Resistance of herpes simplex virus to 9-[[2-hydroxy-1-(hydroxymethyl)ethoxy]methyl]guanine: physical mapping of drug synergism within the viral DNA polymerase locus.

A herpes simplex virus type 2 (HSV-2) mutant TS6 (strain HG52) induces a heat-labile viral DNA polymerase at the nonpermissive temperature and is markedly resistant to 9-[[2-hydroxy-1-(hydroxymethyl)ethoxy]methyl]-guanine [2'-nor-2'-deoxyguanosine; 2'NDG]. This antiviral drug requires HSV thymidine kinase for phosphorylation to an active inhibitor (2'NDG-triphosphate), and thymidine kinase-deficient mutants of HSV exhibit varying degrees of resistance to 2'NDG, with the HSV type 1 (HSV-1) B2006 mutant (Kit) being markedly resistant. The ts6 mutation and the 2'ndgR-1 mutation within the viral DNA polymerase locus have been physically mapped by marker rescue and generation of HSV-1/HSV-2 intertypic recombinants. The physical map limits for the ts6 mutation and 2'ndgR-1 mutation are closely linked within a 2.2-kilobase-pair region of DNA sequences and are physically separate from the paaR-1 and acvR-1 mutations. Resistance to 2'NDG by HSV-2 ts6 can be overcome in the presence of combinations of 2'NDG and phosphonoacetic acid, indicating drug synergism within the viral DNA polymerase locus. These physical mapping studies expand the limits of DNA sequences defining an active center in the viral polymerase to 3.5 kilobase pairs, indicating that regions spanning the entire polymerase polypeptide may contribute to a specialized surface able to interact with nucleotides of different structure.     

T5 DNA polymerase: structural--functional relationships to other DNA polymerases.

T5 DNA polymerase, a highly processive single-polypeptide enzyme, has been analyzed for its primary structural features. The amino acid sequence of T5 DNA polymerase has a high degree of homology with that of DNA polymerase I from Escherichia coli and retains many of the amino acid residues that have been implicated in the 3'----5' exonuclease and DNA polymerase activities of that enzyme. Alignment with sequences of polymerase I and T7 DNA polymerase was used to identify regions possibly involved in the high processivity of this enzyme. Further, amino acid sequence comparisons of T5 DNA polymerase with a large group of DNA polymerases previously shown to exhibit little similarity to polymerase I indicate certain sequence segments are shared among distantly related DNA polymerases. These shared regions have been implicated in the 3'----5' exonuclease function of polymerase I, which suggests that the proofreading domains of all these enzymes may be evolutionarily related.     

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.     

The enzymological basis for resistance of herpesvirus DNA polymerase mutants to acyclovir: Relationship to the structure of α-like DNA polymerases

Acyclovir (ACV), like many antiviral drugs, is a nucleoside analog. In vitro, ACV triphosphate inhibits herpesvirus DNA polymerase by means of binding, incorporation into primer/template, and dead-end complex formation in the presence of the next deoxynucleoside triphosphate. However, it is not known whether this mechanism operates in vivo. To address this and other questions, we analyzed eight mutant polymerases encoded by drug-resistant viruses, each altered in a region conserved among α-like DNA polymerases. We measured K_m and k_cat values for dGTP and ACV triphosphate incorporation and K_i values of ACV triphosphate for dGTP incorporation for each mutant. Certain mutants showed increased K_m values for ACV triphosphate incorporation, suggesting a defect in inhibitor binding. Other mutants showed reduced k_cat values for ACV triphosphate incorporation, suggesting a defect in incorporation of inhibitor into DNA, while the rest of the mutants exhibited both altered k_m and k_cat values. In most cases, the fold increase in K_i of ACV triphosphate for dGTP incorporation relative to wild-type polymerase was similar to fold resistance conferred by the mutation in vivo; however, one mutation conferred a much greater increase in resistance than in K_i. The effects of mutations on enzyme kinetics could be explained by using a model of an α-like DNA polymerase active site bound to primer/template and inhibitor. The results have implications for mechanisms of action and resistance of antiviral nucleoside analogs in vivo, in particular for the importance of incorporation into DNA and for the functional roles of conserved regions of polymerases.     

