G6PD lozere and trinacria-like

Summary Two new G6PD variants have been found in red blood cells of the members of a French family originating from Lozere. The father is hemizygous for an electrophoretically fast variant with mild enzyme deficiency (50–60% of normal). The abnormal paternal G6PD gene is segregating in his daughter who is double heterozygous for maternal and paternal variants. This mutant enzyme, different from previously described variants is designated as Gd Lozère. The mother is heterozygous for another G6PD variant. Two sons are hemizygous for this latter mutant enzyme characterized by a moderate deficiency (25–30% of normal) and slower electrophoretic mobility with some slightly altered kinetic properties. This G6PD has been identified as Gd Trinacria like.These two abnormal enzymes are not associated with any hemolytic problem. Case reported is the first showing the segregation of two new mutant enzymes, distinct from common G6PD variants, among the members of the same family.     

G6PD Avenches and G6PD Moosburg: biochemical and erythrocyte membrane characterization

Two new G6PD variants with severe enzyme deficiency in Switzerland (G6PD Avenches, G6PD I) and in Germany (G6PD Moosburg, G6PD II) are described. One patient had suffered from severe postpartal hyperbilirubinemia, the other one presented with chronic hemolysis and remittent hyperbilirubinemia. Both variants showed diminished electrophoretic mobility, both variants were heat labile. The Michaelis-Menten constants KM for glucose-6-phosphate and for NADP+ were normal. 2-Desoxy-glucose-6-phosphate was utilized by G6PD I in a higher and by G6PD II at a lower rate than by the normal enzyme. Desamino-NADP+ and galactose-6-phosphate were utilized by both variants at a normal rate. The electrophoretic separation of membrane proteins of G6PD II showed both in the presence and in the absence of 6-mercaptoethanol no difference concerning the formation of membrane protein aggregates between patient and normal control.     

Gd- allele distribution patterns in Azerbaijan. III. The identification of mutant forms of glucose-6-phosphate dehydrogenase

In 28 families with G6PD deficiency living in 3 settlements of Shekii district of Azerbaijan 11 G6PD variants of II and III classes differing by kinetic properties were identified according WHO program. 9 of them are characterized with the same electrophoretic mobility. Comparison of G6PD spectra in two subpopulations and in a mixed group permits to make a conclusion about existence of common and rare G6PD alleles in examined population. They distribute by gene drift supported by natural selection. Among 7 samples of G6PD with normal and increased activity two new variants of IV class -- Nukha and Bash-Kungut -- were found.     

Genetic polymorphism of G6PD in a Bulgarian population

Summary Considerable genetic heterogeneity in G6PD was found in the Bulgarian population-14 G6PD variants isolated from 117 hemizygous carriers of G6PD deficiency. Of these, G6PD Mediterranean type was a polymorphic variant and G6PD Corinth occured with high frequency. Two new variants were identified-G6PD Rudosem and G6PD Nedelino. In a selected group of 78 subjects with clinical manifestations, four variants were established: G6PD Mediterranian, G6PD Corinth, G6PD Seattle and G6PD Ohut II.     

Glucose-6-phosphate dehydrogenase (G6PD) Guantánamo and G6PD Caujerí: Two new glucose-6-phosphate dehydrogenase-deficient variants found in Cuba

Glucose-6-phosphate dehydrogenase (G6PD) deficiency was identified in two children who were studied because of hemolytic episodes. The electrophoretic and kinetic properties of the mutant enzymes allowed us to conclude that both of them were new variants. They were named G6PD Guantánamo and G6PD Caujerí.     

G6PD-MutDB: a mutation and phenotype database of glucose-6-phosphate (G6PD) deficiency

Glucose-6-phosphate dehydrogenase (G6PD) deficiency is the most common hereditary enzymatic disorder of red blood cells in humans due to mutations in the G6PD gene. The G6PD enzyme catalyzes the first step in the pentose phosphate pathway to protect cells against oxidative stress. Mutations in the G6PD gene will cause functional variants with various biochemical and clinical phenotypes. So far, about 160 mutations along with more than 400 biochemical variants have been described. G6PD-MutDB is a disease-specific resource of G6PD deficiency, collecting and integrating G6PD mutations with biochemical and clinical phenotypes. Data of G6PD deficiency is manually extracted from published papers, focusing primarily on variants with identified mutation and well-described quantitative phenotypes. G6PD-MutDB implements an approach, CNSHA predictor, to help identify a potential chronic non-spherocytic hemolytic anemia (CNSHA) phenotype of an unknown mutation. G6PD-MutDB is believed to facilitate analysis of relationship between molecular mutation and functional phenotype of G6PD deficiency owing to convenient data resource and useful tools. This database is available from http://202.120.189.88/mutdb.     

