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.     

猪H-FABP基因多态片段的序列分析

利用PCR-RFLP方法在猪H-FABP基因内确定了3个变异酶切位点,分别为5′-上游区HinfI-RFLP、内含子2的HaeIII-RFLP和HinfI*-RFLP（HinfI和HinfI*代表不同区域的HinfI酶切反应）。对每个多态片段进行克隆测序分析,结果表明,5′-上游区HinfI-RFLP是由于1324位的碱基T→C的突变引起;在内含子2中,HaeIII-RFLP变异酶切位点在1811位,发生了C到G的突变;HinfI*-RFLP是由于1970位发生T→C的碱基替换。 Abstract:Three variant restriction sites of porcine H-FABP gene,including HinfI-RFLP in 5′-upsream,HaeIII-RFLP and HinfI*-RFLP in intron 2,were confirmed by PCR-RFLP method.The polymorphic fragments were cloned and sequenced.The results revealed a single nucleotide substitution of T→C at position 1324 for HinfI-RFLP,C→G at position 1811 for HaeIII-RFLP and T→C at position 1970 for HinfI*-RFLP,respectively.     

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.     

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.     

Molecular abnormality of a Japanese glucose-6-phosphate dehydrogenase variant (G6PD Tokyo) associated with hereditary non-spherocytic hemolytic anemia

Summary The entire coding sequence of a Japanese class 1 variant (G6PD Tokyo) was amplified by the polymerase chain reaction from genomic DNA. Nucleotide analysis by a direct sequencing technique revealed a unique nucleotide substitution (1246 G to A) in exon 10, which predicts a Glu to Lys substitution at the 416th amino acid. This is another member of a conspicuous mutation cluster surrounding the putative NADP-binding domain.     

A new polymorphic site in the G6PD gene

Summary A polymorphic restriction site has been found in intron 11 of the gene for glucose-6-phosphate dehydrogenase (G6PD). This site is produced by a TC substitution 13 bp upstream of exon 12, producing an NlaIII restriction site. In various populations there was a strong association between a T at nt 1311 of the G6PD cDNA and the presence of the NlaIII restriction site. Among African Americans, however, the presence of a C at nt 1311 was sometimes associated with the presence of a polymorphic NlaIII site.     

A role for U2/U6 helix Ib in 5' splice site selection.

Selection of pre-mRNA splice sites is a highly accurate process involving many trans-acting factors. Recently, we described a role for U6 snRNA position G52 in selection of the first intron nucleotide (+1G). Because some U2 alleles suppress U6-G52 mutations, we investigated whether the corresponding U2 snRNA region also influenced 5' splice site selection. Our results demonstrate that U2 snRNAs mutated at position U23, but not adjacent nucleotides, specifically affect 5' splice site cleavage. Furthermore, all U2 position U23 mutations are synthetic lethal with the thermosensitive U6-G52U allele. Interestingly, the U2-U23C substitution has an unprecedented hyperaccurate splicing phenotype in which cleavage of introns with a +1G substitution is reduced, whereas the strain grows with wild-type kinetics. U2 position U23 forms the first base pair with U6 position A59 in U2/U6 helix Ib. Restoration of the helical structure suppresses 5' splice site cleavage defects, showing an important role for the helix Ib structure in 5' splice site selection. U2/U6 helix Ib and helix II have recently been described as being functionally redundant. This report demonstrates a unique role for helix Ib in 5' splice site selection that is not shared with helix II.     

Mutation analysis of glucose-6-phosphate dehydrogenase (G6PD) variants in Costa Rica

Summary Glucose-6-phosphate dehydrogenase (G6PD) deficiency has previously been reported among both the black and white populations of Costa Rica. All 28 G6PD A — samples were found to be of the common G6PD A-^376G/202Atype. A previously described mutation associated with nonspherocytic hemolytic anemia, G6PD Puerto Limón, was found to be due to a GA transition at nucleotide (nt) 1192, causing a glulys substitution. Mutations in this region of the G6PD molecule seem invariably to be associated with chronic hemolytic anemia. G6PD Santamaria had been described previously in two unrelated white subjects. We found that both did, indeed, have the same mutations. In this variant the AG substitution at nt 376 that is characteristic of G6PD A was present, but an AT mutation at nt 542, apparently superimposed on the ancient G6PD A mutation, resulted in an aspval substitution. Thus, the gain of a negative charge at amino acid 126 was counterbalanced by the loss of a charge at amino acid 181, giving rise to a variant with the G6PD A mutation but with normal electrophoretic mobility.     

