Experimental Characterization of Hb Flurlingen (HBA2: c.177 C > G, p.His > Gln) and Hb Boghé (HBA2: c.177 C > A, p.His > Gln) Reveals Contradictory HBA2 Expression and Translation Patterns Despite Identical Amino Acid Substitutions.

In this study, we describe the clinical features and provide experimental analyses of Hb Flurlingen (HBA2: c.177 C > G, p.His > Gln) that contrasted with Hb Boghé (HBA2: c.177 C > A, p.His > Gln). Despite the identical amino acid substitution in both variants, Hb Flurlingen shows the phenotype of α-thalassemia (α-thal), whereas Hb Boghé has no impact on α2-globin (HBA2) production. For in vitro transcription analysis, HBA2 expression constructs carrying the HBA2-WT (wild type), Hb Flurlingen and Hb Boghé sequences were generated and expressed in human bladder carcinoma 5637 cells for downstream analyses by quantitative real time-polymerase chain reaction (qReTi-PCR) and immunofluorochemistry (IFC). In silico analysis of secondary folding structures of the HBA2-WT, Hb Flurlingen and Hb Boghé mRNA sequences was performed using Mfold software. The gene transcription and translation analyses revealed that cells transfected with the Hb Flurlingen construct had significantly lower HBA2 transcription (-55.4%, p ≤ 0.01) and reduced protein synthesis when compared to the wild type group. In contrast, cells transfected with the Hb Boghé construct showed no significant changes in HBA2 transcription or translation activities when compared to the wild type group. The in silico prediction of possible effects of these mutations on the folding structures of the HBA2 transcripts showed a change of secondary folding pattern in the Hb Flurlingen transcript when compared to those of HBA2-WT and Hb Boghé. Our experimental findings support the clinical presentation of an α-thalassemic phenotype for Hb Flurlingen in contrast with Hb Boghé, despite identical amino acid substitutions. The results confirm the importance of experimental analysis in establishing the impact of novel base substitutions.

Validation of the immunochromatographic strip for α-thalassemia screening: a multicenter study.

α(0)-Thalassemia occurs from a deletion of 2 linked α-globin genes and interaction of these defective genes leads to hemoglobin (Hb) Bart's hydrops fetalis, the most severe and lethal thalassemia syndrome. Identification of α(0)-thalassemia carriers is thus essential for the prevention and control program. An immunochromatographic (IC) strip test was developed for rapid screening of α(0)-thalassemia by testing for Hb Bart's in the blood samples using a specific monoclonal antibody against Hb Bart's. To evaluate its sensitivity and specificity, the IC strip test was assessed in a cohort with various thalassemia genotypes from 4 different laboratories in Thailand and Australia. The result showed 97% sensitivity in α-thalassemia carriers with 2 α-globin genes deletion and Hb H disease. This is, in particular, the useful rapid screening test for regions where ß-thalassemia and homozygous Hb E are also common. Similar hematologic and Hb data make it impossible to address the concomitant inheritance of α(0)-thalassemia in these samples without polymerase chain reaction (PCR)-based techniques, leading to misdiagnosis of the risk of having Hb Bart's hydrops fetalis. However, α-globin genotyping should be carried out in samples with positive IC strip as positive reactivity was also observed in homozygous α(+)-thalassemia carriers who have 2 trans α-globin gene deletions. These results indicate that in combination with red blood cell indices, the IC strip test could rule out mass populations for further α(0)-thalassemia detection by PCR-based analysis. The Alpha Thal IC strip also has the potential to replace testing for Hb H inclusion bodies, as it appears to be more sensitive, specific, and less labor intensive.

α-thalassemia trait caused by frameshift mutations in exon 2 of the α2-globin gene: HBA2:c.131delT and HBA2:c.143delA.

We describe two frameshift mutations associated with an α-thalassemia (α-thal) phenotype, identified in three unrelated individuals investigated for persistent microcytosis. The first mutation, HBA2:c.131delT, is located in codon 43, and the second, HBA2:c.143delA, is located in codon 47. Both are due to single base pair deletions that cause a frameshift and a premature termination codon (PTC) at positions 48/49. The presence of a PTC at this position has been documented to result in nonsense mediated mRNA decay that would account for the thalassemic phenotype.

A molecular tool to assess the pathological relevance of alpha-globin DNA variants.

AIM: While the phenotype for heterozygous beta-thalassaemia is straightforward, it is more difficult to confirm a causative relationship for mutations in the alpha-globin genes. The aim of this study was to generate an in vitro system to evaluate the pathological relevance of α-globin mutations. METHODS: The novel variant HBA1:c.301-3C>G was used as a model. In silico analysis predicted an aberrant acceptor splice site in the mutant sequence. Subsequent in vitro studies included generation of and transfection of an expression vector carrying the HBA1:c.301-3C>G mutation, RNA purification, reverse-transcription polymerase chain reaction (RT-PCR) and cDNA sequencing. Immunofluorochemistry (IFC) with antibodies specific to the N- and or C- terminal of the α-globin protein was used in protein detection. RESULTS: In vitro molecular characterisation of this point mutation confirmed the preferential utilisation of a cryptic splice site at intron 2 of the pre-mRNA, resulting in a shift in the reading frame causing a premature termination codon (PTC) at codons 101/102 and generation of a truncated protein. CONCLUSION: We have described here a molecular tool to study mutations that affect α-globin pre-mRNA splicing and translation. We confirm in silico predictions of the consequences of the HBA1:c.301-3C>G mutation, proving aberrant RNA splicing and the production of a truncated α-globin protein.

Molecular and cellular characterization of a new α-thalassemia mutation (HBA2:c.94A>C) generating an alternative splice site and a premature stop codon.

The identification of α-thalassemia (α-thal) due to point mutations has been increasing significantly with the advancement of molecular diagnostic tools. We describe here the molecular and cellular characteristics of the thalassemia mutation HBA2:c.94A>C, a novel point mutation affecting the α2-globin gene, causing a mild α-thal phenotype in a male patient of undisclosed ethnicity, investigated for unexplained microcytosis. The detected mutation is located at the penultimate nucleotide (nt) of the first exon which we postulated might affect pre mRNA splicing. While an in silico analysis did not predict any aberrant splice variants, experimental analysis using our in vitro model for gene expression studies showed utilization of a cryptic splice site at codon 15 that resulted in an aberrant splice variant. As a result, a frameshift in the reading frame of the mature mRNA was produced, leading to the formation of a premature termination codon (PTC) between codons 48 and 49 in exon 2. This in turn leads to nonsense mediated mRNA decay (NMD) and the phenotype of α-thal.

Hb Lynwood [α107(G14) (-T) (α2) HBA2:c.323delT)] in conjunction with the α(3.7) deletion produces a moderately severe α-thalassemia phenotype.

We describe a novel frameshift mutation associated with an α-thalassemia (α-thal) phenotype in a patient of Sudanese origin investigated for persistent microcytosis. In addition to the α(3.7) deletion, a novel mutation on the α2 gene was detected: HBA2:c.323delT. This mutation causes a frameshift at codon 107 of the α2 gene. The result is a disturbed amino acid sequence for the following 24 amino acids, and a premature termination codon at position 132.

Hb East Timor [ß80(EF4)Asn→His, AAC>CAC (HBB c.241A>C)], a variant hemoglobin associated with normal hematology.

Routine hemoglobin (Hb) analyses identified a new ß-globin variant in a family from East Timor. The red cell indices were within normal limits for all affected family members. The variant is due to a missense mutation at amino acid codon 80 (AAC>CAC) which results in the substitution of histidine for asparagine.