Two point mutations are responsible for G6PD polymorphism in Sardinia.

The human X-linked gene encoding glucose 6-phosphate dehydrogenase (G6PD) is highly polymorphic; more than 300 G6PD variants have been identified. G6PD deficiency in different geographical areas appears to have arisen through independent mutational events, but within the same population it may also be heterogeneous. One example is the island of Sardinia, where careful clinical and biochemical studies have identified four different G6PD variants. We cloned and sequenced the four G6PD variants from Sardinia and found that only two mutations are responsible for G6PD deficiency in this area: one mutation is the cause of the G6PD Seattle-like phenotype, a milder form of G6PD deficiency; the other mutation is responsible for all forms of very severe G6PD deficiency in Sardinia and, possibly, in the Mediterranean.     

Glucose-6-phosphate dehydrogenase (G6PD) Iserlohn and G6PD Regensburg: two new severe enzyme defects in German families

Two new inheritable variants of glucose-6-phosphate dehydrogenase have been found in two unrelated German families. Patients with one variant (G6PD Iserlohn, also referred to as G6PD I) suffered from intermittent hemolytic crises caused by fava beans; patients with the other variant (G6PD Regensburg, G6PD II) disclosed chronic nonspherocytic hemolytic anemia aggravated by drug treatment. Due to their unusual biochemical characteristics, the new variants were designated G6PD Iserlohn and G6PD Regensburg. Both variants showed a reduction of enzyme activity to about 6% of the normal in erythrocytes, normal electrophoretic mobility, increased affinity for glucose-6-phosphate, a reduced affinity for NADP and a pH optimum in the neutral region (7.0 and 7.5). G6PD Iserlohn had a decreased affinity for the inhibitor NADPH; G6PD Regensburg had a normal inhibitor constant. Deamino NADP was utilized at an increased rate by G6PD Regensburg. G6PD Iserlohn was thermostable, G6PD Regensburg mildly instable. G6PD activity in leukocytes was normal in G6PD Iserlohn and reduced to the same degree as in erythrocytets in G6PD Regensburg. The cause of the decreased activity of G6PD Iserlohn appears to be in vivo instability; in G6PD Regensburg further mechanisms might include reduced specific activity or reduced synthesis of the variant enzyme.     

Molecular abnormality of G6PD Konan and G6PD Ube,the most common glucose-6-phosphate dehydrogenase variants in Japan

G6PD Konan and G6PD Ube are the most common glucose-6-phosphate dehydrogenase (G6PD) variants found in Japan. To clarify the molecular abnormality of these two variants, the entire coding region was amplified by polymerase chain reaction from genomic DNA (G6PD Konan) or cDNA (G6PD Ube). Direct sequencing revealed that both variants have the same nucleotide substitution (241 C to T) in exon 4, which predicts an Arg to Cys substitution at amino acid 81.     

Mutant forms of erythrocyte glucose 6-phosphate dehydrogenase in Ashkenazi. Description of two new variants: G6PD kirovograd and G6PD zhitomir

Two new variants of erythrocyte glucose 6-phosphate dehydrogenase are discovered in 3 unrelated Ashkenazi Jew patients with severe deficiency of enzyme. Both variants have a resemblance to 2 other variants in Ashkenazi: G6PD Boston and G6PD Kilgore, but have a significantly higher affinity for substrates and their analogues and are not associated with chronic hemolytic disease. Probably, all 4 variants arise from two ancestral mutations.     

Molecular genetics of the glucose-6-phosphate dehydrogenase (G6PD) Mediterranean variant and description of a new G6PD mutant, G6PD Andalus1361A

Glucose-6-phosphate dehydrogenase (G6PD; E.C.1.1.1.49) deficiency is the most common human enzymopathy; more than 300 different biochemical variants of the enzyme have been described. In many parts of the world the Mediterranean type of G6PD deficiency is prevalent. However, G6PD Mediterranean has come to be regarded as a generic term applied to similar G6PD mutations thought, however, to represent a somewhat heterogeneous group. A C----T mutation at nucleotide 563 of G6PD Mediterranean has been identified by Vulliamy et al., and the same mutation has been found by De Vita et al. in G6PD Mediterranean, G6PD Sassari, and G6PD Cagliari. The latter subjects had an additional mutation, at nucleotide 1311, that did not produce a coding change. We have examined genomic DNA of five patients--four of Spanish origin and one of Jewish origin--having enzymatically documented G6PD Mediterranean. All had both the mutation at nucleotide 563 and that at nucleotide 1311. A sixth sample, resembling G6PD Mediterranean kinetically but with a slightly rapid electrophoretic mobility, was designated G6PD Andalus and was found to have a different mutation, a G----A transition at nucleotide 1361, producing an arginine-to-histidine substitution. These studies suggest that G6PD Mediterranean is, after all, relatively homogeneous.     

