundamental to improving diagnostic accuracy and genetic counselling. In the 1990s and 2000s, genetic linkage and candidate gene approaches led to the molecular characterization of several dozen genodermatoses, but over the past decade the advent of next-generation sequencing (NGS) technologies has accelerated diagnostic discovery and precision.
This review examines the application of NGS technologies from 2009 to 2019 that have (i) led to the initial discovery of gene mutations in known or new genodermatoses and (ii) identified involvement of more than one contributing pathogenic gene in individuals with complex Mendelian skin disorder phenotypes.
A comprehensive review of the PubMed database and dermatology conference abstracts was undertaken between January 2009 and December 2019. The results were collated and cross-referenced with OMIM.
We identified 166 new disease-gene associations in inherited skin diseases discovered by NGS. Of these, 131 were previously recognized, while 35 were brand new disorders. Eighty-five were autosomal dominant (with 43 of 85 mutations occurring de novo), 78 were autosomal recessive and three were X-linked. We also identified 63 cases harbouring multiple pathogenic mutations, either involving two coexisting genodermatoses (n = 13) or an inherited skin disorder in conjunction with other organ system phenotypes (n = 50).
NGS technologies have accelerated disease-gene discoveries in dermatology over the last decade. Moreover, the era of NGS has enabled clinicians to split complex Mendelian phenotypes into separate diseases. These genetic data improve diagnostic precision and make feasible accurate prenatal testing and better-targeted translational research.
发现遗传性皮肤疾病的遗传基础对于提高诊断准确性和遗传咨询至关重要。在 20 世纪 90 年代和 21 世纪初,遗传连锁和候选基因方法导致了几十种遗传性皮肤病的分子特征描述,但在过去十年中,下一代测序(NGS)技术的出现加速了诊断发现和精准性。
本综述检查了 2009 年至 2019 年 NGS 技术的应用,这些技术(i)导致了已知或新的遗传性皮肤病中基因突变的初步发现,(ii)鉴定了复杂孟德尔皮肤疾病表型个体中多个致病基因的参与。
对 2009 年 1 月至 2019 年 12 月期间 PubMed 数据库和皮肤科会议摘要进行了全面综述。将结果进行了整理,并与 OMIM 进行了交叉参考。
我们确定了通过 NGS 发现的遗传性皮肤疾病中的 166 个新的疾病-基因关联。其中,131 个是先前公认的,而 35 个是全新的疾病。85 个为常染色体显性遗传(85 个突变中有 43 个是从头发生的),78 个为常染色体隐性遗传,3 个为 X 连锁遗传。我们还发现了 63 例携带多个致病突变的病例,要么涉及两种共存的遗传性皮肤病(n=13),要么涉及遗传性皮肤疾病与其他器官系统表型并存(n=50)。
在过去十年中,NGS 技术加速了皮肤科的疾病-基因发现。此外,NGS 时代使临床医生能够将复杂的孟德尔表型分为不同的疾病。这些遗传数据提高了诊断的精确性,并使可行的精确产前测试和更有针对性的转化研究成为可能。
