The same extra FokI cleavage site exists in glucose-6-phosphate dehydrogenase variants A(+) and A(-).

Two common variants of glucose-6-phosphate dehydrogenase (G6PD), i.e., A(+) and A(-), exist in blacks in high frequencies. The mutation of the A(+) gene is a single nucleotide transition, A/G in equilibrium Asp) in the G6PD protein and produces an additional FokI cleavage site of the mutation site. Thus, the FokI fragment types detected by the genomic clone that contain the mutation site differ in the normal B(+) DNA and the variant A(+) DNA. The FokI fragment type of the variant A(-) is the same as that of the A(+). Since A(+) and A(-) enzymes differ at the protein level, the A(-) gene was presumably evolved by stepwise mutations through the A(+) gene.     

A single nucleotide base transition is the basis of the common human glucose-6-phosphate dehydrogenase variant A (+)

The X-chromosome-linked glucose-6-phosphate dehydrogenase (G6PD) A(+) is a common variant found in about 20% of blacks. The amino acid substitution of Asp in the variant G6PD A(+) for Asn in the normal G6PD B(+) was previously found (A. Yoshida, 1967, Proc. Natl. Acad. Sci. USA 57: 835), but the exact substitution position has not been identified. By screening a DNA library prepared from genomic DNA of a G6PD A(+) male subject, we obtained a genomic clone that contained the mutation site. Characterization of the clone revealed that AT----GC transition occurred in the variant A(+) gene, thus producing the amino acid substitution Asn----Asp at the 142nd position from the NH2 terminus of the enzyme. The nucleotide change created an additional FokI cleavage site in the variant A(+) gene; thus, the FokI fragment type of the variant subjects differed from that of normal B(+) subjects in Southern blot hybridization analysis.     

The origin of glucose-6-phosphate-dehydrogenase (G6PD) polymorphisms in African-Americans.

DNA samples from 54 male Afro-Americans were examined for glucose-6-phosphate dehydrogenase (G6PD) genotypes G6PD A(+)376G, G6PD A(-)202A/376G, and G6PD B and for polymorphisms in intron 5 (PvuII), at nucleotide 1311, and at nucleotide 1116 (PstI). In the G6PD B subjects, the nucleotide 1311 mutation and the PstI site appeared to be in linkage equilibrium. No PvuII+ G6PD men were encountered. The G6PD A(+) mutation was in disequilibrium with respect to both the nucleotide 1311 mutation and the PstI site. The G6PD A- nucleotide 202 mutation was in disequilibrium with all three polymorphic sites. No conclusion could be drawn with respect to the PvuII site, except that it preceded the nucleotide 202 (A-) mutation. We conclude from these and our previous studies that G6PD B is the most ancient genotype. The nucleotide 1311 mutation, with its worldwide distribution, probably occurred next. The PstI mutation, limited to Africans, probably arose next and is more ancient than the A(+) mutation, which occurred in a gene without either the PstI or the 1311 mutation. G6PD A-202A/376G is the most recent of these mutations and is still in linkage disequilibrium with all of the sites. Presumably it occurred in an individual with both the A(+) and PvuII mutations.     

Creating highly specific nucleases by fusion of active restriction endonucleases and catalytically inactive homing endonucleases

Zinc-finger nucleases and TALE nucleases are produced by combining a specific DNA-binding module and a non-specific DNA-cleavage module, resulting in nucleases able to cleave DNA at a unique sequence. Here a new approach for creating highly specific nucleases was pursued by fusing a catalytically inactive variant of the homing endonuclease I-SceI, as DNA binding-module, to the type IIP restriction enzyme PvuII, as cleavage module. The fusion enzymes were designed to recognize a composite site comprising the recognition site of PvuII flanked by the recognition site of I-SceI. In order to reduce activity on PvuII sites lacking the flanking I-SceI sites, the enzymes were optimized so that the binding of I-SceI to its sites positions PvuII for cleavage of the composite site. This was achieved by optimization of the linker and by introducing amino acid substitutions in PvuII which decrease its activity or disturb its dimer interface. The most specific variant showed a more than 1000-fold preference for the addressed composite site over an unaddressed PvuII site. These results indicate that using a specific restriction enzyme, such as PvuII, as cleavage module, offers an alternative to the otherwise often used catalytic domain of FokI, which by itself does not contribute to the specificity of the engineered nuclease.     

