Possible factors influencing the haemoglobin and fetal haemoglobin levels in patients with beta-thalassaemia due to a homozygosity for the IVS-I-6 (T-->C) mutation

Establishment of haemoglobin A2 reference intervals in Pretoria, South Africa: A retrospective secondary data analysis

Background

Haemoglobinopathies are one of the most common inherited diseases worldwide. Quantification of haemoglobin A₂ is necessary for the diagnosis of the beta thalassaemia trait. In this context, it is important to have a reliable reference interval for haemoglobin A₂ and a local reference range for South Africa has not been established.

Objective

This study aimed to establish reference intervals for haemoglobin A₂ using stored patient laboratory data.

Methods

This descriptive study used retrospective data to evaluate haemoglobin A₂ levels determined using high-performance liquid chromatography at the National Health Laboratory Service haematology laboratory in Pretoria, South Africa. All tests performed from 01 October 2012 to 31 December 2020 were screened for inclusion; of these, 144 patients’ data met the selection criteria. The reference interval was calculated using descriptive statistics (mean and standard deviation) with a 95% confidence interval.

Results

Analysed data from enrolled patients showed a normal distribution. The mean age of the patients was 40 years (range: 3–84 years). The reference interval for haemoglobin A₂ calculated from this data was 2.3% – 3.6%. The minimum haemoglobin A₂ was 2.3% and the maximum was 3.9% with a mean of 2.95% and a standard deviation of 0.357%.

Conclusion

A normal reference interval has been established for the population served by the laboratory that will assist with accurate diagnosis of the beta thalassaemia trait. This reference interval may also be useful to other laboratories that employ the same technology, especially smaller laboratories where obtaining a sufficiently large number of normal controls may be challenging.

Genotype-Phenotype Correlations of β-Thalassemia Mutations in an Azerbaijani Population

β-Thalassemia is the most common inherited disorder in Azerbaijan. The aim of our study was to reveal genotype-to-phenotype correlations of the most common β-thalassemia mutations in an Azerbaijani population. Patients with codon 8 (-AA), IVS-I-6 (T>C), and IVS-II-1 (G>A) mutations, which are reportedly the most common β-globin gene mutations among the local population, were tested for hematologic parameters. Fifty-five previously tested patients with known genotypes were included in the study. Hematologic indices and hemoglobin fractions were tested in order to reveal the phenotypic manifestation of the mutations. The results obtained indicate that clinical presentation varies between different β-globin gene mutations: individuals with IVS-I-6 (T>C) mutations showed milder presentation than those with codon 8 (-AA) and IVS-II-1 (G>A), which is associated with the molecular basis of the mutations. These data can be of assistance to predict clinical presentation and select the best possible therapeutic approach via early genotype identification.

Role of the cold shock domain protein A in the transcriptional regulation of HBG expression

Impaired switching from fetal haemoglobin (HbF) to adult globin gene expression leads to hereditary persistence of fetal haemoglobin (HPFH) in adult life. This is of prime interest because elevated HbF levels ameliorate β-thalassaemia and sickle cell anaemia. Fetal haemoglobin levels are regulated by complex mechanisms involving factors linked or not to the β-globin gene (HBB) locus. To search for factors putatively involved in the expression of the γ-globin genes (HBG1, HBG2), we examined the reticulocyte transcriptome of three siblings who had different HbF levels and different degrees of β-thalassaemia severity although they had the same ΗBA- and ΗΒB cluster genotypes. By mRNA differential display we isolated the cDNA coding for the cold shock domain protein A (CSDA), also known as dbpA, previously reported to interact in vitro with the HBG2 promoter. Expression studies performed in K562 and in primary erythroid cells showed an inverse relationship between HBG and CSDA expression levels. Functional studies performed by Chromatin Immunoprecipitation and reporter gene assays in K562 cells demonstrated that CSDA is able to bind the HBG2 promoter and suppress its expression. Therefore, our study demonstrated that CSDA is a trans-acting repressor factor of HBG expression and modulates the HPFH phenotype.

