Validation of dHPLC for molecular diagnosis of beta-thalassemia in Southern Italy

Beta-thalassemia, the most common hereditary anemia in the Mediterranean area, results from over 200 causative mutations in the beta-globin locus. The aim of this study was to validate a denaturing high-performance liquid chromatography (dHPLC)-based assay for postnatal and prenatal molecular diagnosis of beta-thalassemia in Southern Italy. Sixty beta-thalassemic patients, affected either by thalassemia intermedia or thalassemia major, were analyzed in a blind study. We also carried out prenatal molecular diagnosis in 12 couples at-risk for having affected offspring. Chorionic villi samples were subjected to dHPLC analysis upon molecular characterization of the parental beta-globin alleles. Direct sequence analysis was used to validate each result, showing an accuracy rate of 100% for dHPLC. Overall, our protocol was able to identify the responsible mutations in all 96 analyzed subjects (including 12 prenatals in at-risk pregnancies), detecting the eight most common mutations in Southern Italy. Three rare mutations (one of which, reported here for the first time) that standard mutation detection methods failed to reveal, were also identified. dHPLC assay proved to be a reliable, rapid, and sensitive method for detecting both common and rare mutations within the beta-globin gene. Because of this property our protocol has the potential to be implemented for mutational screening in different areas of high prevalence for beta-thalassemia.     

Simultaneous screening for beta-thalassemia mutations by chemical cleavage of mismatch.

We used the chemical cleavage of mismatch (CCM) method to screen the beta-globin gene simultaneously for Mediterranean beta-thalassemia mutations. The beta-globin gene was amplified in two segments encompassing the whole gene and hybridized to a corresponding labeled PCR product from a normal subject. All the known mutations tested were identified and discriminated. Three beta-thalassemic subjects with previously undiagnosed mutations were identified as carriers of two rare DNA changes. The inheritance of the mutations could be traced in family studies, showing the reliability of the method even for prenatal diagnosis. The beta-globin gene polymorphisms were also detected and the framework was determined for most alleles. Our results suggest further applicability of the CCM method as a means to screen a gene simultaneously for multiple mutations.     

Combine-ARMS: a rapid and cost-effective protocol for molecular characterization of beta-thalassemia in Malaysia

Beta-thalassemia major patients have chronic anemia and are dependent on blood transfusions to sustain life. Molecular characterization and prenatal diagnosis of beta3-thalassemia is essential in Malaysia because about 4.5% of the population are heterozygous carriers for beta-thalassemia. The high percentage of compound heterozygosity (47.62%) found in beta-thalassemia major patients in the Thalassaemia Registry, University of Malaya Medical Centre (UMMC), Malaysia, also supports a need for rapid, economical, and sensitive protocols for the detection of beta-thalassemia mutations. Molecular characterization of beta-thalassemia mutations in Malaysia is currently carried out using ARMS, which detects a single beta-thalassemia mutation per PCR reaction. We developed and evaluated Combine amplification refractory mutation system (C-ARMS) techniques for efficient molecular detection of two to three beta-thalassemia mutations in a single PCR reaction. Three C-ARMS protocols were evaluated and established for molecular characterization of common beta-thalassemia mutations in the Malay and Chinese ethnic groups in Malaysia. Two C-ARMS protocols (cd 41-42/IVSII #654 and -29/cd 71-72) detected the beta-thalassemia mutations in 74.98% of the Chinese patients studied. The CARMS for cd 41-42/IVSII #654 detected beta-thalassemia mutations in 72% of the Chinese families. C-ARMS for cd 41-42/IVSI #5/cd 17 allowed detection of beta-thalassemia mutations in 36.53% of beta-thalassemia in the Malay patients. C-ARMS for cd 41-42/IVSI #5/cd 17 detected beta-thalassemia in 45.54% of the Chinese patients. We conclude that C-ARMS with the ability to detect two to three mutations in a single reaction provides more rapid and cost-effective protocols for beta-thalassemia prenatal diagnosis and molecular analysis programs in Malaysia.     

Determination of the spectrum of beta-thalassemia genes in Spain by use of dot-blot analysis of amplified beta-globin DNA.

