Defect in synthesis of deoxyribonucleotides by a bacteriophage T4 nrdB mutant is suppressed on mutation of T4 DNA topoisomerase gene

Bacteriophage T4 infection is known to induce the formation of a complex of enzymes effecting the de novo synthesis of deoxyribonucleoside triphosphates, which in turn are channeled into T4 DNA replication. The first step in this pathway is catalyzed by a ribonucleoside diphosphate reductase, comprised of subunits coded by T4 genes nrdA and nrdB. Maximum rates of synthesis of the pyrimidine deoxyribonucleotides and of DNA replication in vivo also require a type II DNA topoisomerase encoded by T4 genes 39, 52, and 60. We report the identification of a unique mutant, nrdB93, and the suppression of its defective deoxyribonucleotide synthesis by a gene 39 mutation, 39-01. After infection by 39-01, DNA synthesis and plaque formation were temperature-sensitive, but nearly wild type rates of deoxyribonucleotide synthesis were retained at all temperatures. The nrdB93 mutation had a profound effect on deoxyribonucleotide synthesis at 41 degrees C; even at the permissive temperature of 30 degrees C, synthesis was reduced to 30% of that of wild type or 39-01. However, on infection at 30 degrees C by the double mutant, 39-01 nrdB93, the level of deoxyribonucleotide synthesis again reached that of wild type phage infections; involvement of the comparable host enzyme in the suppression process has been excluded. Suppression of the effect of nrdB93 by 39-01 implicates the gene 39 product in the regulation of nrdB expression. The accompanying paper (Cook, K. S., Wirak, D. O., Seasholtz, A. F., and Greenberg, G. R. (1988) J. Biol. Chem. 263, 6202-6208) examines the nature of the suppression process at the molecular level.     

Ribonucleotide reductase: A determinant of 5-bromodeoxyuridine mutagenesis in phage T4

Summary Mutagenesis by 5-bromodeoxyuridine (BrdUrd) can result from base-pairing errors either during replication of a BrdUrd-containing template or at the nucleotide incorporation step. Replication errors give rise predominantly to AT-to-GC transitions, while incorporation errors, in which 5-bromo-dUTP competes with dCTP at a template guanine site, should give rise to GC-to-AT transitions. The latter pathway should be sensitive to deoxyribonucleoside triphosphate (dNTP) pool fluctuations. Since dNTP pools are regulated through allosteric control of ribonucleotide reductase, the control of this enzyme should be a determinant of BrdUrd mutagenesis — if mutagenesis results largely from incorporation errors. Since T4 phage-encoded ribonucleotide reductase is insensitive to feedback inhibition, we established conditions under which phage DNA replication is dependent upon ribonucleotide reductase of the host, Escherichia coli. We examined BrdUrd mutagenesis of rII mutants known to revert to wild type either by AT-to-GC or GC-to-AT transition pathways. While both reversion pathways were stimulated under all conditions analyzed, the AT-to-GC pathway was stimulated more when the E. coli reductase was functioning, while the GC-to-AT pathway was more specifically enhanced when the T4 reductase was active. These results confirm that ribonucleotide reductase is a determinant of BrdUrd mutagenesis, but our observations, plus experiments showing that BrdUrd has relatively small effects upon dNTP pool sizes, indicate that the relationship between deoxyribonucleotide metabolism and BrdUrd mutagenesis is more complex than anticipated.     

Development of an in vitro bacteriophage N4 DNA replication system

An in vitro DNA replication system from bacteriophage N4-infected Escherichia coli has been developed. It requires MgCl2, all four deoxyribonucleoside triphosphates, and exogenously added N4 phage DNA; other DNAs are used inefficiently or not at all. Ribonucleoside triphosphates are not required, although they stimulate DNA synthesis. In vitro replication starts at the ends of the N4 genome and moves progressively inward. Initiation occurs through hairpin priming at the 3' ends of the genome, but shows a strong preference for the right end. Three N4 gene products (dnp, dbp, and exo) required in vivo for N4 DNA synthesis are absolutely required in the in vitro system. These findings are discussed with respect to the mode of N4 DNA replication.     

Purification of the gene 43, 44, 45, and 62 proteins of the bacteriophage T4 DNA replication apparatus.