The significance of the hemoglobin A(2) value in screening for hemoglobinopathies

BACKGROUND AND OBJECTIVE

The inherited hemoglobinopathies are a large group of disorders that include thalassemias and hemoglobin variants. Accurate determination of the carrier phenotype is essential for detecting couples at risk for producing offspring with hemoglobinopathy. Heterozygous beta-thalassemia is usually silent at the clinical level. His phenotype is characterized by microcytosis and hypochromia with increased hemoglobin A(2) (HbA(2)) value. Therefore, HbA(2) determination plays a key role in screening programs for hemoglobinopathy. The aim of this review is to address and suggest an approach for reducing or abolishing hemoglobinopathy screening mistakes.

DESIGN AND METHODS

Quantitative methods for HbA(2) value determination, comment on the accuracy of the test and on the interpretation of data were discussed. The most probable diagnostic conclusion based on the HbA(2) level, hemoglobin pattern, hematological parameters and iron markers was suggested in this review.

RESULTS

Hemoglobinopathies are the only genetic disease where it is possible to detect carriers using hematological findings rather than DNA analysis. However, hematological diagnosis is sometimes presumptive, and in these cases, DNA analysis becomes necessary. Complete screening is based on the detection of red cell indices, HbA(2), HbF and hemoglobin variant values. In particular, HbA(2) determination plays a key role in screening programs for beta-thalassemia because a small increase in this fraction is one of the most important markers of beta-thalassemia heterozygous carriers.

CONCLUSION

Genetic factors both related and unrelated to the beta- and alpha-globin gene clusters, iron metabolism, endocrinological disorders, and some types of anemia, together with intra- and inter-laboratory variations in HbA(2) determination, may cause difficulties in evaluating this measurement in screening programs for hemoglobinopathies. Therefore, knowledge of all these issues is important for reducing or eliminating the risk of mistakes in screening programs for hemoglobinopathies.

Hb Stara Zagora: A New Hyper-Unstable Hemoglobin Causing Severe Hemolytic Anemia

We describe a new hyper-unstable beta chain variant (codons 137-139, -6 bp) in a 2-year-old Bulgarian boy. The abnormal hemoglobin (Hb) is associated with severe hemolytic anemia as a consequence of its hyper instability. The child was admitted to the Pediatric Clinic (Faculty of Medicine, Stara Zagora, Bulgaria) at the age of 2 months. Because of anemia (Hb 6.9 g/dL) and high serum iron level (58 microM/L) the child was transfused. However, a month later his Hb level had dropped to 7.5 g/dL, and since then he has been on a regular monthly blood transfusion regimen. Hemoglobin analysis of a blood sample collected 2 months after the last transfusion at the age of 2 years, revealed no abnormalities except for the presence of inclusion bodies after incubation of peripheral blood with brilliant cresyl blue. Sequencing of the beta-globin gene revealed heterozygosity for a 6 bp deletion (-TGGCTA) at codons 137 [the second and third base pair (bp)], 138 and 139 (the first bp), forming a new codon at position 137 (GAT). This event eliminates three amino acids (Val-Ala-Asn) and introduces a new residue (Asp). It creates a new restriction site for HphI. The parents and his dizygotic twin brother had no history of hemolysis. The paternity of the child was confirmed by DNA analysis.

Fetal hemoglobin chemical inducers for treatment of hemoglobinopathies

The switch from fetal ((G)gamma and (A)gamma) to adult (beta and delta) globin gene expression occurs at birth, leading to the gradual replacement of HbF with HbA. Genetic regulation of this switch has been studied for decades, and the molecular mechanisms underlying this developmental change in gene expression have been in part elucidated. The understanding of the developmental regulation of gamma-globin gene expression was paralleled by the identification of a series of chemical compounds able to reactivate HbF synthesis in vitro and in vivo in adult erythroid cells. Reactivation of HbF expression is an important therapeutic option in patients with hemoglobin disorders, such as sickle cell anemia and beta-thalassemia. These HbF inducers can be grouped in several classes based on their chemical structures and mechanisms of action. Clinical studies with some of these agents have shown that they were effective, in a part of patients, in ameliorating the clinical condition. The increase in HbF in response to these drugs varies among patients with beta-thalassemia and sickle cell disease due to individual genetic determinants.