We have delineated the molecular lesions causing beta-thalassemia in Spain, a country that has witnessed the passage of different Mediterranean populations over the centuries, in order to evaluate the extent of heterogeneity of these mutations and to make possible simplified prenatal diagnosis of the disorder in that country. The use of the polymerase chain-reaction (PCR) technique to preferentially amplify beta-globin DNA sequences that contain the most frequent beta-thalassemia mutations in Mediterraneans enabled us to rapidly analyze 58 beta-thalassemia alleles in a dot-blot format either by hybridization with allele-specific radiolabeled oligonucleotide probes or by direct sequence analysis of the amplification product. The Spanish population carries seven different beta-thalassemia mutations; the nonsense codon 39 is predominant (64%), whereas the IVS1 position 110 mutation, the most common cause of beta-thalassemia in the eastern part of the Mediterranean basin, is underrepresented (8.5%). The IVS1 mutation at position 6 accounts for 15% of the defects and leads to a more severe form of beta+-thalassemia than originally described in most of the patients we studied. In this study, we demonstrate further the usefulness of the dot-blot hybridization of PCR-amplified genomic DNA in both rapid population surveys and prenatal diagnosis of beta-thalassemia.     

Major beta-globin gene mutations in eastern India and their associated haplotypes.

324 alleles of the beta-globin gene from unrelated thalassaemia patients native to the eastern region of India (mainly from the state of West Bengal) were analysed for beta-globin gene mutations by the amplification refractory mutation system (ARMS). The major mutations that were detected are IVS-1 pos 5 (G-C), codon 26 (G-A) and codon 30 (G-C) with frequencies of 0.45, 0.33 and 0.05, respectively. Haplotype analysis revealed a very strong linkage disequilibrium of IVS-1 pos 5 (G-C) with one particular haplotype. HbE was found to be associated with two major haplotypes. Codon 30 (G-C) was associated with a haplotype that is the same as that found in the African population. Haplotype associated with codon 8/9 (+G) was the same as that found in northwest India. These findings have implications for the use of molecular diagnosis for genetic counselling and prenatal diagnosis of beta-thalassaemia in this region.     

beta-Thalassemia due to a deletion of the nucleotide which is substituted in the beta S-globin gene.

Sickle-cell anemia results from an A leads to T transversion in the second nucleotide of codon 6 of the beta-globin gene. We now report an uncommon beta-thalassemia gene that contains a deletion of this nucleotide. Thus, one mutation (GAG leads to GTG) produces sickle-cell anemia, while the other (GAG leads to GG) eliminates beta-globin production. These data establish that different alterations affecting one specific nucleotide can produce either an abnormal hemoglobin or beta-thalassemia. Moreover, the nucleotide sequence comprising codons 6-8 of the beta-globin gene appears to be particularly susceptible to mutations affecting nucleotide number.     

Characterization of beta-thalassemia mutations in patients from the state of Rio Grande do Norte, Brazil

35 unrelated individuals were studied for characterization as either heterozygous or homozygous for beta-thalassemia. Molecular analysis was done by PCR/RFLP to detect the mutations most commonly associated with beta-thalassemia (β(0)IVS-I-1, β(+)IVS-I-6, and β(0)39). In the patients who showed none of these mutations, the beta-globin genes were sequenced. Of the 31 heterozygous patients, 13 (41.9%) had the β(+)IVS-I-6 mutation, 15 (48.4%) the β(0)IVS-I-1 mutation, 2 (6.5%) the β(+)IVS-I-110 mutation and 1 (3.2%) the β(+)IVS-I-5 mutation. IVS-I-6 was detected in the four homozygotes. The mutation in codon 39, often found in previous studies in Brazil, was not detected in the present case. This is the first study aiming at identifying mutations that determine beta-thalassemia in the state of Rio Grande do Norte.     

Serum ferritin and transferrin saturation levels in β⁰ and β(+) thalassemia patients

There have been few studies on the mutations that cause heterozygous beta-thalassemia and how they affect the iron profile. One hundred and thirty-eight individuals were analyzed, 90 thalasemic β? and 48 thalasemic β(+), identified by classical and molecular methods. Mutations in the hemochromatosis (HFE) gene, detected using PCR-RFLP, were found in 30.4% of these beta-thalassemic patients; heterozygosity for H63D (20.3%) was the most frequent. Ferritin levels and transferrin saturation were similar in beta-thalassemics with and without mutations in the HFE gene. Ferritin concentrations were significantly higher in men and in individuals over 40 years of age. Transferrin saturation also was significantly higher in men, but only in those without HFE gene mutations. There was no significant difference in the iron profile among the β? and β(+) thalassemics, with and without HFE gene mutations. The frequency of ferritin values above 200 ng/mL in women and 300 ng/mL in men was also similar in β? and β(+) thalassemics (P > 0.72). Our conclusion is that ferritin levels are variable in the beta-thalassemia, trait regardless of the type of beta-globin mutation. Furthermore, HFE gene polymorphisms do not change the iron profile in these individuals.     

