Genetic mapping of the amino-terminal domain of bacteriophage T4 DNA polymerase

The conserved RNP motif of the herpes simplex virus 1 family B DNA polymerase is crucial for viral DNA synthesis but not polymerase activity

The herpes simplex virus 1 DNA polymerase contains a highly conserved structural motif found in most family B polymerases and certain RNA-binding proteins. To investigate its importance within cells, we constructed a mutant virus with substitutions in two residues of the motif and a rescued derivative. The substitutions resulted in severe impairment of plaque formation, yields of infectious virus, and viral DNA synthesis while not meaningfully affecting expression of the mutant enzyme, its co-localization with the viral single-stranded DNA binding protein at intranuclear punctate sites in non-complementing cells or in replication compartments in complementing cells, or viral DNA polymerase activity. Taken together, our results indicate that the RNA binding motif plays a crucial role in herpes simplex virus 1 DNA synthesis through a mechanism separate from effects on polymerase activity, thus identifying a distinct essential function of this motif with implications for hypotheses regarding its biochemical functions.

Structural insights into eukaryotic DNA replication

Three DNA polymerases of the B family function at the replication fork in eukaryotic cells: DNA polymerases α, δ, and ε. DNA polymerase α, an heterotetramer composed of two primase subunits and two polymerase subunits, initiates replication. DNA polymerases δ and ε elongate the primers generated by pol α. The DNA polymerase from bacteriophage RB69 has served as a model for eukaryotic B family polymerases for some time. The recent crystal structures of pol δ, α, and ε revealed similarities but also a number of unexpected differences between the eukaryotic polymerases and their bacteriophage counterpart, and also among the three yeast polymerases. This review will focus on their shared structural elements as well as the features that are unique to each of these polymerases.

Utility of the bacteriophage RB69 polymerase gp43 as a surrogate enzyme for herpesvirus orthologs

Viral polymerases are important targets in drug discovery and development efforts. Most antiviral compounds that are currently approved for treatment of infection with members of the herpesviridae family were shown to inhibit the viral DNA polymerase. However, biochemical studies that shed light on mechanisms of drug action and resistance are hampered primarily due to technical problems associated with enzyme expression and purification. In contrast, the orthologous bacteriophage RB69 polymerase gp43 has been crystallized in various forms and therefore serves as a model system that provides a better understanding of structure–function relationships of polymerases that belong the type B family. This review aims to discuss strengths, limitations, and opportunities of the phage surrogate with emphasis placed on its utility in the discovery and development of anti-herpetic drugs.

Complete genome sequence of the giant virus OBP and comparative genome analysis of the diverse ΦKZ-related phages

The 283,757-bp double-stranded DNA genome of Pseudomonas fluorescens phage OBP shares a general genomic organization with Pseudomonas aeruginosa phage EL. Comparison of this genomic organization, assembled in syntenic genomic blocks interspersed with hyperplastic regions of the ΦKZ-related phages, supports the proposed division in the "EL-like viruses," and the "phiKZ-like viruses" within a larger subfamily. Identification of putative early transcription promoters scattered throughout the hyperplastic regions explains several features of the ΦKZ-related genome organization (existence of genomic islands) and evolution (multi-inversion in hyperplastic regions). When hidden Markov modeling was used, typical conserved core genes could be identified, including the portal protein, the injection needle, and two polypeptides with respective similarity to the 3'-5' exonuclease domain and the polymerase domain of the T4 DNA polymerase. While the N-terminal domains of the tail fiber module and peptidoglycan-degrading proteins are conserved, the observation of C-terminal catalytic domains typical for the different genera supports the further subdivision of the ΦKZ-related phages.

