Rapid Targeted Next-Generation Sequencing Platform for Molecular Screening and Clinical Genotyping in Subjects with Hemoglobinopathies

Overview

Journal EBioMedicine

Specialty Biomedical Engineering

Date 2017 Sep 4

PMID 28865746

Citations 62

Authors

Xuan Shang

Zhiyu Peng

Yuhua Ye

Asan

Xinhua Zhang

Yan Chen

Baosheng Zhu

Wangwei Cai

Shaoke Chen

Ren Cai

Xiaoling Guo

Chonglin Zhang

Yuqiu Zhou

Shuodan Huang

Yanhui Liu

Biyan Chen

Shanhuo Yan

Yajun Chen

Hongmei Ding

Xiaolin Yin

Liusong Wu

Jing He

Dongai Huang

Sheng He

Tizhen Yan

Xin Fan

Yuehong Zhou

Xiaofeng Wei

Sumin Zhao

Decheng Cai

Fengyu Guo

Qianqian Zhang

Yun Li

Xuelian Zhang

Haorong Lu

Huajie Huang

Junfu Guo

Fei Zhu

Yuan Yuan

Li Zhang

Na Liu

Zhiming Li

Hui Jiang

Qiang Zhang

Yijia Zhang

Wan Khairunnisa Wan Juhari

Sarifah Hanafi

Wanjun Zhou

Fu Xiong

Huanming Yang

Jian Wang

Bin Alwi Zilfalil

Ming Qi

Yaping Yang

Ye Yin

Mao Mao

Xiangmin Xu

Affiliations

Soon will be listed here.

Abstract

Hemoglobinopathies are among the most common autosomal-recessive disorders worldwide. A comprehensive next-generation sequencing (NGS) test would greatly facilitate screening and diagnosis of these disorders. An NGS panel targeting the coding regions of hemoglobin genes and four modifier genes was designed. We validated the assay by using 2522 subjects affected with hemoglobinopathies and applied it to carrier testing in a cohort of 10,111 couples who were also screened through traditional methods. In the clinical genotyping analysis of 1182 β-thalassemia subjects, we identified a group of additional variants that can be used for accurate diagnosis. In the molecular screening analysis of the 10,111 couples, we detected 4180 individuals in total who carried 4840 mutant alleles, and identified 186 couples at risk of having affected offspring. 12.1% of the pathogenic or likely pathogenic variants identified by our NGS assay, which were undetectable by traditional methods. Compared with the traditional methods, our assay identified an additional at-risk 35 couples. We describe a comprehensive NGS-based test that offers advantages over the traditional screening/molecular testing methods. To our knowledge, this is among the first large-scale population study to systematically evaluate the application of an NGS technique in carrier screening and molecular diagnosis of hemoglobinopathies.

Citing Articles

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Rapid detection of genetic modifiers of β-thalassemia based on MALDI-TOF MS.

Huang L, Zhang Q, Ye Y, Long Y, Huang H, Niu C Ann Hematol. 2025; .

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Relevance of Next-Generation Sequencing in the Diagnosis of Thalassemia and Hemoglobinopathies: The Experience of Four Italian Diagnostic Hubs.

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Li Q, Li X, He S, Li J Front Pediatr. 2024; 12:1467760.

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