The molecular basis of beta-thalassemia in Thailand: application to prenatal diagnosis.

To enable the prenatal diagnosis of beta-thalassemia by direct detection of the mutant beta-globin genes, we have determined the spectrum of mutations causing this disease in Thailand. The techniques employed included a combination of synthetic oligonucleotide probe hybridization, direct sequencing of genomic DNA enzymatically amplified by the polymerase chain reaction, and cloning and sequencing of the beta-globin genes. A total of 116 beta-thalassemia genes from 78 Hb E/beta-thalassemia patients and from 19 homozygous beta-thalassemia patients were analyzed, and the mutation was characterized in 112/116 (97%) of them. Eleven mutations were found, of which four (-CTTT in codon 41/42, AAG----TAG in codon 17, C----T in position 654 of the IVS-2 region, and A----G in position -28 upstream of the beta-globin gene) accounted for 83%; two previously undescribed mutations have been identified. The spectrum of beta-thalassemia mutations is similar to that reported among the Chinese. However, within the Thai population itself, patients with homozygous beta-thalassemia show a wider spread of mutations in comparison with the Hb E/beta-thalassemia group, in whom the frameshift 41/42 mutation predominates at a frequency of 62%. This difference in distribution may reflect the difference in ethnic origin of the two groups. Characterization of these mutations should aid the planning of a prenatal diagnosis program for beta-thalassemia in Thailand.     

Molecular characterization of beta-thalassemia in the Sardinian population.

This study reports the molecular characterization of beta-thalassemia in the Sardinian population. Three thousand beta-thalassemia chromosomes from prospective parents presenting at the genetic service were initially analyzed by dot blot analysis with oligonucleotide probes complementary to the most common beta-thalassemia mutations in the Mediterranean at-risk populations. the mutations which remained uncharacterized by this approach were defined by denaturing gradient gel electrophoresis (DGGE) followed by direct sequence analysis on amplified DNA. We reconfirmed that the predominant mutation in the Sardinian population is the codon 39 nonsense mutation, which accounts for 95.7% of the beta-thalassemia chromosomes. The other two relatively common mutations are frameshifts at codon 6 (2.1%) and at codon 76 (0.7%), relatively uncommon in other Mediterranean-origin populations. In this study we have detected a novel beta-thalassemia mutation, i.e., a frameshift at codon 1, in three beta-thalassemia chromosomes. The DGGE procedure followed by direct sequencing on amplified DNA is a powerful approach for the characterization of unknown mutations in this genetic system. The results herein presented allowed an expansion of the applicability of prenatal diagnosis by DNA analysis, to all couples at risk for beta-thalassemia in our population.     

Molecular mechanisms underlying thalassemia intermedia in Iran

To improve the differentiation of thalassemia intermedia from other hemoglobinopathies in Iran, four known genetic mechanisms-XmnI (G)gamma polymorphism, inheritance of mild and silent beta-thalassemia alleles, delta beta deletion, and coinheritance of alpha- and beta-thalassemia-were investigated in 52 Iranian individuals suspected to have thalassemia intermedia based on clinical and hematological characteristics. Beta-globin mutations were studied using a reverse-hybridization assay and sequencing of the total beta-globin gene. The XmnI (G)gamma polymorphism, the Sicilian delta beta deletion, and four alpha-globin mutations (-a(3.7), -a(4.2), -(MED), aaa(anti-3.7)) were studied using PCR-based techniques. The inheritance of the XmnI (G)gamma polymorphism with severe beta-thalassemia alleles in the homozygous or compound heterozygous state was the predominant mechanism observed in 27 individuals (55.3%). In five cases, this status overlapped with the -a(3.7)/aa genotype. The second most frequent cause for thalassemia intermedia (14.8%) was the inheritance of mild beta-thalassemia alleles, including IVS-I-6 (T > C), -88 (C > A), and + 113 (A > G). In three subjects (4.3%) the Sicilian delta beta deletion was identified. HbS in association with beta-zero-thalassemia was found in three patients with thalassemia intermedia phenotype. In 11 cases (21.3%) no causative genetic alteration could be identified. Our results reflect the diversity underlying thalassemia intermedia, and the limitations of the applied clinical, hematological, and molecular approaches for correct diagnosis. Some of the unresolved cases will offer an opportunity to discover additional molecular mechanisms leading to thalassemia intermedia.     