Structure of the replicating complex of a pol alpha family DNA polymerase

We describe the 2.6 A resolution crystal structure of RB69 DNA polymerase with primer-template DNA and dTTP, capturing the step just before primer extension. This ternary complex structure in the human DNA polymerase alpha family shows a 60 degrees rotation of the fingers domain relative to the apo-protein structure, similar to the fingers movement in pol I family polymerases. Minor groove interactions near the primer 3' terminus suggest a common fidelity mechanism for pol I and pol alpha family polymerases. The duplex product DNA orientation differs by 40 degrees between the polymerizing mode and editing mode structures. The role of the thumb in this DNA motion provides a model for editing in the pol alpha family.

Nucleotide-sequence-specific and non-specific interactions of T4 DNA polymerase with its own mRNA

The DNA-binding DNA polymerase (gp43) of phage T4 is also an RNA-binding protein that represses translation of its own mRNA. Previous studies implicated two segments of the untranslated 5'-leader of the mRNA in repressor binding, an RNA hairpin structure and the adjacent RNA to the 3' side, which contains the Shine-Dalgarno sequence. Here, we show by in vitro gp43-RNA binding assays that both translated and untranslated segments of the mRNA contribute to the high affinity of gp43 to its mRNA target (translational operator), but that a Shine-Dalgarno sequence is not required for specificity. Nucleotide sequence specificity appears to reside solely in the operator's hairpin structure, which lies outside the putative ribosome-binding site of the mRNA. In the operator region external to the hairpin, RNA length rather than sequence is the important determinant of the high binding affinity to the protein. Two aspects of the RNA hairpin determine specificity, restricted arrangement of purine relative to pyrimidine residues and an invariant 5'-AC-3' in the unpaired (loop) segment of the RNA structure. We propose a generalized structure for the hairpin that encompasses these features and discuss possible relationships between RNA binding determinants of gp43 and DNA binding by this replication enzyme.

Evolution of RNA-binding specificity in T4 DNA polymerase

DNA polymerase of phage T4 (T4 gp43), an essential component of the T4 DNA replicase, is a multifunctional single-chained (898-amino acid) protein that catalyzes the highly accurate synthesis of DNA in phage replication. The enzyme functions both as a DNA-binding replication protein and as a sequence-specific RNA-binding autogenous translational repressor. We have utilized a phylogenetic approach to study the relationships between the two nucleic acid-binding functions of the protein. We found that autogenous translational control of gp43 biosynthesis has been conserved in phage RB69, a distant relative of T4, although we also found that the RB69 system differs from its T4 counterpart in two regards: (a) nucleotide sequence and predicted secondary structure of the RNA target (translational operator), and (b) RNA specificity of the protein. T4 gp43 is specific to the RNA operator sequence of the T4 genome whereas RB69 gp43 can bind and repress operator RNA from both phages equally well. In studies with T4-RB69 gp43 chimeras, we mapped T4 gp43 RNA-binding specificity to a protein segment that also harbors important determinants for DNA binding and the polymerase catalytic function. Our results suggest that RNA functions as a regulator of both the dosage and activity of this DNA replication enzyme.

Modular organization of T4 DNA polymerase. Evidence from phylogenetics

We describe the use of a phylogenetic approach to analyze the modular organization of the single-chained (898 amino acids) and multifunctional DNA polymerase of phage T4. We have identified, cloned in expression vectors, and sequenced the DNA polymerase gene (gene 43) of phage RB69, a distant relative of T4. The deduced primary structure of the RB69 protein (RB69 gp43) differs from that of T4 gp43 in discrete clusters of short sequence that are interspersed with clusters of high similarity between the two proteins. Despite these differences, the two enzymes can substitute for each other in phage DNA replication, although T4 gp43 does exhibit preference to its own genome. A 55-amino acid internal gp43 segment of high sequence divergence between T4 and RB69 could be replaced in RB69 gp43 with the corresponding segment from T4 without loss of replication function. The reciprocal chimera and a deletion mutant of the T4 gp43 segment were both inactive for replication and specifically inhibitory ("dominant lethal") to the T4 wild-type allele. The results show that phylogenetic markers can be used to construct chimeric and truncated froms of gp43 that, although inactive for replication, can still exhibit biological specificity.