Directed evolution of novel polymerase activities: mutation of a DNA polymerase into an efficient RNA polymerase

The creation of novel enzymatic function is of great interest, but remains a challenge because of the large sequence space of proteins. We have developed an activity-based selection method to evolve DNA polymerases with RNA polymerase activity. The Stoffel fragment (SF) of Thermus aquaticus DNA polymerase I is displayed on a filamentous phage by fusing it to a pIII coat protein, and the substrate DNA template/primer duplexes are attached to other adjacent pIII coat proteins. Phage particles displaying SF polymerases, which are able to extend the attached oligonucleotide primer by incorporating ribonucleoside triphosphates and biotinylated UTP, are immobilized to streptavidin-coated magnetic beads and subsequently recovered. After four rounds of screening an SF library, three SF mutants were isolated and shown to incorporate ribonucleoside triphosphates virtually as efficiently as the wild-type enzyme incorporates dNTP substrates.     

A single residue in DNA polymerases of the Escherichia coli DNA polymerase I family is critical for distinguishing between deoxy- and dideoxyribonucleotides.

Bacteriophage T7 DNA polymerase efficiently incorporates a chain-terminating dideoxynucleotide into DNA, in contrast to the DNA polymerases from Escherichia coli and Thermus aquaticus. The molecular basis for this difference has been determined by constructing active site hybrids of these polymerases. A single hydroxyl group on the polypeptide chain is critical for selectivity. Replacing tyrosine-526 of T7 DNA polymerase with phenylalanine increases discrimination against the four dideoxynucleotides by > 2000-fold, while replacing the phenylalanine at the homologous position in E. coli DNA polymerase I (position 762) or T. aquaticus DNA polymerase (position 667) with tyrosine decreases discrimination against the four dideoxynucleotides 250- to 8000-fold. These mutations allow the engineering of new DNA polymerases with enhanced properties for use in DNA sequence analysis.     

Reduced in vivo mutagenesis by mutant herpes simplex DNA polymerase involves improved nucleotide selection.

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.     

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.     

Homology between DNA polymerases of poxviruses, herpesviruses, and adenoviruses: nucleotide sequence of the vaccinia virus DNA polymerase gene.

A 5400-base-pair segment of the vaccinia virus genome was sequenced and an open reading frame of 938 codons was found precisely where the DNA polymerase had been mapped by transfer of a phosphonoacetate-resistance marker. A single nucleotide substitution changing glycine at position 347 to aspartic acid accounts for the drug resistance of the mutant vaccinia virus. The 5' end of the DNA polymerase mRNA was located 80 base pairs before the methionine codon initiating the open reading frame. Correspondence between the predicted Mr 108,577 polypeptide and the 110,000 purified enzyme indicates that little or no proteolytic processing occurs. Extensive homology, extending over 435 amino acids, was found upon comparing the DNA polymerase of vaccinia virus and DNA polymerase of Epstein-Barr virus. A highly conserved sequence of 14 amino acids in the carboxyl-terminal regions of the above DNA polymerases is also present at a similar location in adenovirus DNA polymerase. This structure, which is predicted to form a turn flanked by beta-pleated sheets, may form part of an essential binding or catalytic site that accounts for its presence in DNA polymerases of poxviruses, herpesviruses, and adenoviruses.     

Processive DNA synthesis observed in a polymerase crystal suggests a mechanism for the prevention of frameshift mutations

DNA polymerases replicate DNA by adding nucleotides to a growing primer strand while avoiding frameshift and point mutations. Here we present a series of up to six successive replication events that were obtained by extension of a primed template directly in a crystal of the thermostable Bacillus DNA polymerase I. The 6-bp extension involves a 20-A translocation of the DNA duplex, representing the largest molecular movement observed in a protein crystal. In addition, we obtained the structure of a "closed" conformation of the enzyme with a bound triphosphate juxtaposed to a template and a dideoxy-terminated primer by constructing a point mutant that destroys a crystal lattice contact stabilizing the wild-type polymerase in an "open" conformation. Together, these observations allow many of the steps involved in DNA replication to be observed in the same enzyme at near atomic detail. The successive replication events observed directly by catalysis in the crystal confirm the general reaction sequence deduced from observations obtained by using several other polymerases and further refine critical aspects of the known reaction mechanism, and also allow us to propose new features that concern the regulated transfer of the template strand between a preinsertion site and an insertion site. We propose that such regulated transfer is an important element in the prevention of frameshift mutations in high-fidelity DNA polymerases. The ability to observe processive, high-fidelity replication directly in a crystal establishes this polymerase as a powerful model system for mechanistic studies in which the structural consequences of mismatches and DNA adducts are observed.     