G6PD deficient alleles and haplotype analysis of human G6PD locus in São Tomé e Príncipe (West Africa)

A population sample from S?o Tomé e Príncipe (West Africa) was screened for the G6PD-deficient variants A- (376G/202A), Betica (376G/968C), and Santa Maria (376G/542T). G6PD locus haplotype diversity was also investigated using six intragenic RFLPs (FokI, PvuII, BspHI, PstI, BclI, NlaIII) and a (CTT)n microsatellite 18.61 kb within the G6PD locus. The estimated frequencies of the G6PD*B normal allele, the G6PD*A variant (376G), and the G6PD*A- allele were 0.698, 0.194, and 0.108, respectively. G6PD variants Betica and Santa Maria were not found. Similar levels of microsatellite diversity were found on variants G6PD*B and G6PD*A (H = 0.61 and 0.68, respectively), indicating a similar age for both alleles. All G6PD*A- alleles share the RFLP-microsatellite haplotype ++(-)+(-)+/195, the same haplotype described in nearly all the *A-alleles from sub-Saharan, Mexican Mestizo, and Portuguese populations, consistent with a single and recent origin of the G202A mutation on this *A haplotype.     

Studies of the recognition sequence of phi X174 gene A protein. Cleavage site of phi X gene A protein in St-1 RFI DNA.

It is already known that phi X gene A protein converts besides phi X RFI DNA also the RFI DNAs of the single-stranded bacteriophages G4, St-1, alpha 3 and phi K into RFII DNA. We have extended this observations for bacteriophages G14 and U3. Restriction enzyme analysis placed the phi X gene A protein cleavage site in St-1 RF DNA in the HinfI restriction DNA fragment F10 and in the overlapping HaeIII restriction DNA fragment Z7. The exact position and the nucleotide sequence at the 3'-OH end of the nick were determined by DNA sequence analysis of the single-stranded DNA subfragment of the nicked DNA fragment F10 obtained by gelelectrophoresis in denaturing conditions. A stretch of 85 nucleotides of St-1 DNA around the position of the phi X gene A protein cleavage site was established by DNA sequence analysis of the restriction DNA fragment Z7F1. Comparison of this nucleotide sequence with the previously determined nucleotide sequence around the cleavage site of phi X gene A protein in phi X174 RF DNA and G4 RF DNA revealed an identical sequence of only 10 nucleotides. The results suggest that the recognition sequence of the phi X174 gene A protein lies within these 10 nucleotides.     

Cloning and dosage compensation of the 6-phosphogluconate dehydrogenase gene (Pgd+) of Drosophila melanogaster

Using a heterologous rat cDNA probe, we have identified a 14.7 kbp Drosophila melanogaster genomic clone containing the X-linked gene Pgd+, which encodes the enzyme 6-phosphogluconate dehydrogenase (6PGD). We used in situ hybridization to larval polytene chromosomes, a somatic transient expression assay for enzyme activity, and the rescue of the lethal Pgd- phenotype by germline transformation to verify the identity of the gene. A 7.4 kbp fragment including the gene and approximately 1.2 kbp of upstream and 1.8 kbp of downstream sequences was relocated to autosomal ectopic sites by germline transformation; this transduced gene exhibits levels of enhanced activity in males comparable to those of the indigenous gene at its normal X chromosome locus. We conclude that the sequences responsible for dosage compensation of Pgd+ are included in this fragment.     

Developing a programmed restriction endonuclease for highly specific DNA cleavage

Specific cleavage of large DNA molecules at few sites, necessary for the analysis of genomic DNA or for targeting individual genes in complex genomes, requires endonucleases of extremely high specificity. Restriction endonucleases (REase) that recognize DNA sequences of 4-8 bp are not sufficiently specific for this purpose. In principle, the specificity of REases can be extended by fusion to sequence recognition modules, e.g. specific DNA-binding domains or triple-helix forming oligonucleotides (TFO). We have chosen to extend the specificity of REases using TFOs, given the combinatorial flexibility this fusion offers in addressing a short, yet precisely recognized restriction site next to a defined triple-helix forming site (TFS). We demonstrate here that the single chain variant of PvuII (scPvuII) covalently coupled via the bifunctional cross-linker N-(gamma-maleimidobutryloxy) succinimide ester to a TFO (5'-NH2-[CH2](6 or 12)-MPMPMPMPMPPPPPPT-3', with M being 5-methyl-2'-deoxycytidine and P being 5-[1-propynyl]-2'-deoxyuridine), cleaves DNA specifically at the recognition site of PvuII (CAGCTG) if located in a distance of approximately one helical turn to a TFS (underlined) complementary to the TFO ('addressed' site: 5'-TTTTTTTCTCTCTCTCN(approximately 10)CAGCTG-3'), leaving 'unaddressed' PvuII sites intact. The preference for cleavage of an 'addressed' compared to an 'unaddressed' site is >1000-fold, if the cleavage reaction is initiated by addition of Mg2+ ions after preincubation of scPvuII-TFO and substrate in the absence of Mg2+ ions to allow triple-helix formation before DNA cleavage. Single base pair substitutions in the TFS prevent addressed DNA cleavage by scPvuII-TFO.     

