Molecular Diagnosis of Facioscapulohumeral Muscular Dystrophy in Patients Clinically Suspected of FSHD Using Optical Genome Mapping.

IF 3 3区医学 Q2 CLINICAL NEUROLOGY

Neurology-Genetics Pub Date : 2023-11-22 eCollection Date: 2023-12-01 DOI:10.1212/NXG.0000000000200107

Naga M Guruju, Vanessa Jump, Richard Lemmers, Silvere Van Der Maarel, Ruby Liu, Babi R Nallamilli, Suresh Shenoy, Alka Chaubey, Pratik Koppikar, Rajiv Rose, Satish Khadilkar, Madhuri Hegde

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引用次数: 0

Abstract

Background and objectives: Facioscapulohumeral muscular dystrophy (FSHD) represents the third most common muscular dystrophy in the general population and is characterized by progressive and often asymmetric muscle weakness of the face, upper extremities, arms, lower leg, and hip girdle. In FSHD type 1, contraction of the number of D4Z4 repeats to 1-10 on the chromosome 4-permissive allele (4qA) results in abnormal epigenetic derepression of the DUX4 gene in skeletal muscle. In FSHD type 2, epigenetic derepression of the DUX4 gene on the permissive allele (4qA) with normal-sized D4Z4 repeats (mostly 8-20) is caused by heterozygous pathogenic variants in chromatin modifier genes such as SMCHD1, DNMT3B, or LRIF1. We present validation of the optical genome mapping (OGM) platform for accurate mapping of the D4Z4 repeat size, followed by diagnostic testing of 547 cases with a suspected clinical diagnosis of FSHD and next-generation sequencing (NGS) of the SMCHD1 gene to identify cases with FSHD2.

Methods: OGM with Bionano Genomics Saphyr and EnFocus FSHD analysis software was used to identify FSHD haplotypes and D4Z4 repeat number and compared with the gold standard of Southern blot-based diagnosis. A custom Agilent SureSelect enrichment kit was used to enrich SMCHD1, followed by NGS on an Illumina system with 100-bp paired-end reads. Copy number variants were assessed using NxClinical software.

Results: We performed OGM for the diagnosis of FSHD in 547 patients suspected of FSHD between December 2019 and December 2022, including 301 male (55%) and 246 female patients (45%). Overall, 308 of the referred patients were positive for D4Z4 contraction on a permissive haplotype, resulting in a diagnosis of FSHD1. A total of 252 of 547 patients were referred for concurrent testing for FSHD1 and FSHD2. This resulted in the identification of FSHD2 in 9/252 (3.6%) patients. In our FSHD2 cohort, the 4qA allele size ranged from 8 to 18 repeats. Among FSHD1-positive cases, 2 patients had biallelic contraction and 4 patients had homozygous contraction and showed early onset of clinical features. Nine of the 308 patients (3%) positive for 4qA contraction had mosaic 4q alleles with contraction on at least one 4qA allele. The overall diagnostic yield in our cohort was 58%.

Discussion: A combination of OGM to identify the FSHD haplotype and D4Z4 repeat number and NGS to identify sequence and copy number variants in the SMCHD1 gene is a practical and cost-effective option with increased precision for accurate diagnosis of FSHD types 1 and 2.

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应用光学基因组图谱技术诊断疑似FSHD患者的面肩肱骨肌营养不良。

背景和目的:面肩肱骨肌营养不良(FSHD)是普通人群中第三大最常见的肌肉营养不良，其特征是面部、上肢、手臂、小腿和臀带的进行性且通常不对称的肌肉无力。在FSHD 1型中，4号染色体允许等位基因(4qA)上D4Z4重复数收缩至1-10，导致骨骼肌中DUX4基因的异常表观遗传抑制。在FSHD 2型中，具有正常大小D4Z4重复序列(主要为8-20)的允许等位基因(4qA)上DUX4基因的表观遗传抑制是由染色质修饰基因(如SMCHD1, DNMT3B或LRIF1)的杂合致病性变异引起的。我们验证了光学基因组定位(OGM)平台对D4Z4重复序列大小的准确定位，随后对547例疑似临床诊断为FSHD的病例进行了诊断测试，并对SMCHD1基因进行了下一代测序(NGS)以确定FSHD2病例。方法:采用Bionano Genomics Saphyr的OGM和EnFocus FSHD分析软件，鉴定FSHD单倍型和D4Z4重复数，并与Southern blot诊断的金标准进行比较。使用定制的Agilent SureSelect富集试剂盒富集SMCHD1，然后在Illumina系统上进行NGS，配对端读长为100 bp。使用NxClinical软件评估拷贝数变异。结果:2019年12月至2022年12月，我们对547例疑似FSHD患者行OGM诊断FSHD，其中男性301例(55%)，女性246例(45%)。总体而言，308例患者在允许单倍型上的D4Z4收缩呈阳性，从而诊断为FSHD1。547例患者中有252例接受FSHD1和FSHD2的同时检测。结果在9/252(3.6%)患者中鉴定出FSHD2。在我们的FSHD2队列中，4qA等位基因的大小范围为8到18个重复。fshd1阳性病例中，双等位基因收缩2例，纯合子收缩4例，均表现为早发性临床特征。308例4qA收缩阳性患者中有9例(3%)具有至少一个4qA等位基因收缩的马赛克4q等位基因。在我们的队列中，总诊断率为58%。讨论:结合OGM鉴定FSHD单倍型和D4Z4重复数和NGS鉴定SMCHD1基因的序列和拷贝数变异是一种实用且经济的选择，可提高FSHD 1型和2型的准确诊断精度。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Neurology-Genetics Medicine-Neurology (clinical)

CiteScore

6.30

自引率

3.20%

发文量

107

审稿时长

15 weeks

期刊介绍： Neurology: Genetics is an online open access journal publishing peer-reviewed reports in the field of neurogenetics. Original articles in all areas of neurogenetics will be published including rare and common genetic variation, genotype-phenotype correlations, outlier phenotypes as a result of mutations in known disease-genes, and genetic variations with a putative link to diseases. This will include studies reporting on genetic disease risk and pharmacogenomics. In addition, Neurology: Genetics will publish results of gene-based clinical trials (viral, ASO, etc.). Genetically engineered model systems are not a primary focus of Neurology: Genetics, but studies using model systems for treatment trials are welcome, including well-powered studies reporting negative results.