Nucleotide sequence of the primary origin of bacteriophage T7 DNA replication: relationship to adjacent genes and regulatory elements.

The 682-base-pair nucleotide sequence between positions 14.45 and 16.15 on the bacteriophage T7 DNA molecule has been determined. We can identify not only the sequence of the primary origin of DNA replication but also the termination of gene 1, all of genes 1.1 and 1.2, the start of gene 1.3, and a number of regulatory sequences. The endpoints of four deletion mutations that extend into this region have been determined. These mutations are inferred to have arisen by recombination between short homologous sequences, three of which ar T7 RNA polymerase promoters. The base changes of four point mutations in gene 1.2 have been identified. The sequence essential for initiation at the primary origin is located between the left endpoints of the two deletions D2 and D303. Sequence analysis of these mutants assigns the primary origin to a 129-base-pair segment between positions 14.73 and 15.05. This intergenic segment is A+T-rich (75%) and contains a single T7 gene 4 protein recognition site; it is preceded by two tandem T7 RNA polymerase promoters. A model for initiation of T7 DNA replication is presented.     

Computational study of protein specificity: The molecular basis of HIV-1 protease drug resistance

Drug resistance has sharply limited the effectiveness of HIV-1 protease inhibitors in AIDS therapy. It is critically important to understand the basis of this resistance for designing new drugs. We have evaluated the free energy contribution of each residue in the HIV protease in binding to one of its substrates and to the five FDA-approved protease drugs. Analysis of these free energy profiles and the variability at each sequence position suggests: (i) single drug resistance mutations are likely to occur at not well conserved residues if they interact more favorably with drugs than with the substrate; and (ii) resistance-evading drugs should have a free energy profile similar to the substrate and interact most favorably with well conserved residues. We also propose an empirical parameter, called the free energy/variability value, which combines free energy calculation and sequence analysis to suggest possible drug resistance mutations on the protease. The free energy/variability value is defined as the product of one residue's contribution to the binding free energy and the variability of that residue. This parameter can assist in designing resistance-evading drugs for any target.     

Conformational changes induced in herpes simplex virus DNA polymerase upon DNA binding.

Herpesvirus DNA polymerases are prototypes for alpha-like DNA polymerases and important targets for antiherpesvirus drugs. We have investigated changes in the catalytic subunit of herpes simplex virus DNA polymerase following DNA binding by using the techniques of endogeneous fluorescence quenching and limited proteolysis. The fluorescence studies revealed a reduction in the rate of quenching by acrylamide in the presence of DNA without changes in the wavelength of the emission peak or in the lifetime of the fluorophore, consistent with the possibility of conformational changes. Strikingly, the proteolysis studies revealed that binding to a variety of natural and synthetic DNA and RNA molecules induced the appearance of a new cleavage site for trypsin near residue 1060 of the protein and increased cleavage by trypsin near the center of the protein. The extent of these cleavages correlated with the affinity of the polymerase for these ligands. These data provide strong evidence that binding to nucleic acid polymers induces substantial localized conformational changes in the polymerase. The locations of enhanced tryptic cleavage near sites implicated in substrate recognition and interaction with a processivity factor suggest that the conformational changes are important for catalysis and processivity of this prototype alpha-like DNA polymerase. Inhibition of these changes may provide a mechanism for antiherpesvirus drugs.     

Multigene families for anthracycline antibiotic production in Streptomyces peucetius.

Hybridization of polyketide synthase genes from heterologous Streptomyces sp. led to the identification of four unlinked regions of DNA from Streptomyces peucetius that contain genes that encode the production of the same or closely related metabolites, some of which are intermediates of the daunorubicin pathway. DNA fragments from each region that hybridized with the heterologous polyketide synthase genes were hybridized with each other, but very little sequence similarity was observed even though at least two of the regions have similar (if not identical) functions in metabolite production. Some regions, however, do have sequence similarity with other anthracycline-producing Streptomyces sp.     