Disorders of the synthesis of human fetal hemoglobin

Fetal hemoglobin (HbF), the predominant hemoglobin in the fetus, is a mixture of two molecular species (alpha(2)(G)gamma(2) and alpha(2)(A)gamma(2)) that differ only at position 136 reflecting the products of two nonallelic gamma-globin genes. At the time of birth, HbF accounts for approximately 70% of the total Hb. The (G)gamma:(A)gamma globin ratio in the HbF of normal newborn is 70:30 whereas in the trace amounts of HbF that is found in the adult it reverses to 40:60 because of a gamma- to beta-globin gene switch. Alterations of these ratios are indicative of a molecular defect at the level of the HbF synthesis. Qualitative hemoglobinopathies due to (G)gamma and (A)gamma chain structural variants, and quantitative hemoglobinopathies affecting the synthesis of HbF such as gamma-thalassemias, duplications, triplications, and even sextuplications of the gamma-globin genes, which may be detected in newborn blood lysates, have been described. Moreover, several pathological and nonpathological conditions affecting the beta-globin gene cluster, such as beta-thalassemia, sickle cell disease, deltabeta-thalassemia, and hereditary persistence of HbF syndromes, are characterized by the continued synthesis of gamma-globin chains in the adult life. Studies of these natural mutants associated with increased synthesis of HbF in adult life have provided considerable insight into the understanding of the control of globin gene expression and Hb switching.

Hb Jambol: a new hyperunstable hemoglobin causing severe hemolytic anemia

We describe a new hyperunstable beta-chain variant due to a complex genomic rearrangement. The abnormal hemoglobin (Hb) was found as a de novo mutation in a 2-year-old Bulgarian girl with severe hemolytic anemia. The mutation was detected through RNA/DNA analysis. It represents a complex genomic rearrangement involving an insertion of 23 nts after IVS-II-535 (derived by triplication of the 12-nts adjacent sequence and subsequent deletion of 1 nt), a deletion of 310 nts extending from IVS-II-550 to the first nt of Cd 108 and an insertion of 28 nts at the deletion junctions (derived from the inverted sequence between nts +3,707 and +3,734 3' to the beta-globin gene termination codon). At the protein level this mutation leads to a deletion of 4 amino acid residues (Leu-Leu-Glu-Asn) at positions 105-108 and an insertion of 9 residues (Val-Pro-Ser-Val-Thr-Leu-Phe-Phe-Asp) at the same location, creating an abnormal elongated beta-chain of 151 amino acid residues. This highly unstable variant was named 'Hb Jambol' after the geographic location in which the patient resides.

Pathophysiology of beta thalassemia--a guide to molecular therapies

The central mechanism underlying the pathophysiology of the beta thalassemias can be related to the deleterious effects of imbalanced globin chain synthesis on erythroid maturation and survival. An imbalance of the alpha/non-alpha globin chains leads to an excess of unmatched alpha globin which precipitates out, damaging membrane structures leading to accelerated apoptosis and premature destruction of the erythroid precursors in the bone marrow (ineffective erythropoiesis). Close observation of the genotype/phenotype relationships confirms the pathophysiological mechanism and provides clues to molecular therapies, all of which aim to reduce the alpha/non-alpha chain imbalance. They include inheritance of the milder forms of beta thalassemia, co-inheritance of alpha thalassemia, or genetic factors (quantitative trait loci, QTLs) for increasing gamma globin expression. Currently, the most promising molecular therapeutic approaches include increasing beta globin gene expression by stem cell gene therapy and increasing gamma globin expression using pharmacological agents or by transduction of the gamma globin genes.

Role of polymorphic sequences 5' to the G(gamma) gene and 5' to the beta gene on the homozygous beta thalassemic phenotype

Sixty-seven homozygous male and female thalassemic patients with different phenotypes, aged between 8 and 33 years, were divided into three groups, according to the severity of their beta-thalassemia (thal) mutations. We investigated whether some co-inherited genetic factors could influence the phenotype. Patients with milder beta-thal defects, homozygotes or compound heterozygotes for the IVS-I-6 (T-->C) or -87 (C-->G) mutations had a milder disease. In addition, determination of the co-inheritance of the -158 (C-->T) G(gamma) polymorphism and the (AT)9T5 repeat motif in the region -540 to -525, 5' to the beta-globin gene, showed that in some patients with severe or mild/severe beta-thal mutations, linked to haplotype III, there was higher Hb F expression. We conclude that in homozygous beta-thal patients, the severity of the mutations is the most important factor influencing the phenotype, but some polymorphisms such as the -158 (C-->T) G(gamma) and (AT)9T5 repeat motif, increasing the Hb F expression and ameliorate the clinical course of the disease.

