Hemoglobin E

Abstract: β-Thalassemia/HbE disease is clinically variable. In searching for genetic factors modifying the disease severity, patients were selected based on their disease severities, and a genome-wide association study (GWAS) was performed. Genotyping was conducted with the Illumina Human 610-Quad BeadChips array using DNAs from 618 Thai β0-thalassemia/HbE patients who were classified as 383 severe and 235 mild phenotypes by a validated scoring system. Twenty-three SNPs in three independent genes/regions were identified as being significantly associated with the disease severity. The highest association was observed with SNPs in the β-globin gene cluster (chr.11p15), and rs2071348 of the HBBP1 gene revealed the most significant association [P = 2.96 × 10−13, odds ratio (OR) = 4.33 (95% confidence interval (CI), 2.74–6.84)]. The second was identified in the intergenic region between the HBS1L and MYB genes (chr.6q23), among which rs9376092 was the most significant [P = 2.36 × 10−10, OR = 3.07 (95% CI, 2.16–4.38)]. The third region was located in the BCL11A gene (chr.2p16.1), and rs766432 showed the most significant association [P = 5.87 × 10−10, OR = 3.06 (95% CI, 2.15–4.37)]. All three loci were replicated in an independent cohort of 174 Indonesian patients. The associations to fetal hemoglobin levels were also observed with SNPs on these three regions. Our data indicate that several genetic loci act in concert to influence HbF levels of β0-thalassemia/HbE patients. This study revealed that all the three reported loci and the α-globin gene locus are the best and common predictors of the disease severity in β-thalassemia.

Abstract: Hemoglobin (Hb) E is one of the world's most common and important mutations. It results in a heterogeneous group of disorders whose phenotype range from asymptomatic to severe. Hb E trait and Hb EE are mild disorders. The combination of Hb E and Hb S (Hb SE) results in a sickle cell disease syndrome similar to sickle beta(+) thalassemia. It is important to distinguish Hb E disorders diagnostically because of this marked difference in clinical course among different genotypes. Screening tests, including hemoglobin electrophoresis and high-pressure liquid chromatography (HPLC), may suggest other mutations, unless one is familiar with the findings. E beta-thalassemia, the most serious form of E syndromes, affects a million people worldwide and is increasing in North America. Its phenotype ranges from mild anemia to severe transfusion-dependent thalassemia major. Several genetic modifiers affect the phenotype, including the type of beta-thalassemia mutation, Hb F levels, and co-inheritance of alpha-thalassemia. However, the cause of the phenotypic variability is largely unknown. A prospective natural history study of E beta-thalassemia in Sri Lanka suggests that environmental modifiers are prognostically important. The clinical course of E beta-thalassemia is punctuated by acute and chronic complications that may cause serious morbidity and mortality. Recent studies indicate these patients are at high risk for thromboembolism secondary to a hypercoagulable state increased by splenectomy. Morbidity from iron overload in nontransfused patients secondary to increased gastrointestinal iron absorption is common. Cardiopulmonary disease, including pulmonary hypertension, requires ongoing monitoring and is secondary to iron overload, thromboembolism, and hemolysis-induced nitric oxide deficiency. These patients are excellent candidates for Hb F-modulating agents because moderate changes in hemoglobin may result in marked improvement in phenotype. Recent studies with hydroxyurea indicate 40% of patients will clinically improve with hydroxyurea.

Abstract: The β-thalassemias, including the hemoglobin E disorders, are not only common in the Mediterranean region, South-East Asia, the Indian subcontinent and the Middle East but have now become a global problem, spreading to much of Europe, the Americas and Australia owing to migration of people from these regions. Approximately 1.5% of the global population are heterozygotes or carriers of the β-thalassemias. While the overall frequencies of carriers of these disorders are known in most countries, there have been few attempts at micromapping and wherever this has been done, significant variations are seen even within small geographic regions. Thus, the figures for the estimated numbers of births each year of homozygous β-thalassemia and the severe compound states involving other hemoglobin disorders may be an underestimate. Screening strategies have varied from premarital to antenatal in different countries depending on socio-cultural and religious customs in different populations. Prenatal diagnosis programs are ongoing in many countries and the knowledge of the distribution of mutations has facilitated the establishment of successful control programs. Many of these were through North-South partnerships and networking. Yet, there are many countries in Asia where they are lacking, and South-South partnerships are now being developed in South-East Asia and the Indian subcontinent to link centers with expertise to centers where expertise needs to be developed. Although the carrier frequencies will remain unaltered, this will eventually help to bring down the burden of the birth of affected children with β-thalassemias and hemoglobin E disorders in Asia.