Characterization and application to hot start PCR of neutralizing monoclonal antibodies against KOD DNA polymerase. (73/4762)

DNA polymerase from Pyrococcus kodakaraensis KOD1 (KOD DNA polymerase) is one of the most efficient thermostable PCR enzymes exhibiting higher accuracy and elongation velocity than any other commercially available DNA polymerase [M. Takagi et al. (1997) Appl. Environ. Microbiol. 63, 4504-4510]. However, even when KOD DNA polymerase was used for PCR, troubles with nonspecific DNA amplification and primer dimer formation still remain because of undesirable DNA polymerase activity during the first denaturing step of PCR. In order to inhibit this undesirable DNA polymerase activity (hot start PCR), two neutralizing monoclonal antibodies (mAbs), 3G8 and betaG1, to KOD DNA polymerase were obtained. Both of these antibodies belong to subclass IgG(1), k. K(d) values were 7.3 x 10(-8) for 3G8 and 1.1 x 10(-6) for betaG1. Nucleotide sequencing of cDNAs of these monoclonal antibodies revealed their sequences to differ in their CDRs (complementarity determining region). Exonuclease activity measurement and epitope mapping revealed that the epitope for 3G8 is located in conserved regions among alpha-like (family B) DNA polymerases (Region II), and the epitope for betaG1 is located in the 3'-5' exonuclease domain. When hot start PCR with each of these mAbs was performed, the specificity of target gene amplification became much higher than in reactions without monoclonal antibody. Furthermore, this method can easily be applied to long distance PCR (>17.5 kbp).  (+info)

Baculovirus expression reconstitutes Drosophila mitochondrial DNA polymerase. (74/4762)

Drosophila mitochondrial DNA polymerase has been reconstituted and purified from baculovirus-infected insect cells. Baculoviruses encoding full-length and mature forms of the catalytic and accessory subunits were generated and used in single and co-infection studies. Recombinant heterodimeric holoenzyme was reconstituted in both the mitochondria and cytoplasm of Sf9 cells and required the mitochondrial presequences in both subunits. The recombinant holoenzyme contains DNA polymerase and 3'-5' exonuclease that are stimulated substantially by both salt and mitochondrial single-stranded DNA-binding protein. Thus, the recombinant enzyme exhibits biochemical properties indistinguishable from those of the native enzyme from Drosophila embryos. Production of the catalytic subunit alone yielded soluble protein with the chromatographic properties of the heterodimeric holoenzyme. However, the purified catalytic core has a 50-fold lower specific activity. This provides evidence of a critical role for the accessory subunit in the catalytic efficiency of Drosophila mitochondrial DNA polymerase.  (+info)

Sensitive assay for mitochondrial DNA polymerase gamma. (75/4762)

BACKGROUND: The mitochondrial DNA polymerase gamma is the principal polymerase required for mitochondrial DNA replication. Primary or secondary deficiencies in the activity of DNA polymerase gamma may lead to mitochondrial DNA depletion. We describe a sensitive and robust clinical assay for this enzyme. METHODS: The assay was performed on mitochondria isolated from skeletal muscle biopsies. High-molecular weight polynucleotide reaction products were captured on ion-exchange paper, examined qualitatively by autoradiography, and quantified by scintillation counting. RESULTS: Kinetic analysis of DNA polymerase gamma by this method showed a K(m) for dTTP of 1.43 micromol/L and a K(i) for azidothymidine triphosphate of 0.861 micromol/L. The assay was linear from 0.1 to 2 microgram of mitochondrial protein. The detection limit was 30 units (30 fmol dTMP incorporated in 30 min). The linear dynamic range was three orders of magnitude; 30-30 000 units. Imprecision (CV) was 6.4% within day and 12% between days. Application of this assay to a mixed population of 38 patients referred for evaluation of mitochondrial disease revealed a distribution with a range of 0-2506 U/microgram, reflecting extensive biologic variation among patients with neuromuscular disease. CONCLUSION: This assay provides a useful adjunct to current laboratory methods for the evaluation of patients with suspected mitochondrial DNA depletion syndromes.  (+info)

The linker region between the helicase and primase domains of the bacteriophage T7 gene 4 protein is critical for hexamer formation. (76/4762)

The gene 4 protein of bacteriophage T7, a functional hexamer, comprises DNA helicase and primase activities. Both activities depend on the unidirectional movement of the protein along single-stranded DNA in a reaction coupled to the hydrolysis of dTTP. We have characterized dTTPase activity and hexamer formation for the full-length gene 4 protein (gp4) as well as for three carboxyl-terminal fragments starting at residues 219 (gp4-C219), 241 (gp4-C241), and 272 (gp4-C272). The region between residues 242 and 271, residing between the primase and helicase domains, is critical for oligomerization of the gene 4 protein. A functional TPase active site is dependent on oligomerization. During native gel electrophoresis, gp4, gp4-C219, and gp4-C241 migrate as oligomers, whereas gp4-C272 is monomeric. The steady-state k(cat) for dTTPase activity of gp4-C272 increases sharply with protein concentration, indicating that it forms oligomers only at high concentrations. gp4-C219 and gp4-C241 both form a stable complex with gp4, whereas gp4-C272 interacts only weakly with gp4. Measurements of surface plasmon resonance indicate that a monomer of T7 DNA polymerase binds to a dimer of gp4, gp4-C219, or gp4-C241 but to a monomer of gp4-C272. Like the homologous RecA and F(1)-ATPase proteins, the oligomerization domain of the gene 4 protein is adjacent to the amino terminus of the NTP-binding domain.  (+info)