A procedure has been developed which allows the T4 bacteriophage proteins corresponding to the products of genes 43, 44, 45, and 62 to be purified to near homogeneity from a single T4-infected cell lysate (greater than 90% single species as judged by sodium dodecyl sulfate polyacrylamide elctrophoresis). In these preparations, the major problem of removing all contaminating nucleases has been overcome. Each of the above proteins is known from genetic analysis to be essential for phage DNA replication. The protein product of gene 43 is T4 DNA polymerase, and its recovery can be monitored using a standard DNA polymerase assay. The other three gene products have been designated as "polymerase accessory proteins," since they directly enhance polymerase function on both single- and double-stranded DNA templates. Their activities were monitored by an "in vitro complementation assay," which measures the stimulation of DNA synthesis observed in a concentrated lysate of T4 mutant-infected Escherichia coli cells when the missing T4 wild type protein is added. Starting from 300 g of infected cell paste, we obtained 9.3 mg of gene 43 protein, 21 mg of gene 45 protein, and 70 mg of a tight complex made up of 44 and 62 proteins; final yields were estimated at 30%, 14%, and 28%, respectively, of the initial activity present in the lysate. When the above purified proteins are incubated with preparations of two other T4 DNA replication proteins (gene 41 and gene 32 proteins) plus deoxyribonucleoside and ribonucleoside triphosphates, extensive DNA synthesis occurs on both single- and double-stranded DNA templates. As reported elsewhere, this synthesis mimicks that catalyzed by the T4 DNA replication apparatus in vivo.     

Regulation of deoxyribonucleotide biosynthesis during in vivo bacteriophage T4 DNA replication. Intrinsic control of synthesis of thymine and 5-hydroxymethylcytosine deoxyribonucleotides at precise ratio found in DNA.

The kinetics of the de novo formation of pyrimidine deoxyribonucleotides is the same after infection by wild type bacteriophage T4, which generate very low steady state levels of deoxytibonucleotides, and by T4 DNA synthesis-negative mutatants (Dna-), which accumulate high levels, suggesting that the control is not by a feedback mechanism. In this study, the ratio of the de novo synthesis of dTMP to HmdCMP derivatives was measured by determining the total thymine and 5-hydroxylxytosine (HmCyt) deoxyribonucleotides synthesized by the reductive pathways from [6-3H]uracil including those in DNA and any degradation products excreted into the medium. The ratio of the de novo synthesis of Thy/HmCyt derivatives remained constant at 2.1 +/- 0.1 for at least 45 min after infection by wild type phage, i.e. precisely at the Thy/HmCyt ratio in T4 DNA. On infection by phage mutated in the Dna-genes 32, 41, 44, or 45, the ratio still remained close to 2 to 1 for at least 25 min. Only after the pyrimidine deoxyribonucleotide concentrations reached levels about 100-fold greater than the initial values did the ratio begin to increase. However, a mutant of the structural gene for T4 DNA polymerase showed some increase in ratio by 15 min. Mutants of gene 1 (HmdCMP kinase) were distinct in that the Thy/HmCyt ratio dropped to about 1.0 by 25 min, and then remained quite constant. Uniquely, in these mutants a significant quantity of 5-hydroxymethyluracil or a derivative was found, about 40% being in the medium. The product was shown to be derived by deamination of a 5-HmCyt derivative. All Dna- mutants tested excreted 35 to 50% of their thymine derivatives, mostly as thymine, into the medium. Neither thymine nor 5-hydroxymethyluracil derivates were excreted after wild type phage infection. We propose that pyrimidine deoxyribonucleotide synthesis is regulated at a Thy:HmCyt ratio of 2:1 as an intrinsic property of a complex of enzymes synthesizing and channeling deoxyribonucleotides for T4 DNA replication and not exclusively by effector-sensitive mechanisms.     

In situ enzymology of DNA replication and ultraviolet-induced DNA repair synthesis in permeable human cells

Using permeable diploid human fibroblasts, we have studied the deoxyribonucleoside triphosphate concentration dependences of ultraviolet- (UV-) induced DNA repair synthesis and semiconservative DNA replication. In both cell types (AG1518 and IMR-90) examined, the apparent Km values for dCTP, dGTP, and dTTP for DNA replication were between 1.2 and 2.9 microM. For UV-induced DNA repair synthesis, the apparent Km values were substantially lower, ranging from 0.11 to 0.44 microM for AG1518 cells and from 0.06 to 0.24 microM for IMR-90 cells. Control experiments established that these values were not significantly influenced by nucleotide degradation during the permeable cell incubations or by the presence of residual endogenous nucleotides within the permeable cells. Recent data implicate DNA polymerase delta in UV-induced repair synthesis and suggest that DNA polymerases alpha and delta are both involved in semiconservative replication. We measured Km values for dGTP and dTTP for polymerases alpha and delta, for comparison with the values for replication and repair synthesis. Km values for polymerase alpha were 2.0 microM for dGTP and 5.0 microM for dTTP. For polymerase delta, the Km values were 2.0 microM for dGTP and 3.5 microM for dTTP. The deoxyribonucleotide Km values for DNA polymerase delta are much greater than the Km values for UV-induced repair synthesis, suggesting that when polymerase delta functions in DNA repair, its characteristics are altered substantially either by association with accessory proteins or by direct posttranslational modification. In contrast, the deoxyribonucleotide binding characteristics of the DNA replication machinery differ little from those of the isolated DNA polymerases.(ABSTRACT TRUNCATED AT 250 WORDS)     

Replication of bacteriophage T4 DNA in vitro. I. Basic properties of the system.

