Case report
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Compound Heterozygous Sickle Cell-ß-Thalassemia: A Case Report from Upper Assam, India |
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Anju Barhai Teli, Rumi Deori, Sidhartha Protim Saikia, Bipul Ch. Kalita 1. Associate Professor, Department of Biochemistry, Assam Medical College & Hospital, Dibrugarh, Assam, India. 2. Assistant Professor, Department of Biochemistry, Assam Medical College & Hospital, Dibrugarh, Assam, India. 3. Senior Research Fellow, Department of Anatomy, Assam Medical College & Hospital, Dibrugarh, Assam, India. 4. Associate Professor, Department of Medicine, Assam Medical College & Hospital, Dibrugarh, Assam, India. |
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Correspondence
Address : Mr. Sidhartha Protim Saikia, Department of Anatomy, Assam Medical College & Hospital, Dibrugarh-786002, Assam, India. E-mail: sidharth_saikia@hotmail.com |
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ABSTRACT | |||||||||||||||||||||||||||||||||||||||||
Sickle cell-ß-thalassemia [Hb S/ß- thalassemia] is a rare type of hemoglobinopathy. The clinical characteristics of Hb S/ß- thalassemia are highly variable from a completely asymptomatic state to a severe disorder like homozygous sickle cell disease. In India IVS I-5 (G?C) is the most common ß-thalassemia allele. In this study we presented a case of compound heterozygous Hb S/ß- thalassemia in a 14-year-old female with complaints of anemia with weakness, joint pain and splenomegaly. The patient and her parents were diagnosed by HPLC and for detection of mutational pattern of ß-thalassemia; ARMS-PCR and DNA sequencing were performed. The HPLC report suggested that the patient have Hb S/ß- thalassemia and molecular diagnosis confirmed that the patient inherited IVS I-5 (G?C) ß- thalassemia mutation. | |||||||||||||||||||||||||||||||||||||||||
Keywords : Anemia, ARMS-PCR, DNA sequencing, HPLC | |||||||||||||||||||||||||||||||||||||||||
CASE REPORT | |||||||||||||||||||||||||||||||||||||||||
A 14-year-old female with complaints of anemia with weakness, joint pain and stomach pain presented in the Outpatient Department of Pediatrics. After taking informed consent systemic examination of the patient was done and the patient’s spleen was found to be enlarged. Blood samples of the patient and her parents were collected in EDTA vials after obtaining informed consent. Hematological data of the blood samples were determined on an automated blood cell counter (SYSMEX XS-800i, Japan) and the hemoglobin typing was performed by high performance liquid chromatography (HPLC) using the BIORAD D10 Hemoglobin Testing System. The hematological analysis showed that the patient was anemic (Table/Fig 1). The hemoglobin typing results (Table/Fig 2) revealed that the patient was compound heterozygous for Hb S/ß- thalassemia, the father had ßthalassemia trait and the mother had sickle cell trait. Molecular analysis was done to identify ß- thalassemia mutation pattern associated with the patient. Genomic DNA was extracted by using QIAamp® DNA Blood Mini Kit (QIAGEN, Germany) for doing amplification refractory mutation system polymerase chain reaction (ARMS-PCR). ARMS-PCR was done following standard protocol (1). Amplification was carried out in a 50µl reaction mixture containing 10x PCR buffer, 200µM dNTPs and 1.5mM MgCl2. All the required primers, 2µl of DNA sample, 0.5U of GoTaq® Flexi DNA Polymerase and nuclease free water were added to the reaction mixture. Amplification was carried out in an Arktik™ Thermal Cycler (Thermo Scientific, USA) as following sequence: 940C for 5 minutes followed by 30 cycles of 940C for 45 second, 650C for 45 seconds and 720C for 1.5 minutes, with a final extension at 720C for 7 minutes. Then 15µl aliquot of the PCR product was separated on a 1.5% agarose gel in 1x Tris-borat-EDTA (TBE) buffer. The gel was stained with ethidium bromide and visualized under gel documentation system for the