Sequence and mapping analyses of the herpes simplex virus DNA polymerase gene predict a C-terminal substrate binding domain.

The herpes simplex virus DNA polymerase provides an excellent model for studies of eukaryotic replicative polymerases. We report here the nucleotide sequence of the gene which encodes this enzyme. The gene includes a 3705-base-pair major open reading frame capable of encoding a Mr 136,519 polypeptide, in rough agreement with previous estimates of the size of the major polypeptide found in partially purified viral polymerase preparations. The predicted polymerase polypeptide shares extensive sequence homology with the Epstein-Barr virus open frame predicted to encode DNA polymerase and with a 13-amino acid segment of adenovirus 2 DNA polymerase. Mutations conferring altered sensitivity to antiviral deoxynucleoside triphosphate analogs, pyrophosphate analogs, or aphidicolin from eight different mutants map within the region encoding the carboxyl-terminal portion of the predicted polymerase polypeptide. Two of these are separated by a distance corresponding to at least 228 amino acids. We propose that this region of the gene encodes a polypeptide domain that contains the binding sites for deoxynucleoside triphosphates and pyrophosphate.     

DNA polymerase I gene of Saccharomyces cerevisiae: nucleotide sequence, mapping of a temperature-sensitive mutation, and protein homology with other DNA polymerases.

A 5600-base pair segment spanning the coding region of the Saccharomyces cerevisiae DNA polymerase I gene was sequenced and found to contain an open reading frame of 1468 codons, corresponding to a polypeptide of Mr 166,794. A pol1 temperature-sensitive mutation, encoding a DNA-polymerase-primase complex with altered stability, has a single base-pair substitution that changes the glycine at position 493 to a positively charged arginine. Protein sequence comparison with other prokaryotic and eukaryotic DNA polymerases reveals three major regions of homology. This observation suggests that certain DNA polymerases might require the conservation of critical amino acid residues for activity.     

Human DNA sequence homologous to the transforming gene (mos) of Moloney murine sarcoma virus.

We describe the molecular cloning of a 9-kilo-base-pair BamHI fragment from human placental DNA containing a sequence homologous to the transforming gene (v-mos) of Moloney murine sarcoma virus. The DNA sequence of the homologous region of human DNA (termed humos) was resolved and compared to that of the mouse cellular homolog of v-mos (termed mumos) [Van Beveren, C., van Straaten, F., Galleshaw, J.A. & Verma, I.M. (1981) Cell 27, 97-108]. The humos gene contained an open reading frame of 346 codons that was aligned with the equivalent mumos DNA sequence by the introduction of two gaps of 15 and 3 bases into the mumos DNA and a single gap of 9 bases into the humos DNA. The aligned coding sequences were 77% homologous and terminated at equivalent opal codons. The humos open reading frame initiated at an ATG found internally in the mumos coding sequence. The polypeptides predicted from the DNA sequence to be encoded by humos and mumos also were found to be extensively homologous, and 253 of 337 amino acids were shared between the two polypeptides. The first five NH2-terminal and last two COOH-terminal amino acids of the humos gene product were in common with those of mumos. In addition, near the middle of the polypeptide chains, four regions ranging from 19 to 26 consecutive amino acids were conserved. However, we have not been able to transform mouse cells with transfected humos DNA fragments or with hybrid DNA recombinants containing humos and retroviral long terminal repeat (LTR) sequences.     

Homology between RNA polymerases of poxviruses, prokaryotes, and eukaryotes: nucleotide sequence and transcriptional analysis of vaccinia virus genes encoding 147-kDa and 22-kDa subunits

We have determined the nucleotide sequence of a region of the vaccinia virus genome encoding RNA polymerase subunits of 22 and 147 kDa and have mapped the 5' and 3' ends of the two mRNAs. The predicted amino acid sequence of the vaccinia 147-kDa subunit shows extensive homology with the largest subunit of Escherichia coli RNA polymerase, yeast RNA polymerases II and III, and Drosophila RNA polymerase II. The regions of homology between the five RNA polymerases are subdivided into five separate domains that span most of the length of each. A sixth domain shared by the vaccinia and the eukaryotic polymerases is absent from the E. coli sequence. In all specified regions, the vaccinia large subunit has greater homology with eukaryotic RNA polymerases II and III than with the E. coli polymerase. Vaccinia virus and eukaryotic RNA polymerases may therefore have evolved from a common ancestral gene after the latter diverged from prokaryotes.     