The interaction of the Escherichia coli mutD and mutT pathways in the prevention of A:T-->C:G transversions.

The Escherichia coli mutT mutator allele produces high frequencies of exclusively A:T-->C:G transversions. This is thought to be caused by a failure to prevent or remove A:G mispairs during DNA replication. The mutD5 mutator allele maps to the dnaQ locus which encodes the epsilon subunit of the DNA polymerase III holoenzyme. This subunit provides 3'-->5' exonuclease, proofreading, activity for removing mispaired nucleotides at the 3' end of the newly synthesized DNA strand. mutD5 has an altered epsilon resulting in reduced levels of proofreading and subsequent high mutation frequencies for all base-pair substitutions. We have analyzed the interaction between mutD5 and mutT-induced A:T-->C:G transversions by measuring reversion frequencies in mutD5 and mutT single mutator strains and mutD5mutT double mutator strains using the well-characterized trpA58 and trpA88 alleles. We find that the double mutator strains produce more A:T-->C:G substitutions than would be expected from simple additivity of the single mutator strains. We interpret this to mean that the two systems, at least in part, do act together to prevent the same mutational intermediate from producing A:T-->C:G transversions. It is estimated that over 90% of the mutT-induced A:G mispairs are corrected by proofreading at the trpA58 site while only about 30% are corrected at trpA88. Reversion frequencies in the mutD5mutT double mutator strains indicate A:G misincorporations occur about 100 x more frequently at trpA58 than at the trpA88 site. Using these and other data we also provide estimations of the fidelity contributions for mutT editing, proofreading and methyl-directed mismatch repair at the two trpA sites for both transversions and the transition that could be scored. In the case of A:T-->C:G transversions, both mutT editing and proofreading make major contributions in error reduction with mismatch repair playing a small or no role at all. For the A:T-->G:C transition, proofreading and mismatch repair were both important in preventing mutations while no contribution was observed for mutT editing.     

G6PD Ferrara I has the same two mutations as G6PD A(-) but a distinct biochemical phenotype

The cloning and sequencing of the normal glucose-6-phosphate dehydrogenase (G6PD) gene has led to the study of the molecular defects that determine enzymatic variants. In this paper, we describe the mutations responsible for the Ferrara I variant in an Italian man with a family history of favism, from the Po delta. Nucleotide sequencing of this variant showed a GA mutation at nucleotide 202 in exon IV causing a ValMet amino acid exchange, and a second AG mutation at nucleotide 376 in exon V causing an AsnAsp amino acid substitution. Although on the basis of its biochemical properties this variant was classified as G6PD Ferrara I, it has the same two mutations as G6PD A(-), which is common in American and African blacks, and as the sporadic Italian G6PD Matera. The mutation at nucleotide 202 was confirmed by NlaIII digestion of a polymerase chain reaction amplified DNA fragment spanning 109 bp of exon IV. The 109-bp mutated amplified sequence is not distinguishable from the normal sequence in single strand conformation polymorphism analysis.     

L-nucleotides and 8-methylguanine of d(C1m8G2C3G4C5LG6LC7G8C9G10)2 act cooperatively to promote a left-handed helix under physiological salt conditions