Mutational analysis of the mRNA operator for T4 DNA polymerase

Biosynthesis of bacteriophage T4 DNA polymerase is autogenously regulated at the translational level. The enzyme, product of gene 43, represses its own translation by binding to its mRNA 5' to the initiator AUG at a 36-40 nucleotide segment that includes the Shine-Dalgarno sequence and a putative RNA hairpin structure consisting of a 5-base-pair stem and an 8-base loop. We constructed mutations that either disrupted the stem or altered specific loop residues of the hairpin and found that many of these mutations, including single-base changes in the loop sequence, diminished binding of purified T4 DNA polymerase to its RNA in vitro (as measured by a gel retardation assay) and derepressed synthesis of the enzyme in vivo (as measured in T4 infections and by recombinant-plasmid-mediated expression). In vitro effects, however, were not always congruent with in vivo effects. For example, stem pairing with a sequence other than wild-type resulted in normal protein binding in vitro but derepression of protein synthesis in vivo. Similarly, a C----A change in the loop had a small effect in vitro and a strong effect in vivo. In contrast, an A----U change near the base of the hairpin that was predicted to increase the length of the base-paired stem had small effects both in vitro and in vivo. The results suggest that interaction of T4 DNA polymerase with its structured RNA operator depends on the spatial arrangement of specific nucleotide residues and is subject to modulation in vivo.

Autogenous translational operator recognized by bacteriophage T4 DNA polymerase

The synthesis of the DNA polymerase of bacteriophage T4 is autogenously regulated. This protein (gp43), the product of gene 43, binds to a segment of its mRNA that overlaps its ribosome binding site, and thereby blocks translation. We have determined the Kd of the gp43-operator interaction to be 1.0 x 10(-9) M. The minimum operator sequence to which gp43 binds consists of 36 nucleotides that include a hairpin (containing a 5 base-pair helix and an 8 nucleotide loop) and a single-stranded segment that contains the Shine-Dalgarno sequence of the ribosome binding site. In the distantly related bacteriophage RB69 there is a remarkable conservation of this hairpin and loop sequence at the ribosome binding site of its DNA polymerase gene. We have constructed phage operator mutants that overproduce gp43 in vivo, yet are unchanged for in vivo replication rates and phage yield. We present data that show that the replicative and autoregulatory functions are mutually exclusive activities of this polymerase, and suggest a model for gp43 synthesis that links autoregulation to replicative demand.

Genetic evidence for two protein domains and a potential new activity in bacteriophage T4 DNA polymerase

Intragenic complementation was detected within the bacteriophage T4 DNA polymerase gene. Complementation was observed between specific amino (N)-terminal, temperature-sensitive (ts) mutator mutants and more carboxy (C)-terminal mutants lacking DNA polymerase polymerizing functions. Protein sequences surrounding N-terminal mutation sites are similar to sequences found in Escherichia coli ribonuclease H (RNase H) and in the 5'----3' exonuclease domain of E. coli DNA polymerase I. These observations suggest that T4 DNA polymerase, like E. coli DNA polymerase I, contains a discrete N-terminal domain.

Locations of amino acid substitutions in bacteriophage T4 tsL56 DNA polymerase predict an N-terminal exonuclease domain

