Two new class III G6PD variants [G6PD Tunis (c.920A>C: p.307Gln>Pro) and G6PD Nefza (c.968T>C: p.323 Leu>Pro)] and overview of the spectrum of mutations in Tunisia.

We screened 423 patients referred to our laboratory after hemolysis triggered by fava beans ingestion, neonatal jaundice or drug hemolysis. Others were asymptomatic but belonged to a family with a history of G6PD deficiency. The determination of enzymatic activity using spectrophotometric method, revealed 293 deficient (143 males and 150 females). The molecular analysis was performed by a combination of PCR-RFLP and DNA sequencing to characterize the mutations causing G6PD deficiency. 14 different genotypes have been identified : G6PD A(-) (376A>G;202G>A) (46.07%) and G6PD Med (33.10%) were the most common variants followed by G6PD Santamaria (5.80%), G6PD Kaiping (3.75%), the association [c.1311T and IVS11 93c] (3.75%), G6PD Chatham (2.04%), G6PD Aures (1.70%), G6PD A(-) Betica (0.68%), the association [ 376G;c.1311T;IVS11 93c] (0.68%), G6PD Malaga, G6PD Canton and G6PD Abeno respectively (0.34%). Two novel missense mutations were identified (c.920A>C: p.307Gln>Pro and c.968T>C: p.323 Leu>Pro). We designated these two class III variants as G6PD Tunis and G6PD Nefza. A mechanism which could account for the defective activity is discussed.

Molecular analysis of the rare in(Lu) blood type: toward decoding the phenotypic outcome of haploinsufficiency for the transcription factor KLF1.

KLF1 encodes an erythroid transcription factor, whose essential function in erythropoiesis has been demonstrated by extensive studies in mouse models. The first reported mutations in human KLF1 were found in individuals with a rare and asymptomatic blood type called In(Lu). Here, we show that KLF1 haploinsufficiency is responsible for the In(Lu) blood type, after redefining this peculiar blood type using flow cytometry to quantify the levels of BCAM and CD44 on red blood cells. We found 10 (seven novel) heterozygous KLF1 mutations responsible for the In(Lu) blood type. Although most were obligate loss-of-function mutations due to the truncation of the DNA-binding domain of KLF1, three were missense mutations that were located in its DNA-binding domain and impaired the transactivation capacity of KLF1 in vitro. We further showed that the levels of the hemoglobin variants HbF and HbA(2) were increased in the In(Lu) blood type, albeit differently. The levels of the membrane glycoproteins BCAM and CD44 were also differently reduced on In(Lu) red blood cells. This biochemical and genetic analysis of the In(Lu) blood type tackles the phenotypic outcome of haploinsufficiency for a transcription factor.

Comparison of two known chromosomal rearrangements in the 뫧-globin complex with identical DNA breakpoints but causing different Hb A(2) levels.

We report three cases with very heterogeneous Hb A(2) levels caused by known chromosomal rearrangements in the ß-globin locus. These rearrangements had their breakpoints at the same region in the δ gene, leading either to the Senegalese δ(0)ß(+)-thalassemia (δ(0)ß(+)-thal) deletion or to an insertion of a δ gene, known as Anti-Lepore. One patient showed, apart from drastically increased Hb A(2) values of 17.0%, inconspicuous hematological values. He had an Anti-Lepore mutation with three copies of the δ gene, thus explaining the high Hb A(2) level. Two other patients had Hb A(2) levels in the lower borderline range and increased Hb F levels. Molecular analysis showed the Senegalese δ(0)ß(+)-thal deletion. One of them presented with an additional mild ß-thal mutation leading to ß-thal intermedia. These cases illustrate that different gene rearrangements with the same breakpoints in the δ gene can lead to different levels of Hb A(2) depending on the remaining number of δ genes.

Practical approach for characterization of glucose 6-phosphate dehydrogenase (G6PD) deficiency in countries with population ethnically heterogeneous: description of seven new G6PD mutants.

We present a rapid strategy based on Restriction Fragment Length Polymorphism (RFLP) analysis to characterize the more frequent glucose 6-phosphate dehydrogenase (G6PD) variants observed in a population with high gene flow. During a study involving more than 600 patients, we observed mainly G6PD A(-) (c.202G>A, c.376A>G; p.Val68Met, p.Asn126Asp), G6PD Mediterranean (Med) (c.563C>T, p.Ser188Phe), and G6PD Betica (c.376A>G, 542A>T; p.126Asn>Asp, 181Asp>Val) with addition of a few rare ones. A number of 10 abnormalities amounted to 92% of all the molecular defects. In addition, seven new mutations were found: three presented with acute hemolytic anemia following oxidative stress [G6PD Nice (c.1380G>C, p.Glu460Asp), G6PD Roubaix (c.811G>C, p.Val271Leu), and G6PD Toledo (c.496C>T, p.Arg166Cys)], three with different degrees of chronic hemolytic anemia [G6PD Lille (c.821A>T, p.Glu274Val), G6PD Villeurbanne (c.1000_1002delACC, p.Thr334del), and G6PD Amiens (c.1367A>T, p.Asp456Val)] and one found fortuitously G6PD Montpellier (c.1132G>A, p.Gly378Ser).