A new in vitro system for T4 DNA replication was developed by concentrating cell lysates on cellophane disks. The time course of [3H]dTTP incorporation into DNA by the system was separated into two phases: one was a very rapid incorporation which was terminated within 2 min (phase I reaction), and the other was a slow but continuous incorporation thereafter (phase II reaction). More than half of the phase I reaction product was Escherichia coli DNA, but the phase II reaction was mostly T4 DNA. Phase II reaction required four deoxyribonucleoside triphosphates, ATP, Mg2+, and KCl. 5-Hydroxymethyldeoxycytidine triphosphate was essential for the reaction and not substitutable by dCTP. The presence of KCN or NaN3 in the reaction mixture did not interfere with [3H]dTTP incorporation, but the addition of deoxyribonuclease completely degraded the system. Alkaline sucrose sedimentation analysis of phage II reaction product revealed that phase II reaction proceeded by the discontinuous mode of DNA replication as in vivo. After T4 infection, the activity for phase II reaction appeared in parallel with the activity of T4 phage DNA replication in vivo.     

Studies on bacteriophage T7 DNA synthesis in vitro. II. Reconstitution of the T7 replication system using purified proteins.

Summary DNA synthesis in vitro using intact duplex T7 DNA as template is dependent on a novel group of three phage T7-induced proteins: DNA-priming protein (activity which complements a cell extract lacking the T7 gene 4-protein), T7 DNA polymerase (gene 5-protein plus host factor), and T7 DNA-binding protein. The reaction requires, in addition to the four deoxyribonucleoside triphosphates, all four ribonucleoside triphosphates and is inhibited by low concentrations of actinomycin D. Evidence is presented that the priming protein serves as a novel RNA polymerase to form a priming segment which is subsequently extended by T7 DNA polymerase. T7 RNA polymerase (gene 1-protein) can only partially substitute for the DNA-priming protein. At 30°C, deoxyribonucleotide incorporation proceeds for more than 2 hours and the amount of newly synthesized DNA can exceed the amount of template DNA by 10-fold. The products of synthesis are not covalently attached to the template and sediment as short (12S) DNA chains in alkaline sucrose gradients. Sealing of these fragments into DNA of higher molecular weight requires the presence of E. coli DNA polymerase I and T7 ligase. Examination of the products in the electron microscope reveals many large, forked molecules and a few eye-shaped structures resembling the early replicative intermediates normally observed in vivo.     

Bacteriophage T4-Directed DNA Synthesis in Toluene-Treated Cells

DNA synthesis has been studied in T4-infected Escherichia coli cells made permeable to nucleotides by treatment with toluene. The rate of incorporation of labeled deoxyribonucleoside triphosphates into DNA at various times after infection is proportional to the in vivo rate. This in vitro incorporation is dependent on all four deoxyribonucleoside triphosphates (5-hydroxymethyldeoxy-cytidine triphosphate can substitute for dCTP) and Mg(2+). It is stimulated by rATP, partially inhibited by pancreatic DNase, and abolished by N-ethylmalei-mide and 1-beta-d-arabinofuranosylcytosine triphosphate. T4 amber DO (DNA negative) and temperature-sensitive DO mutants under nonpermissive conditions of infection fail to induce DNA synthesis in vitro. The synthesizing activity is intracellular and the DNA product is exclusively T4 DNA. The in vitro synthesis proceeds in a discontinuous manner involving synthesis and subsequent joining of small DNA fragments (about 10S in alkaline sucrose gradients) into larger molecules predominantly one-half the length of mature T4 DNA. No restriction of C-containing or nonglucosylated HMC-containing T4 DNA product is observed in this system.     