Spectrum of beta thalassemia mutations and HbF levels in the heterozygous Moroccan population

A comprehensive hematological and molecular analysis of 57 beta thalassemic heterozygotes, 28 homozygotes, 18 double heterozygotes, 3 compound heterozygotes beta thal/beta S and one compound heterozygote beta thal/Hb Newcastle, in 46 Moroccan families with at least one beta thalassemia patient is reported. Six major mutations: beta(0)39 (C-->T), beta(0)FsCD8(-AA), beta(+)IVS1,nt6 (T-->C) and beta(0)IVS1,nt1 (G-->A), beta(0)FsCD6 (-A) and beta(+)-29 (A-->G) cap site account for 75% of the 86 independent beta thal chromosomes studied. For the first time, an extensive mutation/haplotype study has been performed on the Moroccan population, and data are consistent with the geographical location of the country and historical links with both the Mediterranean and the Sub-Saharan Africa communities. Despite the heterogeneous spectrum of mutations, good genetic counseling can be offered to the carrier population. This study focuses on the analysis of fetal hemoglobin levels in beta thalassemic heterozygotes and its correlation with beta globin cluster polymorphic markers in this population. Fetal hemoglobin levels in heterozygotes vary from trace quantities to 17.9% (2.38 g/dl) of total hemoglobin in the adult. No statistically significant correlation was found, either between genders and HbF levels, or between the mutation and the HbF level, with the exception of mutation beta(0)FSCD6(-A). We have examined the alpha globin genotype and the beta globin genotype of heterozygotes, namely, the extended haplotype, which includes the XmnI site at -158 bp of the Ggamma gene and the microsatellite (AT)(x)T(y) at -540 bp of the beta globin gene. In this sample, we confirm the existence of linkage disequilibrium between the C-->T variation at -158 bp of Ggamma globin gene (XmnI(+)) and Orkin's haplotypes III, IV, or IX (the 5' subhaplotype class A). At 5' beta globin gene, we observe exclusively the allele (AT)(7)T(7). In the beta thalassemic heterozygotes studied, no correlation of those genetic markers with HbF levels is observed.

Molecular analysis of beta-thalassaemia patients in a high incidence area of southern Italy

The prevalence of eight mutations in 84 patients with beta-thalassaemia major and in 16 subjects with thalassaemia intermedia was investigated. All of the patients were Italian, originating from Eastern Sicily (Messina area) and some Calabrian regions. Genomic DNA was amplified by polymerase chain reaction (PCR). DNA molecular investigations were performed by allele-specific oligonucleotide (ASO) hybridization, to identify the following beta-thalassaemia mutations: CD39 (C-T), IVS1-110 (G-A), IVS1-6 (T-C), IVS1-1 (G-A), IVS2-745 (C-G), IVS2-1 (G-A), -87 (C-G), CD6 A (-A). Our data underline that in thalassemia intermedia two mutations were statistically prevalent: IVS1-6 T-->C (P < 0.001) and CD 6-A (P < 0.05). CD 39 was statistically prevalent in beta-thalassaemia major patients (P < 0.01). The difference between the two groups was not statistically significant for all the other mutations. Five different genotypes were recorded among thalassaemia intermedia and 15 among beta-thalassaemia major patients. Twenty-five percent of the intermedia patients and 4.5% of the major patients had homozygosity for mild mutations (group I); 62.5% of the intermedia patients and 26.2% of the major patients had combinations of mild/severe mutations (group II). In addition, homozygosity or double heterozygosity for severe mutations (group III) was found in 12.5% of the intermedia patients and 69% of the major patients. Some genotypes were restricted to thalassaemia intermedia, including heterozygosity -87/IVS1-6 and IVS1-6/CD 6-A. It is essential to understand the distribution and frequency of the relevant mutations in each population where beta-thalassaemias exist. This is of particular importance for genotype-phenotype correlation and for carrier detection, genetic counselling and prenatal diagnosis.