The structure and thermal stability of a hetero chiral decaoligodeoxyribonucleotide duplex d(C1m8 G2C3G4C5LG6LC7G8C9G10)d(C11m8G12C13G14C15LG16LC17G18C19G20) (O1) with two contiguous pairs of enantiomeric 2'-deoxy-L-ribonucleotides (C5LG6L/C15LG16L) at its centre and an 8-methylguanine at position 2/12 was analysed by circular dichroism, NMR and molecular modelling. O1 resolves in a left-handed helical structure already at low salt concentration (0.1 M NaCl). The central L2-sugar portion assumes a B* left-handed conformation (mirror-image of right-handed B-DNA) while its flanking D4-sugar portions adopt the known Z left-handed conformation. The resulting Z4-B2*-Z4 structure (left-handed helix) is the reverse of that of B4-Z2*-B4 (right-handed helix) displayed by the nearly related decaoligodeoxyribonucleotide d(mC1G2mC3G4C5L G6LmC7G8mC9G10)2, at the same low salt concentration (0.1 M NaCl). In the same experimental conditions, d(C1m8G2C3G4C5G6C7G8C9G10)2 (O2), the stereoregular version of O1, resolves into a right-handed B-DNA helix. Thus, both the 8-methylguanine and the enantiomeric step CLpGL at the centre of the molecule are needed to induce left-handed helicity. Remarkably, in the various heterochiral decaoligodeoxyribonucleotides so far analysed by us, when the central CLpGL adopts the B* (respectively Z*) conformation, then the adjacent steps automatically resolves in the Z (respectively B) conformation. This allows a good optimisation of the base-base stackings and base-sugar van der Waals interactions at the ZB*/B*Z (respectively BZ*/Z*B) junctions so that the Z4-B2*-Z4 (respectively B4-Z2*-B4) helix displays a Tm (approximately 65 degrees C) that is only 5 degrees C lower than the one of its homochiral counterpart. Here we anticipate that a large variety of DNA helices can be generated at low salt concentration by manipulating internal factors such as sugar configuration, duplex length, nucleotide composition and base methylation. These helices can constitute powerful tools for structural and biological investigations, especially as they can be used in physiological conditions.     

定点诱变G6PD基因的表达及突变酶的生物学功能研究

首次将9种人工定点诱变的G6PD基因转化至G6PD缺陷的大肠杆菌HB351(DE3)中表达,并对突变酶的生物学功能进行研究。初步证实G6PD基因m1376 G to T(Arg 459keu),1388 G to A(Arg 463 His)突变可降低酶活性并引起酶动力学改变。这可能与取代氨基酸的化学结构、所带电荷的性质及极性有关。这两个部位的精氨酸在酶与NADP~ 的结合过程中亦起到重要作用。赖氨酸取代精氨酸对酶与NADP~ 的结合影响不大。引入无义突变,证实G6PD第459位以后的氨基酸对酶活性有重要影响。     

The NT 1311 polymorphism of G6PD: G6PD Mediterranean mutation may have originated independently in Europe and Asia.

A polymorphic site exists in exon 11 of G6PD: in the wild-type enzyme, nucleotide (NT) 1311 is a C, but is some individuals from diverse populations a T is present instead. Nine of 54 X chromosomes from Europeans of mixed origins, nine of 41 X chromosomes of Ashkenazi Jewish subjects, three of 18 X chromosomes of Sicilians, five of 20 African X chromosomes, and nine of 20 Asian Indian X chromosomes had the mutant genotype. In contrast, the mutation was found in only three of 59 Oriental X chromosomes and in three of 30 Central/South American X chromosomes. The mutation was absent from four samples of chimpanzee DNA. Twenty-one of 22 male subjects from Mediterranean countries who had the G6PD Mediterranean 563T genotype investigated in the present study or reported previously had a T at NT 1311. Only one had the normal C at NT 1311. In contrast, both G6PD Mediterranean563T males from the Indian subcontinent had the normal C at NT 1311. These findings suggest that the same mutation at nucleotide 563 giving rise to G6PD Mediterranean may have arisen independently in Europe and in Asia.     

Mutations induced by 5-formyl-2'-deoxyuridine in Escherichia coli include base substitutions that can arise from mispairs of 5-formyluracil with guanine, cytosine and thymine

5-Formyluracil (5-foU) is a major oxidation product of thymine formed in yields comparable to that of 8-oxoguanine in DNA by ionizing radiation. Whereas the mutagenic effects of 8-oxoguanine are well understood, the investigation of the biological implications of 5-foU has so far been limited. Here we demonstrate that 5-formyl-2'-deoxyuridine (5-fodUrd) supplied to the growth medium of Escherichia coli induces several base substitutions at different frequencies at position 461 in the lacZ gene in the following order: A.T-->G.C>G.C-->A.T>G.C-->T.A>A.T-->T.A>A.T-->C.G. No induction of G.C-->C.G transversions was observed. It is inferred that 5-fodUrd will be incorporated into the DNA during cell growth, forming mispairs with guanine, cytosine and thymine during replication. It, thus, appears that cell growth in the presence of 5-fodUrd may represent a good model for elucidating the cellular effects of 5-foU residues in DNA.     

