The DNA polymerase-encoding gene of Bacillus subtilis bacteriophage SPO1

Epigenetic Pyrimidine Nucleotides in Competition with Natural dNTPs as Substrates for Diverse DNA Polymerases

Five 2'-deoxyribonucleoside triphosphates (dNTPs) derived from epigenetic pyrimidines (5-methylcytosine, 5-hydroxymethylcytosine, 5-formylcytosine, 5-hydroxymethyluracil, and 5-formyluracil) were prepared and systematically studied as substrates for nine DNA polymerases in competition with natural dNTPs by primer extension experiments. The incorporation of these substrates was evaluated by a restriction endonucleases cleavage-based assay and by a kinetic study of single nucleotide extension. All of the modified pyrimidine dNTPs were good substrates for the studied DNA polymerases that incorporated a significant percentage of the modified nucleotides into DNA even in the presence of natural nucleotides. 5-Methylcytosine dNTP was an even better substrate for most polymerases than natural dCTP. On the other hand, 5-hydroxymethyl-2'-deoxyuridine triphosphate was not the best substrate for SPO1 DNA polymerase, which naturally synthesizes 5hmU-rich genomes of the SPO1 bacteriophage. The results shed light onto the possibility of gene silencing through recycling and random incorporation of epigenetic nucleotides and into the replication of modified bacteriophage genomes.

Shotgun metagenomics indicates novel family A DNA polymerases predominate within marine virioplankton

Virioplankton have a significant role in marine ecosystems, yet we know little of the predominant biological characteristics of aquatic viruses that influence the flow of nutrients and energy through microbial communities. Family A DNA polymerases, critical to DNA replication and repair in prokaryotes, are found in many tailed bacteriophages. The essential role of DNA polymerase in viral replication makes it a useful target for connecting viral diversity with an important biological feature of viruses. Capturing the full diversity of this polymorphic gene by targeted approaches has been difficult; thus, full-length DNA polymerase genes were assembled out of virioplankton shotgun metagenomic sequence libraries (viromes). Within the viromes novel DNA polymerases were common and found in both double-stranded (ds) DNA and single-stranded (ss) DNA libraries. Finding DNA polymerase genes in ssDNA viral libraries was unexpected, as no such genes have been previously reported from ssDNA phage. Surprisingly, the most common virioplankton DNA polymerases were related to a siphovirus infecting an α-proteobacterial symbiont of a marine sponge and not the podoviral T7-like polymerases seen in many other studies. Amino acids predictive of catalytic efficiency and fidelity linked perfectly to the environmental clades, indicating that most DNA polymerase-carrying virioplankton utilize a lower efficiency, higher fidelity enzyme. Comparisons with previously reported, PCR-amplified DNA polymerase sequences indicated that the most common virioplankton metagenomic DNA polymerases formed a new group that included siphoviruses. These data indicate that slower-replicating, lytic or lysogenic phage populations rather than fast-replicating, highly lytic phages may predominate within the virioplankton.

The genome of Bacillus subtilis bacteriophage SPO1

We report the genome sequence of Bacillus subtilis phage SPO1. The unique genome sequence is 132,562 bp long, and DNA packaged in the virion (the chromosome) has a 13,185-bp terminal redundancy, giving a total of 145,747 bp. We predict 204 protein-coding genes and 5 tRNA genes, and we correlate these findings with the extensive body of investigations of SPO1, including studies of the functions of the 61 previously defined genes and studies of the virion structure. Sixty-nine percent of the encoded proteins show no similarity to any previously known protein. We identify 107 probable transcription promoters; most are members of the promoter classes identified in earlier studies, but we also see a new class that has the same sequence as the host sigma K promoters. We find three genes encoding potential new transcription factors, one of which is a distant homologue of the host sigma factor K. We also identify 75 probable transcription terminator structures. Promoters and terminators are generally located between genes and together with earlier data give what appears to be a rather complete picture of how phage transcription is regulated. There are complete genome sequences available for five additional phages of Gram-positive hosts that are similar to SPO1 in genome size and in composition and organization of genes. Comparative analysis of SPO1 in the context of these other phages yields insights about SPO1 and the other phages that would not be apparent from the analysis of any one phage alone. These include assigning identities as well as probable functions for several specific genes and inferring evolutionary events in the phages' histories. The comparative analysis also allows us to put SPO1 into a phylogenetic context. We see a pattern similar to what has been noted in phage T4 and its relatives, in which there is minimal successful horizontal exchange of genes among a "core" set of genes that includes most of the virion structural genes and some genes of DNA metabolism, but there is extensive horizontal transfer of genes over the remainder of the genome. There is a correlation between genes in rapid evolutionary flux through these genomes and genes that are small.

