High resolution melting curve analysis targeting the HBB gene mutational hot-spot offers a reliable screening approach for all common as well as most of the rare beta-globin gene mutations in Bangladesh
Md Tarikul Islam,
Suprovath Kumar Sarkar,
Nusrat Sultana,
Mst. Noorjahan Begum,
Golam Sarower Bhuyan,
Shezote Talukder,
A. K. M. Muraduzzaman,
Md Alauddin,
Mohammad Sazzadul Islam,
Pritha Promita Biswas,
Aparna Biswas,
Syeda Kashfi Qadri,
Tahmina Shirin,
Bilquis Banu,
Salma Sadya,
Manzoor Hussain,
Golam Sarwardi,
Waqar Ahmed Khan,
Mohammad Abdul Mannan,
Hossain Uddin Shekhar,
Emran Kabir Chowdhury,
Abu Ashfaqur Sajib,
Sharif Akhteruzzaman,
Syed Saleheen Qadri,
Firdausi Qadri,
Kaiissar Mannoor
Affiliations
Md Tarikul Islam
Laboratory of Genetics and Genomics, Institute for Developing Science and Health Initiatives
Suprovath Kumar Sarkar
Laboratory of Genetics and Genomics, Institute for Developing Science and Health Initiatives
Nusrat Sultana
Laboratory of Genetics and Genomics, Institute for Developing Science and Health Initiatives
Mst. Noorjahan Begum
Laboratory of Genetics and Genomics, Institute for Developing Science and Health Initiatives
Golam Sarower Bhuyan
Infectious Diseases Laboratory, Institute for Developing Science and Health Initiatives
Shezote Talukder
Laboratory of Genetics and Genomics, Institute for Developing Science and Health Initiatives
A. K. M. Muraduzzaman
Department of Virology, Institute of Epidemiology, Disease Control and Research
Md Alauddin
Laboratory of Genetics and Genomics, Institute for Developing Science and Health Initiatives
Mohammad Sazzadul Islam
Infectious Diseases Laboratory, Institute for Developing Science and Health Initiatives
Pritha Promita Biswas
Laboratory of Genetics and Genomics, Institute for Developing Science and Health Initiatives
Aparna Biswas
Laboratory of Genetics and Genomics, Institute for Developing Science and Health Initiatives
Syeda Kashfi Qadri
Department of Paediatric Medicine, KK Women’s and Children’s Hospital
Tahmina Shirin
Department of Virology, Institute of Epidemiology, Disease Control and Research
Bilquis Banu
Department of Biochemistry and Molecular Biology, Dhaka Shishu Hospital
Salma Sadya
Department of Biochemistry and Molecular Biology, Dhaka Shishu Hospital
Manzoor Hussain
Department of Biochemistry and Molecular Biology, Dhaka Shishu Hospital
Golam Sarwardi
Department of Biochemistry and Molecular Biology, Dhaka Shishu Hospital
Waqar Ahmed Khan
Department of Biochemistry and Molecular Biology, Dhaka Shishu Hospital
Mohammad Abdul Mannan
Department of Neonatology, Bangabandhu Sheikh Mujib Medical University
Hossain Uddin Shekhar
Department of Biochemistry and Molecular Biology, University of Dhaka
Emran Kabir Chowdhury
Department of Biochemistry and Molecular Biology, University of Dhaka
Abu Ashfaqur Sajib
Department of Genetic Engineering & Biotechnology, University of Dhaka
Sharif Akhteruzzaman
Department of Genetic Engineering & Biotechnology, University of Dhaka
Syed Saleheen Qadri
Laboratory of Genetics and Genomics, Institute for Developing Science and Health Initiatives
Firdausi Qadri
Laboratory of Genetics and Genomics, Institute for Developing Science and Health Initiatives
Kaiissar Mannoor
Laboratory of Genetics and Genomics, Institute for Developing Science and Health Initiatives
Abstract Background Bangladesh lies in the global thalassemia belt, which has a defined mutational hot-spot in the beta-globin gene. The high carrier frequencies of beta-thalassemia trait and hemoglobin E-trait in Bangladesh necessitate a reliable DNA-based carrier screening approach that could supplement the use of hematological and electrophoretic indices to overcome the barriers of carrier screening. With this view in mind, the study aimed to establish a high resolution melting (HRM) curve-based rapid and reliable mutation screening method targeting the mutational hot-spot of South Asian and Southeast Asian countries that encompasses exon-1 (c.1 - c.92), intron-1 (c.92 + 1 - c.92 + 130) and a portion of exon-2 (c.93 - c.217) of the HBB gene which harbors more than 95% of mutant alleles responsible for beta-thalassemia in Bangladesh. Results Our HRM approach could successfully differentiate ten beta-globin gene mutations, namely c.79G > A, c.92 + 5G > C, c.126_129delCTTT, c.27_28insG, c.46delT, c.47G > A, c.92G > C, c.92 + 130G > C, c.126delC and c.135delC in heterozygous states from the wild type alleles, implying the significance of the approach for carrier screening as the first three of these mutations account for ~85% of total mutant alleles in Bangladesh. Moreover, different combinations of compound heterozygous mutations were found to generate melt curves that were distinct from the wild type alleles and from one another. Based on the findings, sixteen reference samples were run in parallel to 41 unknown specimens to perform direct genotyping of the beta-thalassemia specimens using HRM. The HRM-based genotyping of the unknown specimens showed 100% consistency with the sequencing result. Conclusions Targeting the mutational hot-spot, the HRM approach could be successfully applied for screening of beta-thalassemia carriers in Bangladesh as well as in other countries of South Asia and Southeast Asia. The approach could be a useful supplement of hematological and electrophortic indices in order to avoid false positive and false negative results.
