Significance of genetic modifiers of hemoglobinopathies leading towards precision medicine.

Hemoglobinopathies though a monogenic disorder, show phenotypic variability. Hence, understanding the genetics underlying the heritable sub-phenotypes of hemoglobinopathies, specific to each population, would be prognostically useful and could inform personalized therapeutics. This study aimed to evaluate the role of genetic modifiers leading to higher HbF production with cumulative impact of the modifiers on disease severity. 200 patients (100 ß-thalassemia homozygotes, 100 Sickle Cell Anemia), and 50 healthy controls were recruited. Primary screening followed with molecular analysis for confirming the ß-hemoglobinopathy was performed. Co-existing α-thalassemia and the polymorphisms located in 3 genetic loci linked to HbF regulation were screened. The most remarkable result was the association of SNPs with clinically relevant phenotypic groups. The γ-globin gene promoter polymorphisms [- 158 C → T, + 25 G → A],BCL11A rs1427407 G → T, - 3 bp HBS1L-MYB rs66650371 and rs9399137 T → C polymorphisms were correlated with higher HbF, in group that has lower disease severity score (P < 0.00001), milder clinical presentation, and a significant delay in the age of the first transfusion. Our study emphasizes the complex genetic interactions underlying the disease phenotype that may be a prognostic marker for predicting the clinical severity and assist in disease management.

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.

Genotypic-phenotypic heterogeneity of 뫧-thalassemia and hereditary persistence of fetal hemoglobin (HPFH) in India.

Large deletions in the ß-globin gene cluster lead to increased HbF levels by delaying the γ- to ß-globin switch process. However, these deletions when inherited as a homozygous condition or when co-inherited with ß-thalassemia result in variable clinical phenotypes. Individuals or families with a clinically presenting child, where the parents had HbF levels ≥ 10%, were further screened for the presence of large ß-globin cluster deletions. Six deletions in the ß-globin gene cluster were screened by GAP-PCR, and the uncharacterized deletions were further analyzed by gene dosage or by multiplex ligation-dependent probe amplification (MLPA). Among 192 individuals suspected for the inheritance of large deletions, 138 were heterozygous for large deletions, 45 were compound heterozygous of a large ß-globin cluster deletion and ß-thalassemia, and 9 were found to be homozygous for deletions. Among the heterozygotes, the Asian Indian inversion-deletion was found to be the most common deletion (39.9%), followed by the HPFH-3 deletion (30.0%). Other deletions 49.3 kb, δß-thalassemia (21.2%), and 32.6 kb deletion (4.4%) were also found to be prevalent in our population. Patients compound heterozygous or homozygous for HPFH-3 and 32.6 kb deletions showed a milder clinical presentation, as compared with the patients compound heterozygous or homozygous for the Asian Indian inversion-deletion and 49.3 kb δß-thalassemia. This comprehensive study highlights the mutation spectrum of large ß-globin cluster deletions and the clinical heterogeneity in the patients homozygous or compound heterozygous with ß-thalassemia, thus asserting the need for molecular characterization of these deletions.

Prevalence of globin gene modifiers encountered in fetuses during antenatal diagnosis of hemoglobinopathies.

INTRODUCTION: The hemoglobinopathies are the commonest group of single gene disorders in the Indian subcontinent. Although genetic modifiers are known to have a remarkable effect on phenotypic expression, the effects of the possible co-inheritance of different modifiers are not taken into account during prenatal diagnosis. The present study was undertaken to look for the frequency of globin gene modifiers like the types of ß-globin gene mutations, α thalassemia, α gene triplication, and the Xmn1 polymorphism in fetuses during antenatal diagnosis of hemoglobinopathies. MATERIALS AND METHODS: A total of 580 fetuses with different diagnoses were screened for the presence of genetic modifiers. RESULTS: Twenty-two different ß-globin gene mutations were identified of which 3.5% were milder mutations. Among the affected fetuses, 29.6% of the ß-thalassemia major and 52.9% of the sickle cell anemia (SCA) fetuses had one genetic modifier while 3.7% of the ß-thalassemia major and 41.1% of the SCA fetuses had co-inherited two modifiers. α-gene triplication was detected in 16 (3.5%) ß-thalassemia/sickle cell heterozygous and normal fetuses of which 5 babies (2 ß-thalassemia heterozygous and 3 normal) could be followed up. Of the 2 ß-thalassemia heterozygous babies, one had a severe clinical presentation. CONCLUSION: Many fetuses had one or two gene modifiers. However, the impact of these on ameliorating the severity of the disease could not be evaluated as all the fetuses with ß thalassemia major or sickle cell disease were terminated. Parents having heterozygous fetuses with α gene triplication should be followed up periodically after birth for better management of these babies.

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.

Synergistic effect of two ß globin gene cluster mutations leading to the hereditary persistence of fetal hemoglobin (HPFH) phenotype.