Roles of genes 44, 50, and 51 in regulating gene expression and host takeover during infection of Bacillus subtilis by bacteriophage SPO1

We show that the products of SPO1 genes 44, 50, and 51 are required for the normal transition from early to middle gene expression during infection of Bacillus subtilis by bacteriophage SPO1; that they are also required for control of the shutoff of host DNA, RNA, and protein synthesis; and that their effects on host shutoff could be accounted for by their effects on the regulation of gene expression. These three gene products had four distinguishable effects in regulating SPO1 gene expression: (i) gp44-50-51 acted to restrain expression of all SPO1 genes tested, (ii) gp44 and/or gp50-51 caused additional specific repression of immediate-early genes, (iii) gp44 and/or gp50-51 stimulated expression of middle genes, and (iv) gp44 and/or gp50-51 stimulated expression of some delayed-early genes. Shutoff of immediate-early gene expression also required the activity of gp28, the middle-gene-specific sigma factor. Shutoff of host RNA and protein synthesis was accelerated by either the 44- single mutant or the 50(-)51(-) double mutant and more so by the 44(-)50(-)51(-) triple mutant. Shutoff of host DNA synthesis was accelerated by the mutants early in infection but delayed by the 44(-)50(-)51(-) triple mutant at later times. Although gp50 is a very small protein, consisting almost entirely of an apparent membrane-spanning domain, it contributed significantly to each activity tested. We identify SPO1 genes 41 to 51 and 53 to 60 as immediate-early genes; genes 27, 28, and 37 to 40 as delayed-early genes; and gene 52 as a middle gene.

Structure and function in the uracil-DNA glycosylase superfamily

Deamination of cytosine to uracil is one of the major pro-mutagenic events in DNA, causing G:C-->A:T transition mutations if not repaired before replication. Repair of uracil-DNA is achieved in a base-excision pathway initiated by a uracil-DNA glycosylase (UDG) enzyme of which four families have so far been identified. Family-1 enzymes are active against uracil in ssDNA and dsDNA, and recognise uracil explicitly in an extrahelical conformation via a combination of protein and bound-water interactions. Extrahelical recognition requires an efficient process of substrate location by 'base-sampling' probably by hopping or gliding along the DNA. Family-2 enzymes are mismatch specific and explicitly recognise the widowed guanine on the complementary strand rather than the extrahelical scissile pyrimidine. This allows a broader specificity so that some Family-2 enzymes can excise uracil and 3, N(4)-ethenocytosine from mismatches with guanine. Although structures are not yet available for Family-3 (SMUG) and Family-4 enzymes, sequence analysis suggests similar overall folds, and identifies common active site motifs but with a surprising lack of conservation of catalytic residues between members of the super-family.

Uracil-DNA glycosylase in the extreme thermophile Archaeoglobus fulgidus

Uracil-DNA glycosylase (UDG) is an essential enzyme for maintaining genomic integrity. Here we describe a UDG from the extreme thermophile Archaeoglobus fulgidus. The enzyme is a member of a new class of enzymes found in prokaryotes that is distinct from the UDG enzyme found in Escherichia coli, eukaryotes, and DNA-containing viruses. The A. fulgidus UDG is extremely thermostable, maintaining full activity after heating for 1.5 h at 95 degrees C. The protein is capable of removing uracil from double-stranded DNA containing either a U/A or U/G base pair as well as from single-stranded DNA. This enzyme is product-inhibited by both uracil and apurinic/apyrimidinic sites. The A. fulgidus UDG has a high degree of similarity at the primary amino acid sequence level to the enzyme found in Thermotoga maritima, a thermophilic eubacteria, and suggests a conserved mechanism of UDG-initiated base excision repair in archaea and thermophilic eubacteria.