Molecular characterization of an atypical beta-thalassemia caused by a large deletion in the 5'' beta-globin gene region.

We describe a Canadian family of Czechoslovakian descent that came to our attention because of an HbA2 percentage approximately twice that of an average case of heterozygous beta-thalassemia. This unique phenotype suggested to us the possibility of a novel genetic mechanism being responsible for their beta-thalassemia. To investigate this possibility, we mapped, cloned, and sequenced the mutant beta-globin allele. This molecular analysis demonstrated the presence of a unique 4,237 base pair (bp) deletion extending from 3.3 kilobases (kb) 5' of the beta-globin mRNA cap site to approximately the middle of beta IVS-2. This truncated beta-globin gene further extends the heterogeneity of mutations known to cause beta-thalassemia and delineates new sequences involved in nonhomologous recombination events in the beta-globin gene region.     

Identification of five rare mutations including a novel frameshift mutation causing beta zero-thalassemia in Thai patients with beta zero-thalassemia/hemoglobin E disease.

6 out of 14 uncharacterized beta-thalassemia alleles from 187 Thai beta-thalassemia/HbE patients were identified by direct sequencing of DNA amplified by polymerase chain reaction. A novel mutation occurring from an insertion of adenosine in codon 95, which results in a shift of the reading frame with terminator at the new codon 101, was detected in one patient. In addition, two frameshift mutations not previously reported among the Thai population were also detected in 3 patients: one with a deletion of thymidine in codon 15 and two with an insertion of cytidine in codons 27/28. A frameshift mutation that occurred from a cytidine deletion in codon 41 was also found in one patient in this study. The remaining case was an amber mutation, GAG-TAG, in codon 43 in exon 2 of the beta-globin gene. These mutations bring the number of mutations known to be present in the Thai population to a total of 20, 15 of which were detected in beta-thalassemia/HbE patients.     

A new TATA box mutation detected at prenatal diagnosis for beta-thalassemia.

During the course of prenatal diagnosis for beta-thalassemia in Chinese patients, we encountered a mutation that was not detectable by oligonucleotides for the known Chinese mutations. Amplification of the beta-globin gene by the polymerase chain reaction and direct DNA sequencing revealed a previously undescribed -30 TATA box mutation which was carried by the father. Prenatal diagnosis was achieved, and the fetus did not inherit this beta-thalassemia allele.     

Molecular basis of beta-thalassemia in Morocco: possible origins of the molecular heterogeneity

We present the molecular spectrum of beta-thalassemia in the Moroccan population obtained by the identification of molecular defects responsible for this disease, and herewith we show that the Moroccan population is genetically heterogeneous; 18 different mutations have been found in the 158 beta-globin chromosomes studied. Eight mutations [codon 39 (C --> T), FSC-8 (-AA), IVS-II-745 (C --> G), -29 (A --> G), FSC-6 (-A), IVS-I-110 (G --> A), IVS-I-2 (T --> C), and IVS-I-1 (G --> A)] out of 18 beta-thalassemia mutations identified accounted for 76% of the Moroccan beta-thalassemia chromosomes. Restriction fragment length polymorphism (RFLP) haplotype analysis showed that the observed genetic diversity originated from both new mutational events and gene flow due to migration.     

Testing of G----A mutation in position 110 of a minor intron of beta-globin genes in patients with thalassemia in Azerbaijan

A point mutation G-A in the 110 position of the beta-globin gene small intron has been revealed by cloning and sequencing from the material of a homozygote beta-thalassemia patient in Azerbaijan. In the present study two allele-specific oligonucleotide probes for testing the mutation have been synthesized. Assessment frequency of the mutation among the beta-thalassemia patients in Azerbaijan has been performed with the use of the amplified beta-globin gene fragments obtained by using the thermostable DNA-polymerase from T. thermophilus with the subsequent dot-hybridization in gel of the amplified material with the oligonucleotide probes. The possibility to test the mutation by hybridization of the oligonucleotide probes with the donors and beta-thalassemia patients restricted genomic DNA has been analyzed. Only one of 50 thalassemia alleles of beta-globin genes under study has been shown to possess the mutation mentioned.     