Spectrum of beta-thalassemia in Jordan: identification of two novel mutations

Two hundred and forty-four beta-thalassemia alleles were identified from 135 unrelated occasionally and periodically transfusion dependent beta- and S/beta-thalassemia patients from all regions of Jordan. Allele identification was achieved by PCR amplification of beta-globin genes, dot-blotting the amplified DNA, hybridization with allele specific synthetic probes, and direct sequencing of amplified genomic DNA. A total of 19 different mutations were detected, eight of them constituted about 86% of the Jordanian thalassemic chromosomes. These mutations were IVS1-110 (G>A) (25%), IVS2-1 (G>A) (15%), IVS2-745 (C>G) (14.2%), IVS1-1 (G>A) (10%), IVS1-6 (T>C) (8.3%), codon 37 (G>A) (6.3%), codon 39 (C>T) (4.6%), and codon 5 (-C) (3.8%). The remaining eleven mutations were rare, presented with frequencies ranging between 0.4% and 1.6%. These included two novel mutations and four others detected in Jordan for the first time. The novel mutations were the frame shift (-C) at codon 49 and the substitution (A>C) at position -29 in the TATA box. Four alleles (1.6%) remained unidentified; having no abnormalities in their beta-globin gene sequences and therefore, constituted additional defects causing beta-thalassemia in the Jordanian population. These unknown alleles are expected to be candidates for upstream or downstream mutations affecting the expression of beta-globin gene. The results provided the essential foundation for planning a national preventive program for thalassemia in Jordan and will help improving the medical services for the patients and their families by helping their clinicians and genetic counselors in evaluating their variants and designing their treatment regimens.

Phenotype-genotype relationships in monogenic disease: lessons from the thalassaemias

The remarkable phenotypic diversity of the beta-thalassaemias reflects the heterogeneity of mutations at the beta-globin locus, the action of many secondary and tertiary modifiers, and a wide range of environmental factors. It is likely that phenotype-genotype relationships will be equally complex in the case of many monogenic diseases. These findings highlight the problems that might be encountered in defining the relationship between the genome and the environment in multifactorial disorders, in which the degree of heritability might be relatively low and several environmental agents are involved. They also emphasize the value of an understanding of phenotype-genotype relationships in designing approaches to gene therapy.

HbF production in beta thalassaemia heterozygotes for the IVS-II-1 G-->A beta(0)-globin mutation. Implication of the haplotype and the (G)gamma-158 C-->T mutation on the HbF level

We studied the presence of the XmnI site and the beta-globin haplotype in 24 individuals, carriers of the IVSII-1 G-->A beta(0)-globin mutation, of whom fourteen had no detectable levels of HbF, while ten coming from 5 families, presented HbF levels ranging from 1.7 to 9% of the total Hb. Of these beta-thalassaemia heterozygotes with fetal hemoglobin, 6 were females and 4 were males with median HbF levels of 4.85% and 4% respectively, and an excess of (G)gamma chains (range (G)gamma/(A)gamma: 55/45-70/30). Of the group of carriers of beta-thalassaemia with HbF < 0.1, in all cases except one, IVSII-1 mutation was found associated with XmnI polymorphic site. Haplotype analysis in these individuals revealed that in 10 cases IVSII-1 was linked with haplotype IIIb, in 1 case with haplotype IIIa, and in 3 cases with haplotype IX. On the other hand, in the group of carriers with measurable levels of HbF, IVSII-1 was always associated with haplotype IIIa and the XmnI site was either in-homozygous or the heterozygous state in-cis or in-trans with the mutated beta-globin gene. In conclusion the results of the study of these families seem that XmnI site in-cis with the IVSII-1 does not induce HbF production when this beta(0)-thalassaemia mutation is associated with IIIb or IX haplotype. On the other hand the (G)gamma -158 C-->T mutation is associated with small amounts of HbF in IVSII-1 heterozygotes, when the beta-globin mutation is linked to haplotype IIIa.