Genes and regulatory sites of the "host-takeover module" in the terminal redundancy of Bacillus subtilis bacteriophage SPO1

Early in infection of Bacillus subtilis by bacteriophage SPO1, the synthesis of most host-specific macromolecules is replaced by the corresponding phage-specific biosyntheses. It is believed that this subversion of the host biosynthetic machinery is accomplished primarily by a cluster of early genes in the SPO1 terminal redundancy. Here we analyze the nucleotide sequence of this 11.5-kb "host-takeover module," which appears to be designed for particularly efficient expression. Promoters, ribosome-binding sites, and codon usage statistics all show characteristics known to be associated with efficient function in B. subtilis. The promoters and ribosome-binding sites have additional conserved features which are not characteristic of their host counterparts and which may be important for competition with host genes for the cellular biosynthetic machinery. The module includes 24 genes, tightly packed into 12 operons driven by the previously identified early promoters PE1 to PE12. The genes are smaller than average, with half of them having fewer than 100 codons. Most of their inferred products show little similarity to known proteins, although zinc finger, trans-membrane, and RNA polymerase-binding domains were identified. Transcription-termination and RNase III cleavage sites were found at appropriate locations.

How E. coli DNA polymerase I (Klenow fragment) distinguishes between deoxy- and dideoxynucleotides

Deoxy- and dideoxynucleotides differ only in whether they have a hydroxyl substituent at C-3' of the ribose moiety, and yet the Klenow fragment DNA polymerase prefers the natural (dNTP) substrate by several thousandfold. We have used this preference in order to investigate how Klenow fragment interacts with the sugar portion of an incoming dNTP. We screened mutant derivatives of Klenow fragment so as to identify those amino acid residues that play important roles in distinguishing between dNTPs and ddNTPs. Substitution of Phe762 with Ala or Tyr caused a dramatic decrease in the discrimination against ddNTPs, while mutations in Tyr766 and Glu710 had a smaller effect, suggesting that these two side-chains play secondary roles in the selection of dNTPs over ddNTPs. In order to understand the interactions in the enzyme-DNA-dNTP ternary complex, pre-steady-state kinetic parameters for the incorporation of dNTPs and ddNTPs were determined for wild-type Klenow fragment and for mutant derivatives that showed changes in dNTP/ddNTP discrimination. From elemental effect measurements we infer that selection against dideoxynucleotides takes place in the transition state for the conformational change that precedes phosphoryl transfer. The crucial role of the Phe762 side-chain appears to be to constrain the dNTP molecule so that the 3'-OH can make an interaction with another group within the ternary complex. When Tyr is substituted at position 762, the same interactions can take place to position the dNTP, but specificity against the ddNTP is lost because the phenolic OH can compensate for the missing 3'-OH of the nucleotide. Substitution of the smaller Ala side-chain results in a loss in specificity because the dNTP is no longer appropriately constrained. Measurement of reaction rates as a function of magnesium ion concentration suggests that the interaction made with the dNTP 3'-OH may involve a metal ion and the Glu710 side-chain, the simplest scenario being that both the 3'-OH and the carboxylate of Glu710 are ligands to the same metal ion.

Amino acid changes in a unique sequence of bacteriophage T7 DNA polymerase alter the processivity of nucleotide polymerization

T7 gene 5 DNA polymerase forms a complex with Escherichia coli thioredoxin (its processivity factor), and a 76-amino acid sequence (residues 258-334), unique to gene 5 protein, has been implicated in this interaction. We have examined the effect of amino acid substitution(s) in this region on T7 phage growth and on the interaction of the polymerase with thioredoxin. Among the mutations in gene 5, we found that a substitution of either Glu or Ala for Lys-302 yielded a protein that could not complement T7 phage lacking gene 5 (T7Delta5) to grow on E. coli having reduced thioredoxin levels. One triple mutant (K300E,K302E,K304E) could not support the growth of T7Delta5 even in wild type cells. This altered polymerase is stimulated 4-fold less by thioredoxin than is the wild type enzyme and the polymerase-thioredoxin complex has reduced processivity. The exonuclease activity of the altered polymerase is not stimulated to the same extent as that of the wild type enzyme by thioredoxin. The observed dissociation constant of the gene 5 protein K(300,302,304)E-thioredoxin complex is 7-fold higher than that of the wild type complex. The altered polymerase also has a lower binding affinity for double-stranded DNA.