Co-inheritance of gamma and beta globin gene mutations in a compound heterozygous state is rare but of clinical interest as it provides an important data on understanding the HbF expression. Hematological analysis was carried out (Sysmex KX-21). F-cells were enumerated using flow cytometry. Beta globin gene was analysed by CRDB technique and by DNA sequencing. Gamma globin promoter region was sequenced and expression studies were carried out using real time Taqman assay. We report a family, where two inherited defects of the ß globin gene cluster segregate. The proband and her sibling were compound heterozygotes for a novel Gγ promoter mutation and the 619 bp deletion a common Indian ß thalassemia mutation. Molecular characterization revealed that the father (HbA2 5.1%, HbF 5.4%), proband (HbA2 3.6%, HbF 31.7%) and her brother (HbA2 3.9%, HbF 23.6%) were heterozygous for the 619 bp deletion. The mother (HbA2 2.1%, HbF 3.4%) had a normal ß globin gene. As both the children showed high HbF levels, the γ globin gene work up was carried out. The Gγ-globin gene promoter analysis revealed that the mother and the two children were heterozygous for a 5 bp deletion -ATAAG (-533 to -529) that resides in the GATA binding site. These findings suggest that the 5 bp deletion in the Gγ globin promoter has a functional role in silencing the γ-globin gene expression in adults by disrupting GATA-1 binding and the associated repressor complex and results in the up-regulation of gamma globin gene expression. When co-inherited with ß -thalassemia trait it leads to a phenotype of HPFH.

Does the Novel KLF1 Gene Mutation Lead to a Delay in Fetal Hemoglobin Switch?

The Kruppel-like factor 1 (KLF1) gene is an essential transcription factor that is required for the proper maturation of the erythroid cells. Recent studies have reported that KLF1 variations are associated with increased fetal hemoglobin (HbF) levels. Here we report a novel KLF1 gene variation codon 211 A→G (c.632 A>G) in a family who was referred for hemoglobinopathy screening. Both parents were classical ß-thalassemia trait (mother: HbA2 4.1%, HbF 8.6%; father: HbA2 5.5%, HbF 0.6%) codon 15 G→A heterozygous, and the child was ß-thalassemia homozygous. Because the mother showed a high HbF level, the genetic determinants for raised HbF were screened. We detected a novel KLF1 gene variant in the mother and the child in the heterozygous state. The co-inheritance of this novel KLF1 variant might have increased the HbF levels in the mother and may have ameliorated the clinical manifestations of the 6-year-old untransfused ß-thalassemia homozygous child. Identification of KLF1 gene variants may act as a novel target for increasing HbF levels in patients with ß-hemoglobinopathies.

Five Rare ß Globin Chain Hemoglobin Variants in India.

Thalassemias as well as structural hemoglobin (Hb) variants are common monogenic inherited disorders of Hb in India. In this paper we describe 5 rare ß-chain Hb variants identified in the Indian population on the basis of high performance liquid chromatography (HPLC). Of these 3 were identified during antenatal screening of ß-thalassemia while the other 2 cases were referred to us for a diagnostic work up. These 5 Hb variants were Hb British Columbia (ß CD 101 GAG â†’ AAG), Hb Saint Louis (ß CD28 CTG â†’ CAG), Hb G Coushatta (ß CD 22 GAA â†’ GCA), Hb Pyrgos (ß CD 83 GGC â†’ GAC) and Hb Agenogi (ß CD 90 GAG â†’ AAG). Hb Saint Louis and Hb G Coushatta eluted in the HbA2 window, Hb British Columbia and Hb Agenogi eluted in the Hb C window while Hb Pyrgos eluted in an unknown window on HPLC. They were all identified by DNA sequencing. The child having Hb St. Louis had hepatosplenomegaly and anemia while the individuals with the other 4 variants were asymptomatic. Rare Hb variants are diagnostic curiosities that may be encountered by laboratories. Correct identification requires the application of more than one technique to avoid misdiagnosing them as more common variants (e.g. St. Louis and G Coushatta as E or D Iran on HPLC. Some, like G Coushatta may interfere with HPLC-based HbA1c estimation).

Challenges in prenatal diagnosis of beta thalassaemia: couples with normal HbA2 in one partner.

OBJECTIVES: To undertake ß-genotyping in couples having normal/borderline HbA2 levels in one partner to offer the possibility of prenatal diagnosis of thalassaemia. METHODS: A total of 967 couples were screened for ß-thalassaemia. Haematological analysis was carried out on a Sysmex K-1000 analyser. The HbA2 and HbF levels were measured by High Performance Liquid Chromatography-Variant II analyser (Bio-Rad, USA). ß-globin gene analysis was done by reverse dot blot hybridization, amplification refractory mutation system or DNA sequencing. Alpha globin gene triplication was determined by Multiplex PCR. RESULTS: In 33 of 967 couples, one partner had a normal/borderline HbA2 level (1-3.5%); however a ß-thalassaemia mutation could be identified in 24 of these individuals. Molecular analysis of the ß-globin gene revealed the presence of the capsite +1 (A → C) [HBB: c.-50 A → C] mutation in 15 cases (60%), Poly A(T → C) [HBB: c.*110 T → C] mutation in two cases (8%), IVS 1-5 (G → C) [HBB: c. 92 + 5 (G → C)] mutation in four cases (17%) and the CD 15 (G → A) [HBB: c. 47 G → A] mutation, CD 16 (-C) [HBB: c. 51 del C] mutation and CD 30 (G → C) [HBB: c. 93 G → C] mutation in one case each (4%). Alpha gene triplication was found in five cases, while four cases remained uncharacterized. CONCLUSIONS: ß-genotyping should always be done in a couple if one partner is a ß-thalassaemia carrier irrespective of the RBC indices and HbA2 levels of the other partner.

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.