An epitope (HPOL) derived from the so-called thumb region of the herpes simplex virus type 1 DNA polymerase in combination with a monoclonal antibody (MAb 1051c) was tested for protein tagging. Using a conventional expression vector, a DNA cassette encoding the HPOL epitope was fused to the C-terminus of the dihydrofolate reductase (DHFR) gene such that the recombinant DHFR contained both a N-terminal HIS-tag and a C-terminal HPOL tag. Expression of recombinant DHFR in <i>Escherichia coli</i> cells was compared by Western blot analysis using either mouse RGS·HIS antibody or MAb 1051c. Immunostaining revealed that both antibodies reacted specifically with DHFR, but the detection sensitivity achieved with MAb 1051c was about 15-fold greater using a standard staining protocol. An HPOL antibody column was successfully applied for affinity purification of DHFR, demonstrating the usefulness of the HPOL epitope/MAb 1051c system for protein tagging, expression monitoring and purification of HPOL-tagged recombinant proteins.
SUMMARY By comparative sequence analysis of the herpes simplex virus type 1 DNA polymerase gene of strain Angelotti and a phosphonoacetic acid-resistant (PAAr) derivative, the site of the PAAr mutation was identified as a single nucleotide (C → T) conversion within the mapping limits of the known PAAr mutations of strains KOS and 17. The conservative amino acid change at residue 719 from alanine to valine results in a radical change in the properties of the polymerase, rendering the mutant enzyme resistant to PAA and various antiviral compounds. Amino acid homologies as well as secondary structure analysis reveal that the PAAr mutation is contained in a 14 amino acid sequence which is highly conserved, and detected in the central domain of prokaryotic and eukaryotic DNA polymerases.
The exonucleolytic activities associated with herpes simplex virus type‐1 (HSV‐1) DNA polymerase and DNase were compared. The unique properties of these nucleases were assessed by applying biochemical and immunological methods as well as by genetics. In contrast to the viral DNA polymerase, HSV DNase is equipped with a 5′–3′‐exonuclease activity. Under reaction conditions optimal for HSV DNA polymerase, i.e. at high ionic strength, HSV DNase exhibited only limited endonucleolytic activity and degraded double‐stranded DNA in a very processive manner and exclusively in the 5′–3′ direction, producing predominantly mononucleotides. Both viral enzymes displayed significant RNase activity which could be correlated with the endogenous endonucleolytic and 5′–3′‐exonucleolytic activities of the DNase and the polymerase‐associated 3′–5′ exonuclease. The tight linkage of polymerizing and exonucleolytic functions of the viral DNA polymerase was demonstrated by their identical response to (a) thermal inactivation, (b) drug inhibition and (c) neutralization by polyclonal antibodies reacting specifically with the N‐terminal, central and C‐terminal polypeptide domains of HSV‐1 DNA polymerase. From the data presented it can be concluded that the cryptic 3′–5′ exonuclease is the only exonucleolytic activity associated with the viral DNA polymerase.
Polyclonal antibodies responding specifically to the N-terminal, central and C-terminal polypeptide domains of the herpes simplex virus type I (HSV-1) DNA polymerase of strain Angelotti were generated. Each of the five different rabbit antisera reacted specifically with a viral 132 +/- 5-kDa polypeptide as shown by immunoblot analysis. Enzyme binding and inhibition studies revealed that antibodies raised to the central and the C-terminal domains of the protein inhibited the polymerizing activity by 70-90%, respectively, which is well in line with the proposed site of the catalytic center of the enzyme and with the possible involvement of these polypeptide chains in DNA-protein interactions. In agreement with this, antibodies directed towards the N-terminal domain bound to the enzyme without effecting the enzymatic activity. The strong binding but low inhibitory properties of antibodies directed to the polypeptide region between residues 1072 and 1146 confirms previous suggestions that these C-terminal sequences, which share no homology to the Epstein-Barr virus DNA polymerase, are less likely involved in the building of the polymerase catalytic site. Antibodies, raised to the very C terminus of the polymerase (EX3), were successfully used to identify a single 132 +/- 5-kDa polypeptide, which coeluted with the HSV DNA polymerase activity during DEAE-cellulose chromatography, and were further shown to precipitate a major viral polypeptide of identical size. From the presented data it can be concluded that the native enzyme consists of a single polypeptide with a size predicted from the long open reading frame of the HSV-1 DNA polymerase gene.
A simple method to assay the major properties of DNA polymerases such as template binding, polymerase and exonuclease activities in one step is exemplified with the DNA polymerases of E. coli , bacteriophage T4 and herpes simplex virus. Combining the advantages of the band‐shift assay with the resolving power of polyacrylamide gradient gel electrophoresis, the procedure is particularly useful for a rapid functional analysis of mutant polymerases as well as inhibitors of DNA replication.
We present evidence that mutation frequencies in a mammalian system can vary according to the replication fidelity of the DNA polymerase. We demonstrated previously that several derivatives of herpes simplex virus type 1 that encode polymerases resistant to various antiviral drugs (e.g., nucleotide analogues) also produce reduced numbers of spontaneous mutants. Here we show that the DNA polymerase from one antimutator virus exhibits enhanced replication fidelity. First, the antimutator virus showed a reduced response to known mutagens that promote base mispairing during DNA replication (N-methyl-N'-nitro-N-nitrosoguanidine, 5-bromo-deoxyuridine). Second, purified DNA polymerase from the antimutator produced fewer replication errors in vitro, based on incorporation of mispaired nucleotides or analogues with abnormal sugar rings. We have investigated possible mechanisms for the enhanced fidelity of the antimutator polymerase. We show that the mutant enzyme has altered interactions with nucleoside triphosphates, as indicated by its resistance to nucleotide analogues and elevated Km values for normal nucleoside triphosphates. We present evidence against increased proofreading by an associated 3',5' exonuclease (as seen for T4 bacteriophage antimutator polymerases), based on nuclease levels in the mutant polymerase. We propose that reduced affinity of the polymerase for nucleoside triphosphates accounts for the antimutator phenotype by accentuating differences in base-pair stability, thus facilitating selection of correct nucleotides.