Clinical follow-up of hydroxyurea-treated adults with sickle cell disease.

Hydroxyurea-derived clinical and biological benefits and safety were retrospectively studied for 123 adult patients from 2 sickle cell disease referral centers during a total follow-up of 654 patient-years and total hydroxyurea exposure of 549 patient-years. Fifty-six adverse events occurred (incidence: 12%/patient-year), with leg ulcers being the most frequent. Adverse events could arise at any time and were usually reversible. No malignancy was observed. Clinical and biological benefits of our cohort were similar to those previously reported. Based on this relatively long retrospective study, the risk/benefit ratio for moderate hydroxyurea doses was satisfactory.

A dominant mutation in the gene encoding the erythroid transcription factor KLF1 causes a congenital dyserythropoietic anemia.

The congenital dyserythropoietic anemias (CDAs) are inherited red blood cell disorders whose hallmarks are ineffective erythropoiesis, hemolysis, and morphological abnormalities of erythroblasts in bone marrow. We have identified a missense mutation in KLF1 of patients with a hitherto unclassified CDA. KLF1 is an erythroid transcription factor, and extensive studies in mouse models have shown that it plays a critical role in the expression of globin genes, but also in the expression of a wide spectrum of genes potentially essential for erythropoiesis. The unique features of this CDA confirm the key role of KLF1 during human erythroid differentiation. Furthermore, we show that the mutation has a dominant-negative effect on KLF1 transcriptional activity and unexpectedly abolishes the expression of the water channel AQP1 and the adhesion molecule CD44. Thus, the study of this disease-causing mutation in KLF1 provides further insights into the roles of this transcription factor during erythropoiesis in humans.

Strategy for identification by mass spectrometry of a new human hemoglobin variant with two mutations in Cis in the beta-globin chain: Hb S-Clichy [beta6(A3)Glu-->Val; beta8(A5)Lys-->Thr].

Hemoglobinopathies are the most frequent genetic diseases in the world. Among them, the Hb S variant [beta6(A3)Glu-->Val], which, in the homozygous state, produces a severe disease known as sickle cell anemia with polymerization of Hb S inside red blood cells under hypoxic conditions. Additional mutations, in cis or in trans of the beta(S)-globin chain, may inhibit or enhance the polymerization process. We describe here a new hemoglobin (Hb) variant (Hb S-Clichy) which carries the beta(S)-globin chain and an additional mutation beta8(A5)Lys-->Thr. The variant was detected by routine electrophoretic techniques and cation exchange liquid chromatography (CE-LC). Globin chain separation by reversed phase LC (RP-LC) showed normal and abnormal beta chains, confirming that the additional abnormality was located in cis to Hb S. Electrospray ionization mass spectrometry (ESI-MS) gave a 57 Da mass decrease for the abnormal globin chain. The abnormal chain was isolated and submitted to trypsin digestion. Normal peptides betaT-1 and betaT-2 were not observed on the matrix-assisted laser desorption-time of flight (MALDI-TOF) mass spectrum but a new peptide betaT-1,2 was detected. Nano LC-ESI-MS/MS of the new peptide showed that the glutamic acid at codon 6 was replaced by a valine residue, and the lysine at codon 8 was replaced by a threonine residue, as confirmed by DNA sequencing. This example demonstrates that in a population where Hb S is present, every unidentified Hb needs to be clearly characterized to prevent major sickle cell syndromes. In addition, the identification of these variants must be considered in newborn screening for sickle cell disease, using either classical biochemical methods or MS techniques.

A rare G6PD variant (c.383T>G; p.128Leu>Arg) with a molecular pathophysiological mechanism similar to that of G6PD A- (68Val>Met, 126Asn>Asp).

We report the second documented observation of a rare class-III variant, we named G6PD Pyrgos, [c.383 T>G, p.128Leu>Arg] found in a Greek family. A 3-dimensional structure model for the enzyme shows that the region modified by the substitution is identical to that modified in G6PD A(-) (68Val>Met, 126Asn>Asp), suggesting a common underlying pathophysiological mechanism. Observation of this mutation in different Mediterranean regions suggests that it might be more widespread that initially supposed and, in the absence of molecular characterization, could be confused with other frequent variants.