Prevalence and significance of naturally occurring mutations in the surface and polymerase genes of hepatitis B virus. (77/4762)

The prevalence and clinical significance of naturally occurring mutations in the full-length surface and overlapping polymerase genes of hepatitis B virus (HBV) were analyzed in 42 patients with chronic hepatitis. Mutations were observed in 10 patients (24%) in the a determinant region, which is the neutralizing epitope within the major hydrophilic region of the surface gene. A high proportion of these mutations (17/18; 94%) occurred in the first loop, unlike mutations induced by immunization. The presence of serum antibody to hepatitis B surface antigen was significantly associated with these mutations. No other region of the surface gene contained any cluster of mutations. These results suggest that escape mutations commonly contribute to persistency in the natural course of HBV infection. In contrast, mutations affecting the major catalytic domains of the polymerase gene, which could alter susceptibility to antiviral nucleoside analogues, were not detected at all.  (+info)

Sequence and insertion sites of murine melanoma-associated retrovirus. (78/4762)

We previously showed that B16 melanoma cells produce ecotropic melanoma-associated retrovirus (MelARV) which encodes a melanoma-associated antigen recognized by MM2-9B6 monoclonal antibody. The biological significance of MelARV in melanoma formation remains unknown. We found that infection of normal melanocytes with MelARV resulted in malignant transformation. It is likely that MelARV emerged from the defective Emv-2 provirus, a single copy of ecotropic provirus existing in the genome of C57BL/6 mice. In the present study, we cloned and sequenced the full-length MelARV genome and its insertion sites and we completed sequencing of the Emv-2 provirus. Our data show that MelARV has a typical full-length retroviral genome with high homology (98.54%) to Emv-2, indicating a close relationship between both viruses. MelARV probably emerged as a result of recombination between Emv-2 and an endogenous nonecotropic provirus. Some observed differences in the gag and pol regions of MelARV might account for the restoration of productivity and infectivity of a novel retrovirus that somatically emerged during melanoma formation. MelARV does not contain any oncogene and therefore might induce transformation by insertional mutagenesis. We sequenced two insertion sites of MelARV. The first insertion site represents the 3' coding region of the c-maf proto-oncogene at 67.0 centimorgans (cM) on chromosome 8. The c-maf proto-oncogene encodes a basic leucine zipper protein homologous to c-fos and c-jun. Insertion of MelARV in BL6 melanoma cells resulted in the up-regulation of c-maf. It is noteworthy that the Emv-2 provirus is also inserted into a noncoding region at 61.0 cM on the same chromosome 8. The second insertion site is the 3' noncoding region of the DNA polymerase gamma (PolG) gene on chromosome 7. The expression of PolG was not affected by the MelARV insertion. Further investigation of the biological significance of MelARV in melanoma formation is being undertaken.  (+info)

Human and mouse homologs of Escherichia coli DinB (DNA polymerase IV), members of the UmuC/DinB superfamily. (79/4762)

To understand the mechanisms underlying mutagenesis in eukaryotes better, we have cloned mouse and human homologs of the Escherichia coli dinB gene. E. coli dinB encodes DNA polymerase IV and greatly increases spontaneous mutations when overexpressed. The mouse and human DinB1 amino acid sequences share significant identity with E. coli DinB, including distinct motifs implicated in catalysis, suggesting conservation of the polymerase function. These proteins are members of a large superfamily of DNA damage-bypass replication proteins, including the E. coli proteins UmuC and DinB and the Saccharomyces cerevisiae proteins Rev1 and Rad30. In a phylogenetic tree, the mouse and human DinB1 proteins specifically group with E. coli DinB, suggesting a mitochondrial origin for these genes. The human DINB1 gene is localized to chromosome 5q13 and is widely expressed.  (+info)

Resolution of head-on collisions between the transcription machinery and bacteriophage phi29 DNA polymerase is dependent on RNA polymerase translocation. (80/4762)

The outcome of collisions between Bacillus subtilis phage Phi29 DNA polymerase and oppositely oriented transcription complexes has been studied in vitro. We found that the replication fork was unable to go past a transcription ternary complex stalled head-on. However, head-on collisions did not lead to a deadlock. Both DNA and RNA polymerase remained bound to the template and, when the halted transcription complex was allowed to move, the replication machinery resumed normal elongation. These results suggested that a replication fork that encounters an RNA polymerase head-on whose movement is not impeded would bypass the transcription machinery. Our results for head-on collisions between concurrently moving replication and transcription complexes are indeed consistent with the existence of a resolving mechanism. The ability of Phi29 DNA polymerase to resolve head-on collisions with itself during symmetrical replication of Phi29 DNA in vivo is likely to be related to its ability to pass a head-on oriented RNA polymerase.  (+info)