DNA polymerase II is encoded by the DNA damage-inducible dinA gene of Escherichia coli.

The structural gene for DNA polymerase II was cloned by using a synthetic inosine-containing oligonucleotide probe corresponding to 11 amino acids, which were determined by sequencing the amino terminus of the purified protein. The labeled oligonucleotide hybridized specifically to the lambda clone 7H9 from the Kohara collection as well as to plasmid pGW511 containing the SOS-regulated dinA gene. Approximately 1400 base pairs of dinA sequence were determined. The predicted amino-terminal sequence of dinA demonstrated that this gene encoded DNA polymerase II. Sequence analysis of the upstream region localized a LexA binding site overlapping the -35 region of the dinA promoter, and this promoter element was found to be only two nucleotides downstream from the 3' end of the araD gene. These results demonstrate that the gene order is thr-dinA (pol II)-ara-leu on the Escherichia coli chromosome and that the DNA polymerase II structural gene is transcribed in the same direction as the araBAD operon. Based on the analysis of the predicted protein, we have identified a sequence motif Asp-Xaa-Xaa-Ser-Leu-Tyr-Pro-Ser in DNA polymerase II that is highly conserved among a diverse group of DNA polymerases, which include those from humans, yeast, Herpes and vaccinia viruses, and phages T4 and PRD1. The demonstration that DNA polymerase II is a component of the SOS response in E. coli suggests that it plays an important role in DNA repair and/or mutagenesis.     

Identification of a poxvirus gene encoding a uracil DNA glycosylase.

An open reading frame, BamHI D6R, from the central highly conserved region of the Shope fibroma virus (SFV) genome was sequenced and found to have significant homology to that of uracil DNA glycosylases from a number of organisms. Uracil DNA glycosylase catalyzes the initial step in the repair pathway that removes potentially mutagenic uracil from duplex DNA. The D6R polypeptide was expressed in reticulocyte lysates programmed with RNA transcribed from an expression vector containing the T7 RNA polymerase promoter. A highly specific ethidium bromide fluorescence assay of the in vitro translation product determined that the encoded protein does indeed possess uracil DNA glycosylase activity. Open reading frames from other poxviruses, including vaccinia virus (HindIII D4R) and fowlpox (D4), are highly homologous to D6R of SFV and are predicted to encode uracil DNA glycosylases. Identification of the SFV uracil DNA glycosylase provides evidence that this poxviral protein is involved in the repair of the viral DNA genome. Since this enzyme performs only the initial step required for the removal of uracil from DNA, creating an apyrimidinic site, we suggest that other, possibly virus-encoded, repair activities must be present in the cytoplasm of infected cells to complete the uracil excision repair pathway.     

Identification of amino acids in herpes simplex virus DNA polymerase involved in substrate and drug recognition.

Herpes simplex virus (HSV) encodes a DNA polymerase that is similar in several respects to the replicative mammalian DNA polymerase alpha. Recently, these and other DNA polymerases have been shown to share several regions of protein sequence similarity. Despite these similarities, antiviral drugs that mimic natural polymerase substrates specifically inhibit herpesvirus DNA polymerases. To study amino acids involved in substrate and drug recognition, we have characterized and mapped altered drug sensitivity markers of nine HSV pol mutants and sequenced the relevant portions of these mutants. The mutations were found to occur within four relatively small regions. One such region, which we designate region A, has sequence similarity only to DNA polymerases that are sensitive to certain antiviral drugs. The other three regions contain sequences that are similar among various DNA polymerases. The multiple mutations occurring within two of these regions make it likely that the regions interact directly with drugs and substrates. Our results lead us to favor a model in which protein folding allows interactions among the four regions to form the substrate and drug binding sites.     

Bacterial-type DNA holliday junction resolvases in eukaryotic viruses

Homologous DNA recombination promotes genetic diversity and the maintenance of genome integrity, yet no enzymes with specificity for the Holliday junction (HJ)-a key DNA recombination intermediate-have been purified and characterized from metazoa or their viruses. Here we identify critical structural elements of RuvC, a bacterial HJ resolvase, in uncharacterized open reading frames from poxviruses and an iridovirus. The putative vaccinia virus resolvase was expressed as a recombinant protein, affinity purified, and shown to specifically bind and cleave a synthetic HJ to yield nicked duplex molecules. Mutation of either of two conserved acidic amino acids abrogated the catalytic activity of the A22R protein without affecting HJ binding. The presence of bacterial-type enzymes in metazoan viruses raises evolutionary questions.     