From genotype to phenotype: genetics and medical practice in the new millennium

The completion of the human genome project will provide a vast amount of information about human genetic diversity. One of the major challenges for the medical sciences will be to relate genotype to phenotype. Over recent years considerable progress has been made in relating the molecular pathology of monogenic diseases to the associated clinical phenotypes. Studies of the inherited disorders of haemoglobin, notably the thalassaemias, have shown how even in these, the simplest of monogenic diseases, there is remarkable complexity with respect to their phenotypic expression. Although studies of other monogenic diseases are less far advanced, it is clear that the same level of complexity will exist. This information provides some indication of the difficulties that will be met when trying to define the genes that are involved in common multigenic disorders and, in particular, in trying to relate disease phenotypes to the complex interactions between many genes and multiple environmental factors.

Fetal hemoglobin expression in the compound heterozygous state for -117 (G-->A) Agamma HPFH and IVSII-745 (C-->G) beta+ thalassemia: a case study

We studied a family in which two inherited defects of the non-alpha-globin cluster segregate: Greek hereditary persistence of fetal hemoglobin (HPFH) and beta-thalassemia. The compound heterozygote is a healthy man with 43% HbF, Ggamma/Agamma ratio (27:73) differing from that of 10 simple heterozygotes for the Greek HPFH (92:8), normal levels of total Hb (13.3 g/dl), and reduced HbA2 levels comparing with the levels of beta-thal heterozygotes for the same mutation. Molecular analysis of the beta-globin genotype revealed the presence of the IVSII-745 (C-->G) beta+ RNA splice mutation in trans with the -117 G-->A Greek HPFH. The beta+ mutation was linked to haplotype VII and the Greek HPFH was associated with haplotype Ia. The father of the compound heterozygote carries the Greek HPFH in trans with the -158 C-->T on the Ggamma promoter, which is linked with haplotype IV. He presented 13.5% HbF with a Ggamma/Agamma ratio 75:25. His daughter was a compound heterozygote for the IVSII-745 mutation in trans with the -158 C-->T, while her HbF levels were 3.7% with a Ggamma/Agamma ratio 31:69.

Relationship between genotype and phenotype. Thalassemia intermedia

Thalassemia intermedia encompasses a number of clinical conditions ranging in severity from beta-thalassemia carrier state to transfusion-dependent thalassemia major. The molecular bases of thalassemia intermedia, only partially defined, are very heterogeneous, but in general any factor able to reduce the globin-chain imbalance results in a milder form of thalassemia. These factors are the presence of a silent or mild beta-thalassemia allele, associated with a high residual beta-globin production, and the coinheritance of alpha-thalassemia or of genetic determinants that increase the gamma-chain production. Less frequent mechanisms are double heterozygosity for beta-thalassemia and triplicated alpha genes, and the presence of a hyperunstable hemoglobin variant. However, for a consistent number of beta zero-thalassemia homozygotes with a thalassemia intermedia phenotype the modifying factor has not been defined yet. In contrast, there are simple beta-thalassemia carriers who, for unknown reasons, have an unusually severe clinical phenotype.

The hemoglobin E syndromes

Heterozygotes and homozygotes for HbE (beta 26, GAG-AAG, Glu-Lys) are microcytic, minimally anemic, and asymptomatic. The microcytosis is attributed to the beta thalassemic nature of the beta E gene, whereas the in vitro instability of HbE does not contribute to the phenotype. However, the compound heterozygote state HbE/beta thalassemia results in a variable, and often severe anemia, with the phenotype ranging from transfusion dependence to a complete lack of symptoms. This has been well documented in Thailand, but the basis of the interaction and the cause of the variability remains unexplained. We have studied 50 HbE/beta thalassemics from the UK and 16 from Oakland, CA and assessed the role of HbE instability. Time-course globin chain synthesis experiments have shown that instability is not an important factor in the steady state, but that at 41 degrees C newly synthesized Hb molecules are unstable. We have identified one family in which HbE interacts with pyrimidine 5' nucleotidase deficiency to cause severe anemia with Hb instability. The UK individuals, mostly of Bengali origin, have Hb's from 4.5-11 g/dl. The beta thalassemia mutation, alpha thalassemia and the Xmn 1 G gamma polymorphism do not explain this variability, but the relative and absolute amounts of HbF correlate significantly with total Hb. The Oakland individuals, mostly from Southeast Asia, show similar variation in Hb, which again is largely unexplained.