The amino acid substitutions responsible for the temperature-sensitive (ts) and mutator phenotypes of the classical bacteriophage T4 DNA polymerase mutant tsL56 were determined. tsL56 DNA polymerase has two mutations in the 5' end of the DNA polymerase gene (g43) that produce two amino acid substitutions: codon 89, alanine to threonine, and codon 363, aspartate to asparagine. Both mutations are required for the strong ts and mutator phenotypes. The increased error rate of the tsL56 DNA polymerase is due to a reduction in 3'----5' exonuclease activity relative to polymerase activity (N. Muzyczka, R. L. Poland, and M. J. Bessman, J. Biol. Chem. 247:7116-7122, 1972). Thus, the locations of the tsL56 mutations suggest that the 3'----5' exonuclease domain resides in the N-terminal region. Several other ts DNA polymerase mutant strains isolated with tsL56 also have mutator or antimutator phenotypes. The nucleotide changes in these important mutant strains were also determined. This mutant collection, combined with collections of g43 amber mutants and mutants selected on the basis of a strong mutator phenotype (L. J. Reha-Krantz, J. Mol. Biol. 202:711-724, 1988), contains nearly 70 different DNA polymerase mutations. The numerous T4 DNA polymerase mutations are valuable for DNA polymerase structure-function and fidelity studies.

DNA polymerase of bacteriophage T4 is an autogenous translational repressor

In bacteriophage T4 the protein product of gene 43 (gp43) is a multifunctional DNA polymerase that is essential for replication of the phage genome. The protein harbors DNA-binding, deoxyribonucleotide-binding, DNA-synthesizing (polymerase) and 3'-exonucleolytic (editing) activities as well as a capacity to interact with several other T4-induced replication enzymes. In addition, the T4 gp43 is a repressor of its own synthesis in vivo. We show here that this protein is an autogenous repressor of translation, and we have localized its RNA-binding sequence (translational operator) to the translation initiation domain of gene 43 mRNA. This mechanism for regulation of T4 DNA polymerase expression underscores the ubiquity of translational repression in the control of T4 DNA replication. Many T4 DNA polymerase accessory proteins and nucleotide biosynthesis enzymes are regulated by the phage-induced translational repressor regA, while the T4 single-stranded DNA-binding protein (T4 gp32) is, like gp43, autogenously regulated at the translational level.

Bacteriophage T4 DNA polymerase determines the amount and specificity of ultraviolet mutagenesis

Ultraviolet mutagenesis in bacteriophage T4 proceeds via error-prone repair (EPR) and requires the functional integrity of the uvsWXY system which mediates genetic recombination, recombinational repair, and mutability by diverse DNA damaging agents. Current opinion holds that mutagens acting through EPR generate DNA damage which blocks the progress of the replication complex and that EPR consists of the facilitated bypass of such inaccurate, damaged templates. This notion predicts that the T4 DNA polymerase (encoded by gene 43) mediates EPR in UV irradiated phage T4. This prediction is verified by the discovery that gene 43 mutations often enhance or reduce UV mutagenesis (which is scored by the induction of r mutants) and sometimes change its specificity.

Amino acid changes coded by bacteriophage T4 DNA polymerase mutator mutants. Relating structure to function

Previous studies on the selection of bacteriophage T4 mutator mutants have been extended and a method to regulate the mutator activity of DNA polymerase mutator strains has been developed. The nucleotide changes of 17 bacteriophage T4 DNA polymerase mutations that confer a mutator phenotype and the nucleotide substitutions of several other T4 DNA polymerase mutations have been determined. The most striking observation is that the distribution of DNA polymerase mutator mutations is not random; almost all mutator mutations are located in the N-terminal half of the DNA polymerase. It has been shown that the T4 DNA polymerase shares several regions of homology at the protein sequence level with DNA polymerases of herpes, adeno and pox viruses. From studies of bacteriophage T4 and herpes DNA polymerase mutants, and from analyses of similar protein sequences from several organisms, we conclude that DNA polymerase synthetic activities are located in the C-terminal half of the DNA polymerase and that exonucleolytic activity is located nearer the N terminus.

Cloning and expression of T4 DNA polymerase

The structural gene coding for bacteriophage T4 DNA polymerase (gene 43) has been cloned into inducible plasmid vectors, which provide a source for obtaining large amounts of this enzyme after induction. The T4 DNA polymerase produced in this fashion was purified by an innovative three-step procedure and was fully active.