Mutations in the paralogous human alpha-globin genes yielding identical hemoglobin variants.

The human alpha-globin genes are paralogues, sharing a high degree of DNA sequence similarity and producing an identical alpha-globin chain. Over half of the alpha-globin structural variants reported to date are only characterized at the amino acid level. It is likely that a fraction of these variants, with phenotypes differing from one observation to another, may be due to the same mutation but on a different alpha-globin gene. There have been very few previous examples of hemoglobin variants that can be found at both HBA1 and HBA2 genes. Here, we report the results of a systematic multicenter study in a large multiethnic population to identify such variants and to analyze their differences from a functional and evolutionary perspective. We identified 14 different Hb variants resulting from identical mutations on either one of the two human alpha-globin paralogue genes. We also showed that the average percentage of hemoglobin variants due to a HBA2 gene mutation (alpha2) is higher than the percentage of hemoglobin variants due to the same HBA1 gene mutation (alpha1) and that the alpha2/alpha1 ratio varied between variants. These alpha-globin chain variants have most likely occurred via recurrent mutations, gene conversion events, or both. Based on these data, we propose a nomenclature for hemoglobin variants that fall into this category.

Hb Gerland [alpha 55(E4)Val-->Ala]: a mutation found on the alpha1-globin gene.

The Hb Gerland [alpha 55(E4)Val-->Ala] mutation has been described in the alpha2-globin gene. We report here the same mutation in the paralogous alpha1-globin gene. This variant was found in a healthy 18-month-old boy of Chinese origin. Abnormal hemoglobin (Hb) fractions were visible on isoelectric focusing (IEF) and cation exchange high performance liquid chromatography (HPLC), with elution patterns differing from one system to another. Direct sequencing of the alpha-globin genes revealed a GTT>GCT (Val-->Ala) transversion at codon 55 of the alpha1-globin gene. We propose to name the variant encoded by the alpha1-globin gene Hb Gerland [A1], and the variant that is encoded by the alpha2-globin gene Hb Gerland [A2].

An alpha0-thalassemia-like mutation: Hb Suan-Dok [alpha109(G16)Leu-->Arg] carried by a recombinant -alpha(3.7) gene.

In a family of Spanish origin, five individuals presented a heterozygous alpha(0)-thalassemia (alpha-thal)-like phenotype. All had a -alpha(3.7) deletion with the recombinant alpha gene carrying the Hb Suan-Dok [alpha109(G16)LeuArg] mutation, proposed to be thalassemic. Thus, the abnormal chromosome carried an alpha(0)-thal-like allele that has to be taken into account for genetic counseling and prenatal diagnosis. The possibility of Hb H disease or hydrops fetalis should be considered when this allele is associated with alpha(+)-thal or with another alpha(0)-thal, respectively. Other described genotypes associated with Hb Suan-Dok are discussed.

A study of 36 unrelated cases with pure erythrocytosis revealed three new mutations in the erythropoietin receptor gene.

Thirty-six unrelated cases with erythrocytosis of unknown origin were investigated. Exons 5-8 of the erythropoietin receptor gene (EPOR), the von Hippel-Lindau gene, and the prolyl hydroxylase domain protein 2 gene (PHD2) were screened by direct DNA sequencing. The Janus kinase 2 mutation, JAK2 (Val617Phe), was screened by allele specific PCR. In this study, three new mutations of EPOR causing deletions in exon 8 were found: the first led directly to a stop codon [g.5957_5958delTT (p.Phe424X)], the second to a stop codon after one residue [g.5828_5829delCC (p.Pro381GlnfsX1)] and the third to a stop codon following a frameshift sequence of 23 residues [g.5971delC (p.Leu429TrpfsX23)]. One patient had a previously reported EPOR mutation [g.6146A>G (p.Asn487Ser)] and another, a silent one (g.5799G>A). All were heterozygotes. In addition, 2 patients were positive for JAK2 (Val617Phe), and 2 reported elsewhere, were mutated in the PHD2 gene [c.606delG (p.Met202IlefsX71).

Disturbance in the HIF-1alpha pathway associated with erythrocytosis: further evidences brought by frameshift and nonsense mutations in the prolyl hydroxylase domain protein 2 (PHD2) gene.