Glutaredoxin homolog encoded by vaccinia virus is a virion-associated enzyme with thioltransferase and dehydroascorbate reductase activities.

Glutaredoxins (GRXs), also known as thioltransferases, use glutathione as a cofactor for reduction of disulfides in prokaryotes and eukaryotes. We demonstrate that the vaccinia virus O2L open reading frame encodes a functional GRX, as predicted by Johnson et al. [Johnson, G. P., Goebel, S. J., Perkus, M. E., Davis, S. W., Winslow, J. P. & Paoletti, E. (1991) Virology 181, 378-381] from sequence homology. The 12-kDa protein product of the O2L open reading frame was synthesized after viral DNA replication, coincident with a major increase in cytoplasmic glutathione-dependent thioltransferase activity. The protein was associated with purified vaccinia virions and was not released by treatment with a nonionic detergent unless dithiothreitol was added. The virion-derived protein, as well as a recombinant form expressed in Escherichia coli, exhibited thioltransferase and dehydroascorbate reductase activities indicative of a functional GRX. The postreplicative synthesis of vaccinia virus GRX and its association with virions suggest that the enzyme may have novel roles in the virus growth cycle.     

Retroviral protease-like gene in the vaccinia virus genome.

The retroviral protease-encoding region, PR, situated between the gag and pol genes, underwent gene duplication in the lineage now represented by simian retrovirus type 1; the sequence of the duplicated segment has diverged considerably from the present PR sequence [Power, M.D., Marx, P.A., Bryant, M.L., Gardner, M.B., Barr, P.J. & Luciw, P.A. (1986) Science 231, 1567-1572]. The PR-like duplicated gene segment was at some point translocated to a new site within the pol gene of a lentivirus (subsequent to the divergence of human immunodeficiency virus type 1), where it has been maintained. We have identified in the vaccinia virus genome a sequence that is homologous to the PR-like duplicated gene segment of both types of retrovirus in an open reading frame whose product is predicted to be a 16.2-kDa protein. The vaccinia PR-like gene is located in the HindIII F fragment, and its product displays 31-34% amino acid identity to the two types of retroviral duplicated protease sequences over a region encompassing 125 amino acid residues. Sequences flanking the vaccinia gene showed no significant homology at either the DNA or amino acid level to the retroviruses. Nuclease S1 and primer extension analyses determined that the vaccinia gene is transcribed early in infection.     

Intervening sequences in an Archaea DNA polymerase gene.

The DNA polymerase gene from the Archaea Thermococcus litoralis has been cloned and expressed in Escherichia coli. It is split by two intervening sequences (IVSs) that form one continuous open reading frame with the three polymerase exons. To our knowledge, neither IVS is similar to previously described introns. However, the deduced amino acid sequences of both IVSs are similar to open reading frames present in mobile group I introns. The second IVS (IVS2) encodes an endonuclease, I-Tli I, that cleaves at the exon 2-exon 3 junction after IVS2 has been deleted. IVS2 self-splices in E. coli to yield active polymerase, but processing is abolished if the IVS2 reading frame is disrupted. Silent changes in the DNA sequence at the exon 2-IVS2 junction that maintain the original protein sequence do not inhibit splicing. These data suggest that protein rather than mRNA splicing may be responsible for production of the mature polymerase.     

Spontaneous changes in nucleotide sequence in proviruses of spleen necrosis virus, an avian retrovirus.