Structural and functional organization of the DNA polymerase of bacteriophage T7

The 80-kDa gene 5 protein encoded by bacteriophage T7 shares significant amino acid homology with the large fragment of Escherichia coli DNA polymerase I (Klenow fragment). Like the Klenow fragment, T7 gene 5 protein has both DNA polymerase and 3' to 5' exonuclease activities. However, unlike the Klenow fragment, T7 gene 5 protein binds tightly to E. coli thioredoxin to form a complex that has a high processivity of nucleotide polymerization. In order to identify the domains of gene 5 protein responsible for polymerization, hydrolysis, and binding of thioredoxin, we have analyzed proteolytic fragments of gene 5 protein. Cleavage of the protein within one protease-sensitive region (residue 250-300) yields two molecular weight species of peptides of 32-37 and 43-51 kDa derived from the N-terminal and C-terminal region, respectively. DNA polymerase activity is found within the C-terminal fragments and exonuclease activity within the N-terminal fragments. Thioredoxin stimulates the DNA polymerase activity of the C-terminal fragments. All fragments bind to DNA. In addition to delineating the polymerase and exonuclease domains, the protease-sensitive region appears to interact with E. coli thioredoxin. Thioredoxin protects this region from proteolysis, and alteration of this region reduces the ability of thioredoxin to stimulate polymerase activity.

Amino acid residues critical for the interaction between bacteriophage T7 DNA polymerase and Escherichia coli thioredoxin

Upon infection of Escherichia coli, bacteriophage T7 annexes a host protein, thioredoxin, to serve as a processivity factor for its DNA polymerase, T7 gene 5 protein. In a previous communication (Himawan, J., and Richardson, C. C. (1992) Proc. Natl. Acad. Sci. U. S. A. 89, 9774-9778), we reported that an E. coli strain encoding a Gly-74 to Asp-74 (G74D) thioredoxin mutation could not support wild-type T7 growth and that in vivo, six mutations in T7 gene 5 could individually suppress this G74D thioredoxin defect. In the present study, we report the purification and biochemical characterization of the G74D thioredoxin mutant and two suppressor gene 5 proteins, a Glu-319 to Lys-319 (E319K) mutant of gene 5 protein and an Ala-45 to Thr-45 (A45T) mutant. The suppressor E319K mutation, positioned within the DNA polymerization domain of gene 5 protein, appears to suppress the parental thioredoxin mutation by compensating for the binding defect that was caused by the G74D alteration. We suggest that the Glu-319 residue of T7 gene 5 protein and the Gly-74 residue of E. coli thioredoxin define a contact point or site of interaction between the two proteins. In contrast, the A45T mutation in gene 5 protein, located within the 3' to 5' exonuclease domain, does not suppress the G74D thioredoxin mutation by simple restoration of binding affinity. Based upon our understanding of the mechanisms of suppression, we propose a model for the T7 gene 5 protein-E. coli thioredoxin interaction.

Beyond homing: competition between intron endonucleases confers a selective advantage on flanking genetic markers

The closely related B. subtilis bacteriophages SPO1 and SP82 have similar introns inserted into a conserved domain of their DNA polymerase genes. These introns encode endonucleases with unique properties. Other intron-encoded "homing" endonucleases cleave both strands of intronless DNA; subsequent repair results in unidirectional gene conversion to the intron-containing allele. In contrast, the enzymes described here cleave one strand on both intron-containing and intronless targets at different distances from their common intron insertion site. Most surprisingly, each enzyme prefers DNA of the heterologous phage. The SP82-encoded endonuclease is responsible for exclusion of the SPO1 intron and flanking genetic markers from the progeny of mixed infections, a novel selective advantage imparted by an intron to the genome in which it resides.

The DNA polymerase genes of several HMU-bacteriophages have similar group I introns with highly divergent open reading frames

A previous report described the discovery of a group I, self-splicing intron in the DNA polymerase gene of the Bacillus subtilis bacteriophage SPO1 (1). In this study, the DNA polymerase genes of three close relatives of SPO1: SP82, 2C and phi e, were also found to be interrupted by an intron. All of these introns have group I secondary structures that are extremely similar to one another in primary sequence. Each is interrupted by an open reading frame (ORF) that, unlike the intron core or exon sequences, are highly diverged. Unlike the relatives of Escherichia coli bacteriophage T4, most of which do not have introns (2), this intron seems to be common among the relatives of SPO1.