Xiangzhong Sun scite author profile

Genetic variants in the GJB2 gene are the most frequent causes of congenital and childhood hearing loss worldwide. In addition to nonsyndromic hearing loss, GJB2 pathogenic variants are also correlated with syndromic phenotypes, showing high genetic and phenotypic heterogeneity. To comprehensively delineate the genetic and phenotypic landscape of GJB2 variants, we interpreted and manually curated all the 2043 possible single-nucleotide substitution (SNS) coding variants in this gene following the hearing loss-specific ACMG/AMP guidelines. As a result, 61 (3.0%), 188 (9.2%), 1487 (72.8%), 301 (14.7%) and 6 (0.3%) variants were classified as pathogenic, likely pathogenic, variant of uncertain significance, likely benign and benign, respectively. Interestingly, 54% (84/156) of pathogenic/likely pathogenic missense variants were not recorded in ClinVar. Further analysis showed that the second transmembrane domain (TM2) and the 310 helix are highly enriched for pathogenic missense variants. The N-terminal tail and the extracellular loop (E1) showed a high density of variants that are associated with syndromic or dominant nonsyndromic hearing loss. On the other hand, the intracellular loops (CL and CT) were extremely tolerant to variation. Based on this new information, we propose refinements of the guidelines for variant interpretation in GJB2. In summary, our study interpreted all possible SNS variants in the coding region of the GJB2 gene, characterized novel clinically significant (N = 249) and benign or likely benign (N = 307) in this gene, and revealed significant genotype-phenotype correlations at this common hearing loss locus.The interpretation of GJB2 SNS variants in the coding region provides a prototype for genes with similarly high genetic and phenotypic heterogeneity.

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Comprehensive genetic testing improves the clinical diagnosis and medical management of pediatric patients with isolated hearing loss

Xiang

Yuan

Song

et al. 2022

BMC Med Genomics

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Purpose Genetic testing is widely used in diagnosing genetic hearing loss in patients. Other than providing genetic etiology, the benefits of genetic testing in pediatric patients with hearing loss are less investigated. Methods From 2018–2020, pediatric patients who initially presented isolated hearing loss were enrolled. Comprehensive genetic testing, including GJB2/SLC26A4 multiplex amplicon sequencing, STRC/OTOA copy number variation analysis, and exome sequencing, were hierarchically offered. Clinical follow-up and examinations were performed. Results A total of 80 pediatric patients who initially presented isolated hearing loss were considered as nonsyndromic hearing loss and enrolled in this study. The definitive diagnosis yield was 66% (53/80) and the likely diagnosis yield was 8% (6/80) through comprehensive genetic testing. With the aid of genetic testing and further clinical follow-up and examinations, the clinical diagnoses and medical management were altered in eleven patients (19%, 11/59); five were syndromic hearing loss; six were nonsyndromic hearing loss mimics. Conclusion Syndromic hearing loss and nonsyndromic hearing loss mimics are common in pediatric patients who initially present with isolated hearing loss. The comprehensive genetic testing provides not only a high diagnostic yield but also valuable information for clinicians to uncover subclinical or pre-symptomatic phenotypes, which allows early diagnosis of SHL, and leads to precise genetic counseling and changes the medical management.

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The Next Generation of Population-Based DFNB16 Carrier Screening and Diagnosis: STRC Copy-Number Variant Analysis from Genome Sequencing Data

Xiang

Peng

Sun

et al. 2023

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Background Deafness, autosomal recessive 16 (DFNB16) is caused by compound heterozygous or homozygous variants in STRC and is the second most common form of genetic hearing loss. Due to the nearly identical sequences of STRC and the pseudogene STRCP1, analysis of this region is challenging in clinical testing. Methods We developed a method that accurately identifies the copy number of STRC and STRCP1 using standard short-read genome sequencing. Then, we used whole genome sequencing (WGS) data to investigate the population distribution of STRC copy number in 6813 neonates and the correlation between STRC and STRCP1 copy number. Results The comparison of WGS results with multiplex ligation-dependent probe amplification demonstrated high sensitivity (100%; 95% CI, 97.5%–100%) and specificity (98.8%; 95% CI, 97.7%–99.5%) in detecting heterozygous deletion of STRC from short-read genome sequencing data. The population analysis revealed that 5.22% of the general population has STRC copy number changes, almost half of which (2.33%; 95% CI, 1.99%–2.72%) were clinically significant, including heterozygous and homozygous STRC deletions. There was a strong inverse correlation between STRC and STRCP1 copy number. Conclusions We developed a novel and reliable method to determine STRC copy number based on standard short-read based WGS data. Incorporating this method into analytic pipelines would improve the clinical utility of WGS in the screening and diagnosis of hearing loss. Finally, we provide population-based evidence of pseudogene-mediated gene conversions between STRC and STRCP1.

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Utility of Whole Genome Sequencing for Population Screening of Deafness-Related Genetic Variants and Cytomegalovirus Infection in Newborns

et al. 2022

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Background: Hearing loss affects approximately two out of every 1,000 newborns. Genetic factors and congenital cytomegalovirus (CMV) infections account for around 90% of the etiology. The purpose of this study was to develop and test a whole genome sequencing (WGS) approach to detect deafness-related genetic variants and CMV infections simultaneously in newborns.Method: Deafness-related genes causing congenital or childhood hearing loss were curated and selected for newborn screening. Nine dried blood spots from newborns with known genetic variants (n = 6) or CMV infections (n = 3) were employed to develop and validate the WGS testing and analytic pipeline. We then pilot tested the WGS analysis on 51 de-identified clinical samples.Results: 92 gene-disease pairs were selected for screening hearing loss in newborns. In the validation test, WGS accurately detected all types of genetic variants, including single nucleotide variations, insertions/deletions, and copy number variations in the nuclear or mitochondrial genome. Sequence reads mapping to the CMV reference genome were discovered in CMV infected samples. In the pilot test, WGS identified nine out of 51 (18%) newborns carrying pathogenic variants associated with deafness.Conclusion: WGS can simultaneously detect genetic variants and CMV infections in dried blood spot specimens from newborns. Our study provides proof of principle that genome sequencing can be a promising alternative for newborn screening of hearing loss.

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Xiangzhong Sun

Comprehensive interpretation of single-nucleotide substitutions in GJB2 reveals the genetic and phenotypic landscape of GJB2-related hearing loss

Comprehensive genetic testing improves the clinical diagnosis and medical management of pediatric patients with isolated hearing loss

The Next Generation of Population-Based DFNB16 Carrier Screening and Diagnosis: STRC Copy-Number Variant Analysis from Genome Sequencing Data

Utility of Whole Genome Sequencing for Population Screening of Deafness-Related Genetic Variants and Cytomegalovirus Infection in Newborns

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