Uncovering thalassemia diversity in southern china through next-generation sequencing
Around 5.2% of the global population carries abnormal hemoglobin genes [1]. Each year, 300,000 to 500,000 children are born with severe hemoglobinopathies worldwide, with approximately 80% of these cases occurring in developing countries [2]. Thalassemia is the most common hereditary hemoglobinopathy and occurs in 4.4 out of every 10,000 live births [3]. It is prevalent […]
Around 5.2% of the global population carries abnormal hemoglobin genes [1]. Each year, 300,000 to 500,000 children are born with severe hemoglobinopathies worldwide, with approximately 80% of these cases occurring in developing countries [2]. Thalassemia is the most common hereditary hemoglobinopathy and occurs in 4.4 out of every 10,000 live births [3]. It is prevalent in Mediterranean coastal areas, Africa, the Middle East, Southeast Asia, and southern China.
Credit: BGI Genomics
Around 5.2% of the global population carries abnormal hemoglobin genes [1]. Each year, 300,000 to 500,000 children are born with severe hemoglobinopathies worldwide, with approximately 80% of these cases occurring in developing countries [2]. Thalassemia is the most common hereditary hemoglobinopathy and occurs in 4.4 out of every 10,000 live births [3]. It is prevalent in Mediterranean coastal areas, Africa, the Middle East, Southeast Asia, and southern China.
A previous study indicated that Ganzhou, the southernmost city in Jiangxi province, had a thalassemia prevalence as high as 9.49% [4]. Still, it had limitations in terms of small sample size, non-representative population and limited mutation spectrum. A new study by Tong Yang, Xuemei Luo, Yanqiu Liu, Wenqian Zhang (BGI Genomics, Senior Manager Clinical Research) et al. published on August 18, 2023 in Human Genomics looks at the prevalence and mutation spectrum of thalassemia in Ganzhou based on a large-scale thalassemia screening project involving 136,312 individuals.
Method:
In this study, the researchers retrospectively analyzed 136,312 individuals who participated in the “Implementation Plan for the Free Gene Detection of Thalassemia in Ganzhou City (2019–2022)”.
Key findings:
1. Found a total of 19,827 (14.545%) thalassemia carriers, including 14,298 (10.489%) α-thalassemia carriers, 4,921 (3.610%) β-thalassemia, and 608 (0.446%) combined α- and β-thalassemia carriers.
2. A total of 156 distinct thalassemia genotypes were identified, comprising 40 α-thalassemia genotypes, 42 β-thalassemia genotypes and 74 combined α-/β-thalassemia genotypes. 48 rare thalassemia mutations were identified, such as 5’UTR +43 to +40 (-AAAC), Chinese Gγ+(Aγδβ)0, –THAI, αfusion, -50 G > A, and Hb Phnom Penh.
3. The prevalence of thalassemia was higher in the southeastern Jiangxi Province at the junction of Fujian, Guangdong, and Jiangxi Provinces. In particular, Dingnan and Xunwu had a high prevalence of 18.3% and 17.7%, respectively.
4. Next-Generation Sequencing (NGS) techniques perform better than conventional thalassemia genetic screening methods, especially in identifying novel or rare thalassemia mutations. Limited by the low sensitivity of hematological analysis and the disadvantages of Polymerase chain reaction (PCR), a large number of novel or rare thalassemia variations would be missed or misdiagnosed using traditional screening methods. NGS is also a cost-effective tool for prenatal screening.
This study utilized large-scale thalassemia screening through NGS to uncover the prevalence and mutation spectrum of thalassemia in Ganzhou, demonstrating that thalassemia is a serious public health problem in this region. The findings will be very important for thalassemia prevention and control in Ganzhou and other high-prevalence areas. More importantly, the identification of rare and novel variations highlighted the necessity and significance of choosing NGS for thalassemia screening in large populations.
This study was approved by the Ethics Committee of the First Affiliated Hospital of Gannan Medical University.
References:
[1] Modell B, Darlison M. Global epidemiology of hemoglobin disorders and derived service indicators. Bulletin of the World Health Organization 2008; 86(6):480-7.
[2] WHO TIF Meeting on the Management of Haemoglobin Disorders, World Health Organization, Thalassaemia International Federation. Management of hemoglobin disorders: report of a joint WHO-TIF meeting, Nicosia, Cyprus, 16-18 November 2007. Geneva: World Health Organization; 2008.
[3] Kadhim, K. A., Baldawi, K. H., & Lami, F. H. (2017). Prevalence, Incidence, Trend, and Complications of Thalassemia in Iraq. Hemoglobin, 41(3), 164–168. https://doi.org/10.1080/03630269.2017.1354877
[4] Lin M, Zhong T-Y, Chen Y-G, Wang J-Z, Wu J-R, Lin F, et al. Molecular epidemiological characterization and health burden of thalassemia in Jiangxi Province, P. R. China. PloS One
Learn more about BGI Genomics strategy to control hemoglobinopathies worldwide:
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About BGI Genomics:
BGI Genomics, headquartered in Shenzhen, China, is the world’s leading integrated solutions provider of precision medicine. Our services cover more than 100 countries and regions, involving more than 2,300 medical institutions. In July of 2017, as a subsidiary of BGI Group, BGI Genomics (300676.SZ) was officially listed on the Shenzhen Stock Exchange.
Journal
Human Genomics
DOI
10.1186/s40246-023-00520-5
Method of Research
Observational study
Subject of Research
People
Article Title
Next-generation sequencing analysis of the molecular spectrum of thalassemia in Southern Jiangxi, China
Article Publication Date
17-Aug-2023
COI Statement
This study was also approved by the Ganzhou Municipal Health Commission and was conducted in accordance with the ethical guidelines for research on human subjects.
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