A novel zinc-finger nuclease platform with a sequence-specific cleavage module

Zinc-finger nucleases (ZFNs) typically consist of three to four zinc fingers (ZFs) and the non-specific DNA-cleavage domain of the restriction endonuclease FokI. In this configuration, the ZFs constitute the binding module and the FokI domain the cleavage module. Whereas new binding modules, e.g. TALE sequences, have been considered as alternatives to ZFs, no efforts have been undertaken so far to replace the catalytic domain of FokI as the cleavage module in ZFNs. Here, we have fused a three ZF array to the restriction endonuclease PvuII to generate an alternative ZFN. While PvuII adds an extra element of specificity when combined with ZFs, ZF-PvuII constructs must be designed such that only PvuII sites with adjacent ZF-binding sites are cleaved. To achieve this, we introduced amino acid substitutions into PvuII that alter K(m) and k(cat) and increase fidelity. The optimized ZF-PvuII fusion constructs cleave DNA at addressed sites with a >1000-fold preference over unaddressed PvuII sites in vitro as well as in cellula. In contrast to the 'analogous' ZF-FokI nucleases, neither excess of enzyme over substrate nor prolonged incubation times induced unaddressed cleavage in vitro. These results present the ZF-PvuII platform as a valid alternative to conventional ZFNs.     

Molecular cloning of an ice nucleation gene from Erwinia ananas and its expression in Escherichia coli

Abstract An approximately 7 kbp genomic DNA fragment was cloned from an ice nucleation-active (ina) strain of Erwinia ananas and defined as to its restriction enzyme site. When the DNA fragment was introduced into E. coli MM294, a potent ice nucleation activity was expressed. Both 0.7 kbp truncation from the 5'-end and 1.7 kbp truncation from the 3'-end were also effective in expressing the ice nucleation activity in E. coli . Therefore, the resulting DNA fragment of approximately 5 kbp was considered to be an ina gene and named ina A. It existed as a unique gene in this strain of E. ananas . No corresponding ina gene existed in an ice nucleation-inactive strain of E. milletiae .     

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.     

Nucleotide sequence of the herpes simplex virus type 2 (HSV-2) thymidine kinase gene and predicted amino acid sequence of thymidine kinase polypeptide and its comparison with the HSV-1 thymidine kinase gene

To analyze the boundaries of the functional coding region of the HSV-2(333) thymidine kinase gene (TK gene), deletion mutants of hybrid plasmid pMAR401 H2G, which contains the 17.5 kbp BglII-G fragment of HSV-2 DNA, were prepared and tested for capacity to transform LM(TK-) cells to the thymidine kinase-positive phenotype. These studies showed that hybrid plasmids containing 2.2-2.4 kbp subfragments of HSV-2 BglII-G DNA transformed LM(TK-) cells to the thymidine kinase-positive phenotype and suggested that the region critical for transformation might be less than 2 kbp. That the activity expressed in the transformants was HSV-2 thymidine kinase was shown by experiments with type-specific enzyme-inhibiting rabbit antisera and by disc-polyacrylamide gel electrophoresis analyses. DNA fragments of the HSV-2 TK gene were subcloned in phage M13mp9 and M13mp8. A sequence of 1656 bp containing the entire coding region of the TK gene and the flanking sequences was determined by the dideoxynucleotide chain termination method. Comparisons with the HSV-1(Cl 101) TK gene revealed that PstI, PvuII, and EcoRI cleavage sites had homologous locations as did promoter, translational start and stop, and polyadenylation signals. Extensive homology was observed in the nucleotide sequence preceding the ATG translational start signal and in portions of the coding region of the genes. Comparisons of the predicted amino acid sequences of the HSV-1 and HSV-2 thymidine kinase polypeptides revealed that both were enriched in alanine, arginine, glycine, leucine, and proline residues and that clear, but interrupted homology existed within several regions of the polypeptide chains. Stretches of 15-30 amino acid residues were identical in conserved regions. The possibility is suggested that domains containing some of the conserved amino acid sequences might have a role in substrate binding and as major antigenic determinants.     

Stability of the "two active X" phenotype in triploid somatic cells.