The hypoxia-inducible factor HIF-1 is the key regulator in cellular adaptation to hypoxia. Acting through a complex pathway, interconnected with VHL and kinases, it regulates a large number of genes, such as those involved in erythropoiesis, glycolysis, pH regulation, and angiogenesis. Recently, a missense mutation [c.950C>G (p.Pro317Arg)] in the prolyl hydroxylase domain protein 2 (PHD2) gene, whose encoded protein has HIF-1alpha as a substrate, provided evidence of the PHD2 role in a case of familial erythrocytosis. In this study, we looked for mutations in the PHD2 gene, in 74 patients with unidentified erythrocytosis. We found two heterozygous carriers of frameshift mutations [c.606delG (p.Met202IlefsX71) and c.840_841insA (p.Arg281ThrfsX3)]; both located in exon 1 and a heterozygous carrier of a nonsense mutation [c.1129C>T (p. Gln377X)] in exon 3. As a result of these mutations the encoded PHD2, if synthesized, would lose its catalytic activity. The genetic defects herein described are the first frameshift and nonsense mutations reported in the PHD2 gene and, as the previous missense mutation described, suggest that a decreased prolyl hydroxylase activity disturbing the oxygen-sensing pathway might be the cause of erythrocytosis. In addition to erythrocytosis, other complications, such as inflammatory arthromyalgia, have been observed in one case.

Hb Niigata [beta1(NA1)Val-->Leu] in a Romanian individual resulting from another nucleotide substitution than that found in the Japanese.

We present a new case of Hb Niigata that we named Hb Niigata(C), observed in a woman from Romania, with a mutation different from that described in Japanese (GTG-->CTG instead of GTG-->TTG). This single nucleotide substitution replaces the valine residue for leucine at codon 1 and causes retention of the N-terminal methionine leading to an elongated beta chain. This mutation was without any hematological consequences.

Hb Barika [alpha42(C7)Tyr-->His (alpha2)] leads to an alpha+ -Thalassemia-like syndrome.

In human deoxyhemoglobin (deoxyHb), the hydrogen bond between Aspbeta99(G1) and Tyralpha42(C7), located in the alpha1beta2 interface, is crucial for the stability of the T structure. All the variants that could arise from a single point mutation affecting codon beta99 have already been observed, leading always to erythrocytosis. Conversely, up to now, Hb Barika is the only example found in a patient in whom the alpha42 is mutated. From a biochemical point of view, for theoretical reasons, this substitution has already been extensively studied on recombinant hemoglobin (rHb). In the patient, Hb Barika is expressed at a level lower than expected for an alpha2 gene variant and leads to an alpha+-thalassemic-like syndrome.

Two French Caucasian families with dominant thalassemia-like phenotypes due to hyper unstable hemoglobin variants: Hb Sainte Seve [codon 118 (-T)] and codon 127 [CAG-->TAG (Gln-->stop]).

We report two French Caucasian families suffering from dominant thalassemia-like phenotypes due to hyper unstable hemoglobin (Hb) variants. In both cases, molecular analysis revealed a defect localized in the third exon of the beta-globin gene, resulting in dramatic changes of the Hb structure. The first one is a new variant, Hb Sainte Seve, that is associated with a frameshift mutation at codon 118 (-T). In the second family, the disease resulted from a truncated protein due to a stop mutation at codon 127 [CAG-->TAG (Gln-->Stop)]. These two observations are additional evidences of the important role played by helix H in Hb stability: its partial absence, or a large structural modification, seems to be the major reason for the hyper instability of such molecules.

Evaluation of the Bio-Rad VARIANT II HbA2/HbA1C Dual Program for measurement of hemoglobin concentrations and detection of variants.

In this work data obtained on the VARIANT II hemoglobin analyzer using the Dual Kit elution system were compared to those obtained with the beta-Thalassemia Short Program. Since many laboratories still use an earlier model of the hemoglobin analyzer, the Variant 1, these data were also compared to those obtained with the latter instrument. Our study is divided into two parts. The first is an evaluation of the precision of the VARIANT II for determining the levels of hemoglobin (Hb)A2 and Hb F. This was carried out for normal subjects, thalassemic patients and patients with HbS. The second part concerns the potential of this instrument in the presumptive identification of Hb variants.

Hb Montfermeil [beta 130(H8) Tyr-->Cys]: suggests a key role for the interaction between helix A and H in oxygen affinity of the hemoglobin molecule.

Hb Montfermeil [beta130(H8) Tyr-->Cys] is a high oxygen affinity variant causing erythrocytosis. The cysteine replacement is buried in the inside of the beta chain where it alters the interactions between helix A and H, with a further effect on helix E. This position has already been proposed to contribute to the difference in oxygen affinity between human and bovine hemoglobins. Three dimensional structural considerations and comparison of the functional behavior of other variants suggest that this region is an important determinant of the intrinsic oxygen affinity of the hemoglobin molecule.