Characterization of the DNA polymerase and thymidine kinase genesof herpes simplex virus isolates from AIDS patients in whom acyclovirand foscarnet therapy sequentially failed.

Herpes simplex virus (HSV) isolates were characterized from 8 AIDS patients in whom acyclovir and foscarnet therapy sequentially failed. The 6 postacyclovir (prefoscarnet) HSV isolates were resistant to acyclovir and susceptible to foscarnet. Of the 9 postfoscarnet isolates, 8 were foscarnet-resistant and acyclovir-susceptible, 1 was resistant to both drugs. Acyclovir- or foscarnet-resistant isolates retained susceptibility to cidofovir. The acyclovir-resistant isolates contained single-base substitutions or frameshift mutations in G or C homopolymer nucleotide repeats of the thymidine kinase gene. In contrast, the foscarnet-resistant strains contained single-base substitutions in conserved (II, III, or VI) or, more rarely, nonconserved (between I and VII) regions of the DNA polymerase (pol) gene. The single isolate exhibiting resistance to acyclovir and foscarnet contained mutations in both genes. In this study of clinical HSV isolates, DNA pol mutations conferring foscarnet resistance were not associated with decreased acyclovir or cidofovir susceptibility.     

New Insights into Human Cytomegalovirus pUL52 Structure

Human cytomegalovirus (HCMV) can cause serious diseases in immunocompromised patients. Current antiviral inhibitors all target the viral DNA polymerase. They have adverse effects, and prolonged treatment can select for drug resistance mutations. Thus, new drugs targeting other stages of replication are an urgent need. The terminase complex (pUL56–pUL89–pUL51) is highly specific, has no counterpart in the human organism, and thus represents a target of choice for new antivirals development. This complex is required for DNA processing and packaging. pUL52 was shown to be essential for the cleavage of concatemeric HCMV DNA and crucial for viral replication, but its functional domains are not yet identified. Polymorphism analysis was performed by sequencing UL52 from 61 HCMV naive strains and from 14 HCMV strains from patients treated with letermovir. Using sequence alignment and homology modeling, we identified conserved regions and potential functional motifs within the pUL52 sequence. Recombinant viruses were generated with specific serine or alanine substitutions in these putative patterns. Within conserved regions, we identified residues essential for viral replication probably involved in CXXC-like or zinc finger motifs. These results suggest that they are essential for pUL52 structure/function. Thus, these patterns represent potential targets for the development of new antivirals.     

RNA-dependent RNA polymerase consensus sequence of the L-A double-stranded RNA virus: definition of essential domains.

The L-A double-stranded RNA virus of Saccharomyces cerevisiae makes a gag-pol fusion protein by a -1 ribosomal frameshift. The pol amino acid sequence includes consensus patterns typical of the RNA-dependent RNA polymerases (EC 2.7.7.48) of (+) strand and double-stranded RNA viruses of animals and plants. We have carried out "alanine-scanning mutagenesis" of the region of L-A including the two most conserved polymerase motifs, SG...T...NT..N (. = any amino acid) and GDD. By constructing and analyzing 46 different mutations in and around the RNA polymerase consensus regions, we have precisely defined the extent of domains and specific residues essential for viral replication. Assuming that this highly conserved region has a common secondary structure among different viruses, we predict a largely beta-sheet structure.     

Interaction of RNA polymerase with forked DNA: evidence for two kinetically significant intermediates on the pathway to the final complex

RNA polymerase forms competitor-resistant complexes with "forked DNA" templates that are double-stranded from the -35 promoter region through the first base pair of the -10 region, with an additional unpaired A at the 3' end of the nontemplate strand. These types of substrates were introduced recently as model templates for the study of DNA-protein interactions occurring in the early stages of the formation of RNA polymerase-promoter open complexes. We have performed kinetic and equilibrium measurements of interactions of wild-type and mutant RNA polymerases bearing substitutions in the sigma(70) initiation factor, with forked DNA of wild-type and mutant sequence. Our observations reveal that formation of a competitor-resistant complex between RNA polymerase and forked DNA, similar to the formation of open complexes at promoters, is a multistep process, and some of the sequentially formed intermediates along the two pathways share common properties. This work establishes, for the forked template, progression through these intermediates in the absence of downstream DNA and validates the use of forked DNA to determine the effects of changes in promoter or RNA polymerase sequence on the process of open complex formation.