We examined triploid cells of XXY karyotype heterozygous for glucose 6 phosphate dehydrogenase (G6PD) electrophoretic variants with regard to the stability of their X chromosome phenotype. Clonal populations of cells derived from these human fibroblasts maintained a precise 1:2:1 ratio of A:heteropolymer:B isozymes throughout their life span, indicating stability of the two active X chromosomes in these cells. To determine the influence of the autosomal complement on X chromosome expression, we attempted to perturb the relationship. Fusion of these triploid cells with human diploid fibroblasts carrying a novel G6PD variant (B') resulted in heterokaryons exprssing a novel heteropolymer, presumably indicating that all three parental X chromosomes were active. However, no derepression of the inactive X chromosome was observed. Analysis of interspecific hybrids derived from triploid cells and mouse fibroblasts confirmed that activity of parental X chromosomes is maintained. Some human mouse hybrid clones, however, expressed only a single human G6PD isozyme, probably attributable to segregation of the pertinent X chromosome, but elimination of a relevant autosome cannot be excluded. The triploid cells transformed by SV40 showed alterations in LDH pattern and an approximately 10-20% decrease in chromosome number, but maintained the precise G6PD phenotype of the untransformed cell. These studies provide evidence for the stability of the X chromosome phenotype in triploid cells.     

High level expression of porcine growth hormone in Escherichia coli from an expression vector containing bacteriophage lambda PL and N gene untranslated region

An Escherichia coli expression vector, pG408N containing a PL promoter and the upstream untranslated region of the N gene of bacteriophage lambda has been constructed. We have designed a PvuII site immediately behind the untranslated region. A DNA fragment starting with an initiation codon ATG could be inserted into this site for expression. This vector also contains 7 additional cloning sites downstream from the PvuII site. A gene could be cloned into one of these sites and the 5' sequence of this gene could be modified with synthetic oligonucleotides and ligated to the PvuII for the purpose of increasing gene expression. We have also cloned the lambda cl gene into a p15A plasmid. Cotransformation of this plasmid with the expression vector allows the cloning vector pG408N to be used in any E. coli strain. Using this system, we were able to express porcine growth hormone to approximately 35% of total proteins in E. coli DH5 alpha.     

The factor IX BamHI polymorphism: T-to-G transversion at the nucleotide sequence-561

Summary The polymerase chain reaction (PCR) method was used to amplify a 356-bp DNA segment containing the suspected BamHI polymorphic site of the factor IX gene. Following the enzyme digestions and gel electrophoresis, polymorphic genotypes (-,+ and +/- types) were observed. The gene frequencies for the rare (+) allele are about 36% in blacks and 2% in Caucasians. The 356-bp DNA was further purified and sequenced. The sequencing gels revealed a single nucleotide substitution (T to G) at position-561 of the gene in blacks and Causians. The T-to-G transversion generated a new BamHI site (GGATCC,+type) from a nonenzymatic site, (TGATCC,-type).     

An extensive search for RFLP in the human glucose-6-phosphate dehydrogenase locus has revealed a silent mutation in the coding sequence.

The genetic polymorphism of an approximately 100-kb DNA region comprising and flanking the glucose-6-phosphate dehydrogenase (G6PD) gene on human chromosome Xq28 has been analyzed in detail. By using 14 unique sequence probes and 18 restriction enzymes, we have characterized 257 restriction fragments or 370 restriction sites. On testing 12-57 individual X chromosomes, all sites but one were nonpolymorphic. However, a PstI site that maps to exon 10 of the G6PD gene, which is still monomorphic in all British and Italian subjects tested, is polymorphic in west-African people. Specifically, it is absent from 22% of Nigerian X chromosomes. By sequence analysis we have shown that the absence of this PstI site results from a G----A replacement at position 1116, corresponding to the third base of a glutamine codon; no amino acid change is produced in the protein. Thus, a polymorphic silent mutation is demonstrated in a human gene.     

A PvuII restriction fragment length polymorphism of the glucose-6-phosphate dehydrogenase gene is an African-specific marker

Summary The site of a PvuII restriction fragment length polymorphism (RFLP) of the human glucose-6-phosphate dehydrogenase (G6PD) gene has been located in intron V, 60 bp upstream of G6PD exon VI. A population survey shows this RFLP to be specific for African populations, with frequencies of the rarer allele (PvuII type 2 site present) of 0.32–0.40 in Kenyans, Nigerians, Zambians, and West Indians. This allele has not been found in the European, Asian and Middle Eastern populations studied. Such population-specific markers may be useful in the study of population affinities and may provide insight into prehistoric migrations of peoples.