The Changing Trends in Prenatal Diagnosis of Hemoglobinopathies in India: The Quest of a Single Center to Reduce the Burden of Disease over Three Decades.

The ß-thalassemias and sickle cell disorders pose a considerable health burden in India. Of the more than 10,000 annual births of children with a severe hemoglobinopathy, only around 10.0% are managed optimally. Thus, genetic counseling and prenatal diagnosis (PND) is a valid option for a large and diverse country. Our center was one of the first to initiate PND and we present our experience over 30 years to evaluate the impact of awareness in changing the trends of PND of hemoglobinopathies. Both second and first-trimester diagnoses were undertaken by fetoscopy/cordocentesis and globin biosynthesis/high-performance liquid chromatography (HPLC) analysis of fetal blood and chorionic villus sampling (CVS) and DNA analysis. Over 30 years, 3478 couples (first trimester: 2475; second trimester: 1003) from all over India were offered PND. The number of couples coming in the first trimester increased significantly over each decade and couples coming prospectively increased from 2.5 to 18.4%. A cost-effective stepwise approach was used for molecular analysis. Eight hundred and one fetuses (23.0%) were affected and all except three couples opted for termination of these pregnancies. Genetic counseling and PND is the only way to reduce the burden of disease. With awareness, there was a shift from second trimester to first trimester PND over each decade, with an increasing number of couples coming during the first pregnancy. There are only 15 to 20 centers in India offering PND. We have compared our study with other reports on PND from different regions in India.

The phenotypic and molecular diversity of hemoglobinopathies in India: A review of 15 years at a referral center.

INTRODUCTION: The hemoglobinopathies pose a significant health burden in India. Apart from the ß thalassemias and sickle cell disorders, α thalassemias and structural hemoglobin variants are also common. Here we have reviewed the phenotypic and molecular diversity of hemoglobinopathies encountered at a referral center in western India over a period of 15 years. MATERIALS AND METHODS: Screening for hemoglobinopathies was done using HPLC and cellulose acetate electrophoresis. Molecular characterization was done using Covalent Reverse Dot Blot Hybridization (CRDB), Amplification Refractory Mutation System (ARMS), GAP PCR and direct DNA sequencing. RESULTS: The study includes 31 075 individuals who were referred for diagnosis of hemoglobinopathies and prenatal diagnosis. Of these 14 423 individuals showed various hemoglobin abnormalities. Beta genotyping in 5615 individuals showed the presence of 49 ß thalassemia mutations. 143 ß thalassemia heterozygotes had normal or borderline HbA2 levels. We identified three δ gene mutations (HbA2 Pellendri, HbA2 St.George, HbA2 Saurashtra) in ß thalassemia heterozygotes leading to normal HbA2 levels. The commonest defects among the raised Hb F determinants were Gγ(Αγδß)0 Indian inversion and the HPFH-3 Indian deletion. A total of 312 individuals showed the presence of α thalassemia, of which 12.0% had a single α gene deletion (-α/αα). HbH disease was identified in 29 cases with 10 different genotypes. Alpha globin gene triplication was seen in 2.1% of ß thalassemia heterozygotes with a thalassemia intermedia phenotype. Seven unusual α chain variants and eight uncommon ß chain variants were identified. CONCLUSION: The repertoire of molecular defects seen in the different globin genes will be valuable for management and control of these disorders both in India as well as in other countries where there is a huge influx of migrant populations from India.

Diverse phenotypes and transfusion requirements due to interaction of ß-thalassemias with triplicated α-globin genes.

Co-inheritance of triplicated α-genes can alter the clinical and hematological phenotypes of ß-thalassemias. We evaluated the phenotypic diversity and transfusion requirements in ß-thalassemia heterozygotes, homozygotes, and normal individuals with associated α-gene triplication. Clinical and hematological evaluation was done and the ß-thalassemia mutations characterized by a covalent reverse dot blot hybridization/amplification refractory mutation system. Alpha-globin gene triplication was assessed by multiplex PCR. During the last 2.5 years, 181 ß-thalassemia patients and ß-thalassemia carriers with an unusual clinical presentation were referred to us for screening for the presence of associated α-globin gene triplication. Twenty-nine of them had associated α-gene triplication (3 ß-thalassemia homozygotes or compound heterozygotes and 26 ß-thalassemia heterozygotes). One ß-thalassemia compound heterozygote [IVS 1-5 (G → C) + CD 41/42 (-CTTT)] was anemic at birth and required blood transfusions unusually early by 6 weeks of age. The second patient (4.5 years) was also clinically severe and became transfusion dependent in spite of having one mild ß-thalassemia mutation [Capsite +1 (A → C)]. The third case (3.5 years) who was homozygous for a mild ß-gene mutation [-88 (C → T)] with α gene triplication was untransfused. The 26 ß-thalassemia heterozygotes with associated triplicated α-genes presented variably, with a ß-thalassemia intermedia-like presentation. While screening the family members of all these cases, we found another 10 ß-thalassemia heterozygotes and 9 normal individuals with α-globin gene triplication; however, all of them were asymptomatic. Beta-thalassemia carriers, homozygotes, and compound heterozygotes with an unusual presentation should be screened for the possible presence of associated α-globin gene triplication which could influence the clinical and hematological presentation.