Genetic analysis of beta-thalassemia intermedia in Israel: diversity of mechanisms and unpredictability of phenotype

Molecular analysis was performed on 95 Israeli patients with thalassemia intermedia, representing 60 families of Arab (Moslem and Christian), Jewish, Druze, and Samaritan origin. There was a wide range of phenotypic severity, with baseline hemoglobin levels ranging from 5.5 to 10.7. Eighteen thalassemia mutations were found (29 genotypes), which were subdivided into groups, according to the severity of mutations. A consistently mild phenotype (10 families) was caused by compound heterozygosity for a silent mutation, such as -101 C-T or by coexistence of triplicated alpha-globin genes with thalassemia trait. In 39 thalassemia intermedia families, the genotype which was found was one which led to severe thalassemia intermedia, or, in other families, was associated with thalassemia major. Elevated hemoglobin F ameliorated the disease in some patients with a severe genotype. We did not find a beneficial effect of concurrent alpha-thalassemia in any of the families studied. In 11 families, only one beta-thalassemia allele was identified. One was a dominant thalassemia intermedia allele. Three additional families with heterozygous beta-thalassemia had excess alpha-globin genes (5 or 6 total). In 7 of these heterozygotes, no explanation was found for the thalassemia intermedia phenotype. Our results suggest a substantial influence of as yet unknown genetic modifiers. These findings have important implications for prenatal diagnosis and for the genetic counseling of families with thalassemia intermedia.

Severity of beta-thalassemia due to genotypes involving the IVS-I-6 (T-->C) mutation

Among individuals of Mediterranean or Middle Eastern descent, the IVS-I-6 (T-->C) mutation is one of the most common causes of beta-thalassemia. In this report, we describe the clinical phenotypes of a group of beta-thalassemia patients who are compound heterozygotes for the relatively mild IVS-I-6 (T-->C) beta-thalassemia mutation and more severe beta(+)- or beta (0)-thalassemia mutations. Although most of these patients are transfusion-dependent, the requirement for regular transfusions generally occurred late in childhood. A correlation between concomitant alpha-thalassemia and a mild transfusion-independent phenotype is not apparent, indicating the involvement of other ameliorating determinants.

gamma-mRNA and Hb F levels in beta-thalassaemia

The Hb F levels in beta-thalassaemia can be affected by factors both linked and unlinked to the beta-globin gene cluster. We have recently analysed a group of patients with a homozygosity for the IVS-I-6 (T-->C) mutation, showing a wide variation in Hb F levels (2-47%) which could not be accounted for by any sequence variation within regulatory elements of the beta-globin gene cluster. In order to further investigate factors underlying this phenotypic difference we have developed a competitive reverse transcription/polymerase chain reaction procedure and used this method to determine the relative amounts of gamma- and beta-mRNAs in 10 patients with the IVS-I-6 homozygosity and 15 heterozygous parents, two IVS-I-6/delta beta-thalassaemia compound heterozygotes, five homozygotes for the beta(+) IVS-I-110 (G-->A) mutation, and in two with a homozygosity for the beta(0) codon 39 (C-->T) mutation. Three heterozygotes were also included. The percentages of gamma/(gamma(+) beta) mRNA were 10-73% in the IVS-I-6 homozygotes and < 2% to 10% in their heterozygous parents. A direct relationship existed between the level of mRNA and the % Hb F. However, the relative gamma-mRNA levels in the IVS-I-6 homozygotes were higher than their Hb F levels, indicating a possible competition between the gamma and beta transcripts for translational factors with a less efficient initiation of protein synthesis on the gamma-mRNA or a preferential survival of cells with mainly beta-globin gene expression at the post-reticulocyte stage. The gamma-mRNA levels in the two IVS-I-6/delta beta-thalassaemia compound heterozygotes were 71% and 62%, similar to their Hb F levels (63% and 59%), and averaged 82% (range 65-91%) in the five IVS-I-110 homozygotes, and 97.5% in the two codon 39 homozygotes. The correlation between these values and the % Hb F could not be evaluated because of the transfusion regimens; however, the levels of gamma-mRNA were as expected for patients with these beta-thalassaemia alleles.