We determined the nucleotide sequence of about 1 kilobase of DNA 3' to the 5' long terminal repeat of three noninfectious ad one infectious proviral DNA clones of spleen necrosis virus, an avian retrovirus, to determine if the types of nucleic acid changes involved in retrovirus mutation shed light on special features of retrovirus replication. An open reading frame was found starting 411 base pairs from the end of the long terminal repeat. It contained sequences coding for the 36 amino acids at the amino terminus of the p30 of a related reticuloendotheliosis virus [Oroszlan, S., Barbacid, M., Copeland T., Aaronson, S. A. & Gilden, R. V. (1981) J. Virol. 39, 845-854]. Therefore, the open reading frame represents the 5' end of the gag gene. A mutation in one noninfectious provirus changed the initiation codon for the gag polypeptide; a mutation in another noninfectious provirus caused premature termination of gag polypeptide synthesis; and a nontandem duplication into gag resulting from a mistake in initial (+) strand DNA synthesis changed amino acids and the reading frame in a third noninfectious provirus. These mutations appear to be responsible for the lack of infectivity of these provirus clones and indicate a higher relative frequency of mutation in this region of the genome. In addition, all four clones have multiple other mutations. These mutations are mostly base pair substitutions and many are clustered for any one clone, reflecting certain special features of retrovirus replication.     

Identification of a vaccinia virus gene encoding a type I DNA topoisomerase.

Vaccinia virus encapsidates a type I DNA topoisomerase (EC 5.99.1.2). The enzyme was purified from virus cores to apparent homogeneity, yielding a protein of Mr 32,000. The amino-terminal sequence of the isolated Mr 32,000 polypeptide was determined and used to map the putative structural gene for the vaccinia topoisomerase to the H7r open reading frame of the vaccinia genome. This gene encodes a 314-amino acid polypeptide containing a region homologous to a region of the type I topoisomerase from the yeast Saccharomyces cerevisiae.     

DNA polymerase active site is highly mutable: evolutionary consequences

DNA polymerases contain active sites that are structurally superimposable and highly conserved in sequence. To assess the significance of this preservation and to determine the mutational burden that active sites can tolerate, we randomly mutated a stretch of 13 amino acids within the polymerase catalytic site (motif A) of Thermus aquaticus DNA polymerase I. After selection, by using genetic complementation, we obtained a library of approximately 8, 000 active mutant DNA polymerases, of which 350 were sequenced and analyzed. This is the largest collection of physiologically active polymerase mutants. We find that all residues of motif A, except one (Asp-610), are mutable while preserving wild-type activity. A wide variety of amino acid substitutions were obtained at sites that are evolutionarily maintained, and conservative substitutions predominate at regions that stabilize tertiary structures. Several mutants exhibit unique properties, including DNA polymerase activity higher than the wild-type enzyme or the ability to incorporate ribonucleotide analogs. Bacteria dependent on these mutated polymerases for survival are fit to replicate repetitively. The high mutability of the polymerase active site in vivo and the ability to evolve altered enzymes may be required for survival in environments that demand increased mutagenesis. The inherent substitutability of the polymerase active site must be addressed relative to the constancy of nucleotide sequence found in nature.     

Identification of C-terminal amino acid residues of cauliflower mosaic virus open reading frame III protein responsible for its DNA binding activity.

We cloned in Escherichia coli truncated versions of the protein p15 encoded by open reading frame III of cauliflower mosaic virus. We then compared the ability of the wild-type p15 (129 amino acids) and the deleted p15 to bind viral double-stranded DNA genome. Deletions of > 11 amino acids in the C-terminal proline-rich region resulted in loss of DNA binding activity of wild-type p15. Moreover, a point mutation of the proline at position 118 sharply reduced the interaction between the viral protein and DNA. These results suggest that cauliflower mosaic virus p15 belongs to the family of DNA binding proteins having a proline-rich motif involved in interaction with double-stranded DNA.     

Bovine galactosyltransferase: identification of a clone by direct immunological screening of a cDNA expression library.

A 1.3-kilobase cDNA clone (7A) coding for bovine galactosyltransferase (glycoprotein 4-beta-galactosyltransferase, EC 2.4.1.38) was isolated from a lambda gt11 expression library by immunological screening with monospecific polyclonal antisera to the affinity-purified bovine enzyme. The nucleotide sequence of this clone predicts an open reading frame that starts at the 5' end of the insert and codes for a polypeptide of 334 amino acids with Mr 37,645. Based on a Mr of 57,000 for the membrane-bound enzyme this clone accounts for approximately 61% of the coding sequence. Portions of the predicted amino acid sequence matched the six tryptic peptides isolated from affinity-purified bovine galactosyltransferase. Clone 7A hybridizes to a 4.8-kilobase bovine mRNA and identifies multiple EcoRI restriction fragments in bovine, murine, and human DNA.