Characterization of some erythrocyte G6PD variants by isoelectric focusing

Summary The existence of a microheterogeneity of glucose-6-phosphate dehydrogenase (G6PD) in human erythrocyte lysates has been previously demonstrated using isoelectric focusing (Der Kaloustian et al., 1974; Turner et al., 1975). The application of this method, modified in some aspects, to the identification of various G6PD variants led to interesting conclusions. The results reported here have been obtained from a study of four distinct molecular types: Gd(-)Mediterranean, Gd(-) Kabyle, the African Gd(+) A, and a new almost undescribed G6PD variant with severe enzyme deficiency named Gd(-) Muret.     

Molecular identification of mutations in G6PD gene in patients with favism in Iran

Glucose 6-phosphate dehydrogenase is a highly polymorphic enzyme encoded by a human X-linked gene (Xq2.8). This enzyme catalyses the first step of pentose phosphate pathway, that converts glucose 6-phosphate to 6-phosphogluconate with production of NADPH2. G6PD deficiency is the most common human metabolic inborn error affecting more than 400 million people world wide. The main clinical manifestations are acute hemolytic anemia and jaundice, triggered by infection or ingestion of Fava beans or oxidative drugs. A predominant variant of G6PD named Mediterranean is often associated with favism. This has been evident in several countries including Northern coastal provinces of Iran. Other current variants are Chatham and Cosenza. Molecular identification of the most prevalent mutations in G6PD gene was carried out in 71 males and females with G6PD deficiency. They were from Iranian Northern province of Golestan. DNA was extracted from blood samples and analyzed for known G6PD mutation by PCR and restriction fragment length polymorphisms (RFLP) technique. Adapting this method, revealed that Mediterranean mutation at nt 563(C-->T) is predominant in the area (69%) and 26.7% of patients have Chatham mutation at nt 1003(G-->A). Findings indicate a higher prevalence of these mutations, in Golestan compared to Mazandaran (66.2% Mediterranean and 19% Chatham mutation) and Gilan (86.4% Mediterranean and 9.71% Chatham mutations). Cosenza mutation at nt 1376(G-->C), by PCR-RFLP technique was not found among other 3 samples (4.3%). The similarity of these results with mutations in Italy indicates probable existence of a common ancestral origin in the observed populations.     

Patterns in the distribution of GPD- alleles in Azerbaijan. I. Incidence and polymorphism of glucose-6-phosphate dehydrogenase deficiency in the Shekii region of the Azerbaijan SSR

Through examination of G6PD deficiency among 939 pupils of Shekii district of Azerbaijan 52 hemi-, 10 homo- and 58 heterozygous carriers of defect were found. Relatives of probands--inhabitants of 3 settlements in the Shekii district-- were examined on G6PD deficiency too. Average hemizygote frequency is 11.11%, heterozygotes frequency is 12.9%. The cases of disaccordance between phenotype and genotype in female carriers of Gd- are analysed using pedigree data.     

Molecular characterisation of the glucose-6-phosphate dehydrogenase (G6PD) Ferrara II variant

During the last ten years, molecular biological techniques such as cloning and sequencing and, more recently, polymerase chain reaction (PCR) amplification have led to the identification of the molecular defects responsible for more than fifty glucose-6-phosphate dehydrogenase (G6PD) variants. In this paper, we report the identification of the molecular abnormality underlying the G6PD Ferrara II variant, present in the Po delta area of Northern Italy. Biochemical characterisation shows an enzymatic activity of about 15% of normal (WHO class III), slow electrophoretic mobility, low Km for G6P, high percentage substrate analogue utilisation and a biphasic pH optimum curve. After PCR amplification, non-radioiso-topic single-strand conformation polymorphism analysis carried out for the entire coding region has revealed a mobility shift in exon 8. Nucleotide sequencing has demonstrated a missense 844 G>C mutation, causing an Asp>His amino-acid replacement, known as being responsible for G6PD Seattle, G6PD Modena and G6PD Lodi.     