A review on the origin and spread of deleterious mutants of the β-globin gene in Indian populations

Deleterious mutations of the human beta-globin gene are responsible for beta-thalassaemia and other haemoglobinopathies, which are the most common genetic diseases in Indian populations. A highly heterogeneous distribution of those mutations is observed in India and certain mutations are restricted to some extent to particular groups only. The reasons behind the geographical clustering and origin of the mutations in India is a highly debated issue and the evidence is conflicting. Our present article aims at tracing the origin of the deleterious beta-globin mutation and evaluates the role of different evolutionary forces responsible for the spread and present distribution of those mutations in Indian populations, using data from molecular biology and statistical methods. Mutations are generated essentially randomly, but "hot-spot" sites for mutation are reported for the beta-globin gene cluster, indicating sequence dependency of mutation. A single origin of a deleterious beta-globin mutation, followed by recombination (in a hot spot region) and/or interallelic gene conversion (within beta-globin gene) through time is the most plausible hypothesis to explain the association of those mutations with multiple haplotype backgrounds and frameworks. It is suggested that India is the place of origin of HbE and HbD mutations and that they dispersed to other parts of the would by migration. HbS mutants present in Indian populations are not of Middle East origin but rather a fresh mutation is the probable explanation for the prevalence among tribal groups. beta-thalassaemia represents a heterogeneous group of mutant alleles in India. Five common and twelve rare mutations have been reported in variable frequencies among different Indian populations. Gene flow of those mutant alleles from different populations of the world by political, military and commercial interactions possibly accounts for the heterogenous nature of beta-thalassaemia among Indians. A multiple allelic polymorphic system of the beta-globin gene exists in different populations. Dynamic interaction of the mutant alleles in the presence of different selective forces including falciparum malaria and biosocial patterns of Indian populations is discussed in order to explain the variable distribution and maintenance of those mutant alleles.     

The detection of beta-globin gene mutations in beta-thalassemia using oligonucleotide probes and amplified DNA

DNA amplification combined with the use of synthetic oligonucleotide probes has become an important tool in the identification of base substitutions. We report the use of this DNA amplification technique for the detection of mutations in beta-thalassemia. A series of oligonucleotide primers are synthesized which span the beta-globin gene; one primer is complementary to the coding strand and the other to the non-coding strand. The primers are chosen so that there is little homology with other DNA segments, especially the delta gene. Each set of primers spans an area of the gene between 100 and 300 bp, while the suspected mutation point is located between these two primers. With the use of such a primer set, the beta-globin gene region is amplified by denaturation, annealing and DNA synthesis. The amplification cycle is repeated 25-30 times, using the Klenow fragment of DNA polymerase I. The resulting amplified DNA is hybridized with normal and synthetic deoxynucleotide probes using a standard dot-blot method. We have designed a set of primers and experimental conditions which should prove useful to diagnostic centers for detection of numerous beta-thalassemia mutations.     

History and origin of beta-thalassemia in Turkey: sequence haplotype diversity of beta-globin genes.

In the present study we report the sequence haplotypes associated with 22 beta-globin gene mutations present in Turkey. Nine nucleotide polymorphisms and an (AT)xTy motif located at the 5' end of the beta-globin gene form the sequence haplotypes that were investigated in 204 unrelated beta-thalassemia and wild-type chromosomes from Turkey. Twelve sequence haplotypes were observed in the chromosomes analyzed and haplotypic heterogeneity was found in the wild-type beta-globin genes. Samples from the Black Sea region demonstrated a remarkable level of haplotypic heterogeneity in contrast to the homogeneity present in Central Anatolian samples. Of the 22 beta-globin mutations analyzed, 18 were related with single sequence haplotypes. This simple association led to the attempt to determine the origin of these mutations by comparing their frequencies in Turkey with those in other countries and/or the world distribution of the haplotypes carrying them. However, the presence of several exceptions for the "one haplotype/one mutation" rule showed that the beta-globin gene cluster is far from static. Each of the IVS-I-110 (G-->A), Cd 39 (C-->T), IVS-I-6 (T-->C), and -30 (T-->A) beta-globin mutations was associated with a minimum of two sequence haplotypes. This fact is best explained by the likelihood of strong recombination mechanisms taking place, rather than by assuming multiple origins for each of these alleles. According to our results, malarial selection for the oldest beta-thalassemia allele in Anatolia (i.e., IVS-I-110 G-->A) may have occurred between 6500 and 2000 B.C. From that date on, most of the common beta-thalassemia mutations in Turkey were established, and by the 13th century A.D. most of them were brought to frequencies close to those observed at present.