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.     

O6-methylguanine and A.C and G.T mismatches cause asymmetric structural defects in DNA that are affected by DNA sequence

Mismatched and modified base pairs are central to questions of DNA mutation and repair. NMR and X-ray crystallography of mispairs indicate little to no local helical distortion, but these techniques are not sensitive to more global distortions of the DNA molecule. We used polyacrylamide gel electrophoresis and thermal denaturation to examine A.C, G.T, and O6-methylG.T and O6-methylG.C mismatches synthesized in place of either of two adjacent G.C base pairs in synthetic DNA duplexes. Substitution for G.C at either position decreased the stability of the duplex; O6-methylguanine was more destabilizing in place of the 5'G than in place of the 3'G. Comparisons between polymers synthesized so that lesions occurred regularly spaced on the same side of the helix and polymers synthesized so that the lesions alternated from side to side on the helix showed that these lesions introduced helical distortion composed of (i) a symmetric frictional component, probably caused by localized bubble formation, and (ii) an asymmetric component indicative of a more global effect on the DNA molecule. Comparisons between these effects at the two adjacent positions show that the extent of structural perturbation depends on sequence context.     

Negative correlation of G+C content at silent substitution sites between orthologous human and mouse protein-coding sequences.

We conducted a genome-wide analysis of variations in guanine plus cytosine (G+C) content at the third codon position at silent substitution sites of orthologous human and mouse protein-coding nucleotide sequences. Alignments of 3776 human protein-coding DNA sequences with mouse orthologs having >50 synonymous codons were analyzed, and nucleotide substitutions were counted by comparing sequences in the alignments extracted from gap-free regions. The G+C content at silent sites in these pairs of genes showed a strong negative correlation (r = -0.93). Some gene pairs showed significant differences in G+C content at the third codon position at silent substitution sites. For example, human thymine-DNA glycosylase was A+T-rich at the silent substitution sites, while the orthologous mouse sequence was G+C-rich at the corresponding sites. In contrast, human matrix metalloproteinase 23B was G+C-rich at silent substitution sites, while the mouse ortholog was A+T-rich. We discuss possible implications of this significant negative correlation of G+C content at silent sites.     

Conformational change of helix G in the bacteriorhodopsin photocycle: investigation with heavy atom labeling and x-ray diffraction.

According to the current structural model of bacteriorhodopsin, Ile222 is located at the cytoplasmic end of helix G. We labeled the single cysteine of the site-directed mutant Ile222 --> Cys with p-chloromercuribenzoic acid and determined the position of the labeled mercury by x-ray diffraction in the unphotolyzed state, and in the MN photointermediate accumulated in the presence of guanidine hydrochloride at pH 9.5. According to the difference Fourier maps between the MN intermediate and the unphotolyzed state, the structural change in the MN intermediate was not affected by mercury labeling. The difference Fourier map between the labeled and the unlabeled I222C gave the position of the mercury label. This information was obtained for both the unphotolyzed state and the MN intermediate. We found that the position of the mercury at residue 222 is shifted by 2.1 +/- 0.8 A in the MN intermediate. This agrees with earlier results that suggested a structural change in the G helix. The movement of the mercury label is so large that it must originate from a cooperative conformational change in the helix G at its cytoplasmic end, rather than from displacement of residue 222. Because Ile222 is located at the same level on the z coordinate as Asp96, the structural change in the G helix could have the functional role of perturbing the environment and therefore the pKa of this functionally important aspartate.     

Mutagenic effects of 8-hydroxy-dGTP in live mammalian cells

The mutagenicity of an oxidized form of dGTP, 8-hydroxy-2'-deoxyguanosine 5'-triphosphate (8-OH-dGTP), was examined using COS-7 cells. 8-OH-dGTP and supF shuttle plasmid DNA were cointroduced by means of cationic liposomes, and the DNAs replicated in the cells were recovered and then transfected into Escherichia coli. 8-OH-dGTP induced A:T-->C:G substitution mutations in the COS-7 cells. This result agrees with previous observations indicating that DNA polymerases misincorporate 8-OH-dGTP opposite A in vitro, and that the oxidized deoxyribonucleotide induces A:T-->C:G transversions in E. coli. These results constitute the first direct evidence to show that 8-OH-dGTP actually induces mutations in living mammalian cells.