result. ARMS-PCR revealed that the ß- thalassemia mutation pattern inherited by the patient was IVS I-5 (G?C) mutation (Table/Fig 3). The same mutation pattern was also found in the patient’s father (Table/Fig 3). Finally the PCR products were sequenced by automated DNA sequencer based on Sanger method to confirm the IVS I-5 (G?C) mutation (Table/Fig 4). After complete diagnosis; folic acid course and 2 units of blood transfusion had been given to the patient. Follow-up of the patient had been done after confirmation of diagnosis along with genetic counseling. | |||||||||||||||||||||||||||||||||||||||||
DISCUSSION | |||||||||||||||||||||||||||||||||||||||||
Thalassemia and sickle cell disease have impacting on the population of low income countries (2). The combination of the sickle cell mutation and ß-thalassemia mutation results Hb S/ß- thalassemia. In India 52 mutations accounted for 97.5% of all ß-thalassemia alleles and IVS I-5 (G?C) is the most common disease allele (54.7%) (3). The prevalence of IVS I-5 (G?C) is 44.8% in the North and 71.4% in the East India (3). Hb S/ß- thalassemia disease is a hemoglobinopathy. Clinically, the disorder causes symptoms of moderate anemia and signs of sickle cell anemia. The incidence of ß - thalassemia trait and sickle cell hemoglobinopathy in India varies between 3-17% and 1-44% respectively (4),(5). ß- thalassemia is characterized by its genetic heterogeneity at the molecular level and more than 300 mutations of the ß - globin gene have been characterized all over the world (6). There are few ß -thalassemia mutations which are common in India. Six mutations, codon 8–9 (+G), codon 15 (G?A), codon 41/42 (–TCTT), IVS 1-1 (G?T), IVS I-5 (G?C) and 619 bp deletion at 3’ end of ß -globin gene, account for about 80 % of ß -thalassemia mutation in Indian population (7). Thalassemia and Sickle cell disease are two major erythrocytic genetic disorders prevalent in India. ß - Thalassemia is predominantly found in the Mediterranean countries, the Middle East, Central Asia, India, North Coast of Africa and South America (8). The prevalence of the sickle gene in India is found to vary from 2-34% (9). The average frequency of Sickle cell disorders in India is 4.3% (10). Sickle cell hemoglobin is mainly prevalent among the Tea garden communities of Assam (11). The association of ß- thalassemia with sickle cell hemoglobin is rare, which was reported as 1.7% (12). For diagnosis of Hb S/ß-thalassemia; hemoglobin typing by HPLC is very important. Elevated HbA2 is the most significant parameter in the identification of ß-thalassemia carriers and the result should be interpreted together with other hematological and biochemical parameters (13). HPLC is a method that allows rapid and precise detection of Hb variants, as well as sensitive quantitation of HbA2 (14). When Hb S variant is present, percentage of Hb A2 and Hb F, family history, clinical data and hematological parameters help for distinguishing between homozygosis for Hb S and Hb S/ß- thalassemia (15),(16),(17),(18). In the present study, ARMS-PCR and automated DNA sequencer has been used for detection of ß -thalassemia mutations. ARMS-PCR has the advantage that it is theoretically possible to detect any known mutation (19). When considering the findings associated with Hb S/ßthalassemia, blood transfusion might be the best treatment; however, many more Hb S/ß- thalassemia case findings are necessary to more clearly identify an optimal treatment strategy. | |||||||||||||||||||||||||||||||||||||||||
CONCLUSION | |||||||||||||||||||||||||||||||||||||||||
Present study shows that the molecular techniques are very important for diagnosis of Hb S/ß-thalassemia. Correct diagnosis of Hb S/ß-thalassemia can be made based on high performance liquid chromatography (HPLC) testing, ARMS-PCR and DNA sequencing. | |||||||||||||||||||||||||||||||||||||||||
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TABLES AND FIGURES | |||||||||||||||||||||||||||||||||||||||||