Two commonly occurring nucleotide base substitutions in Chinese G6PD variants

Using a direct PCR sequencing technique, we have identified two DNA base substitutions in 8 different biochemical G6PD variants of Chinese origin. Neither one of these abnormalities has been reported in other ethnic groups. An abnormality (C1) of G to T substitution at cDNA 1376 causing an amino acid change from Arg to Leu has been found in 3 variants. Another abnormality (C2) of G to A substitution at cDNA 1388 causing an amino acid change from Arg to His has been found in 5 variants. Both C1 and C2 are located in exon 12 of the G6PD gene and are only 12 base pairs apart. However, C1 is associated with a significant increase in the deamino-NADP utilization rate, whereas C2 is not. Taken together, our data suggest that C1 and C2 are very common among Chinese with a G6PD deficiency and exon 12 may define an important functional domain of the human G6PD.     

Glucose 6-Phosphate dehydrogenase variants: A unique variant (G6PD Kobe) showed an extremely increased affinity for galactose 6-phosphate and a new variant (G6PD Sapporo) resembling G6PD Pea Ridge

Summary Two new glucose 6-phosphate dehydrogenase (G6PD) variants associated with chronic nonspherocytic hemolytic anemia were discovered. G6PD Kobe was found in a 16-year-old male associated with hemolytic crisis after upper respiratory infection. The enzyme activity of the variant was about 22% of that of the normal enzyme. The main enzymatic characteristics were slower than normal anodal electrophoretic mobility, high Km G6P, increased thermal-instability, an acidic pH optimum, and an extremely increased affinity for the substrate analogue, galactose 6-phosphate (Gal-6P).G6PD Sapporo was found in a 3-year-old male associated with drug-induced hemolysis. The enzyme activity was extremely low, being 3.6% of normal. In addition, this variant showed high Ki NADPH and thermal-instability.G6PD Kobe utilized the artificial substrate Gal-6P effectively as compared with the common natural substrate, glucose 6-phosphate. In G6PD Sapporo, NADPH could not exert the effect of product inhibition. The structural changes of these variants are expected to occur at the portions inducing conformational changes of the substrate binding site of the enzyme.     

G6PD Ube, a glucose-6-phosphate dehydrogenase variant found in four unrelated Japanese families.

A total of 6,120 Japanese males were screened for glucose-6-phosphate dehydrogenase deficiency (G6PD). Five cases with the deficiency were discovered. Two of them and an additional two cases have the same variant, G6PD Ube, characterized by moderate enzyme deficiency, fast moving enzyme activity on electrophoresis, high Ki Nadph, utilization of substrate analogues, kinetics, pH optima, and stability. This variant was distinguished for G6PD A- and from other Oriental variants by biochemical parameters. Differences in the frequency and type of the variants between southern Asia and Japan, suggest that the Japanese who have been isolated on islands where malaria is not endemic, may have developed their own variant traits.     

Characterization of G6PD Genotypes and Phenotypes on the Northwestern Thailand-Myanmar Border

Mutations in the glucose-6-phosphate dehydrogenase (G6PD) gene result in red blood cells with increased susceptibility to oxidative damage. Significant haemolysis can be caused by primaquine and other 8-aminoquinoline antimalarials used for the radical treatment of Plasmodium vivax malaria. The distribution and phenotypes of mutations causing G6PD deficiency in the male population of migrants and refugees in a malaria endemic region on the Thailand-Myanmar border were characterized. Blood samples for G6PD fluorescent spot test (FST), G6PD genotyping, and malaria testing were taken from 504 unrelated males of Karen and Burman ethnicities presenting to the outpatient clinics. The overall frequency of G6PD deficiency by the FST was 13.7%. Among the deficient subjects, almost 90% had the Mahidol variant (487G>A) genotype. The remaining subjects had Chinese-4 (392G>T), Viangchan (871G>A), Açores (595A>G), Seattle (844G>C) and Mediterranean (563C>T) variants. Quantification of G6PD activity was performed using a modification of the standard spectrophotometric assay on a subset of 24 samples with Mahidol, Viangchan, Seattle and Chinese-4 mutations; all samples showed a residual enzymatic activity below 10% of normal and were diagnosed correctly by the FST. Further studies are needed to characterise the haemolytic risk of using 8-aminoquinolines in patients with these genotypes.