Single-molecule investigation of the T4 bacteriophage DNA polymerase holoenzyme: multiple pathways of holoenzyme formation

In T4 bacteriophage, the DNA polymerase holoenzyme is responsible for accurate and processive DNA synthesis. The holoenzyme consists of DNA polymerase gp43 and clamp protein gp45. To form a productive holoenzyme complex, clamp loader protein gp44/62 is required for the loading of gp45, along with MgATP, and also for the subsequent binding of polymerase to the loaded clamp. Recently published evidence suggests that holoenzyme assembly in the T4 replisome may take place via more than one pathway [Zhuang, Z., Berdis, A. J., and Benkovic, S. J. (2006) Biochemistry 45, 7976-7989]. To demonstrate unequivocally whether there are multiple pathways leading to the formation of a productive holoenzyme, single-molecule fluorescence microscopy has been used to study the potential clamp loading and holoenzyme assembly pathways on a single-molecule DNA substrate. The results obtained reveal four pathways that foster the formation of a functional holoenzyme on DNA: (1) clamp loader-clamp complex binding to DNA followed by polymerase, (2) clamp loader binding to DNA followed by clamp and then polymerase, (3) clamp binding to DNA followed by clamp loader and then polymerase, and (4) polymerase binding to DNA followed by the clamp loader-clamp complex. In all cases, MgATP is required. The possible physiological significance of the various assembly pathways is discussed in the context of replication initiation and lagging strand synthesis during various stages of T4 phage replication.     

In vitro studies on the role of phage T7 gene 4 product in DNA replication

Summary A soluble enzyme fraction prepared from T7-infected E. coli is able to initiate DNA synthesis on circular single-stranded phage DNA. The product synthesized in vitro is a full-length linear complementary strand as judged by alkaline sucrose gradient analysis. DNA synthesis requires the products of the phage genes 4 and 5, Mg⁺⁺, dNTPs and rNTPs; however, ATP by itself can almost completely satisfy the rNTP requirement. The gene 4 product is essential for DNA chain initiation on unprimed single-stranded DNA, but is dispensable for the replication of a X174 DNA-RNA hybrid. The enzyme system from T7-infected cells does not discriminate between the DNA templates from phages X174, M13 or fd and is also capable of replicating native T7 DNA. However, a striking difference with regard to the template DNA is revealed by complementation analysis. Extracts of T7 mutant-infected cells complement each other only with T7 DNA but not with X174 DNA as template.Abbreviations rNTP ribonucleoside triphosphate - dNTP deoxyribonucleoside triphosphate - BSA bovine serum albumin     

Postinfection control in T4 bacteriophage infection: inhibition of the rep function.

We suggest that the general mechanism by which T4 phage turns off host macromolecular synthesis involves specific phage proteins which react with key components in the synthetic pathway. Support for this mechanism exists for the inhibition of host RNA synthesis. Here we note that the host rep function was inhibited after T4 phage infection. Since rep functions are known to be involved in host DNA replication, inhibition of rep might alter the course of host DNA replication.     

Fate of cloned bacteriophage T4 DNA after phage T4 infection of clone-bearing cells

Plasmid pBR322 replication is inhibited after bacteriophage T4 infection. If no T4 DNA had been cloned into this plasmid vector, the kinetics of inhibition are similar to those observed for the inhibition of Escherichia coli chromosomal DNA. However, if T4 DNA has been cloned into pBR322, plasmid DNA synthesis is initially inhibited but then resumes approximately at the time that phage DNA replication begins. The T4 insert-dependent synthesis of pBR322 DNA is not observed if the infecting phage are deleted for the T4 DNA cloned in the plasmid. Thus, this T4 homology-dependent synthesis of plasmid DNA probably reflects recombination between plasmids and infecting phage genomes. However, this recombination-dependent synthesis of pBR322 DNA does not require the T4 gene 46 product, which is essential for T4 generalized recombination. The effect of T4 infection on the degradation of plasmid DNA is also examined. Plasmid DNA degradation, like E. coli chromosomal DNA degradation, occurs in wild-type and denB mutant infections. However, neither plasmid or chromosomal degradation can be detected in denA mutant infections by the method of DNA--DNA hybridization on nitrocellulose filters.     

Rescue of DNA Replication and Bacteriophage Production After Infection with T4 DNA Ligase Mutants

By preventing phage DNA synthesis during a critical period, conditions have been found under which DNA replication and phage production are rescued after infection with T4 DNA ligase mutants.     

DNA Replication of Induced Prophage in Haemophilus influenzae

DNA synthesis during transition from the lysogenic state to the lytic cycle and throughout the latter has been studied in Haemophilus influenzae BC200 (HP1c1). Following exposure to ultraviolet light, there is a 30-min delay in DNA synthesis after which there is a rapidly increasing rate of phage DNA synthesis. The phage genome is replicated without extensive utilization of segments or of breakdown products of the bacterial chromosome. The mode of phage DNA replication was investigated by zonal sedimentation of labeled DNA in 5 to 20% neutral and alkaline sucrose gradients. Tritiated thymidine, incorporated during a 2-min pulse given at 38 min, chases rapidly into DNA, sedimenting like linear DNA of approximately 2 x 10(8) daltons, and then, at the expense of label in this peak, chases into slower-sedimenting phage DNA (2 x 10(7) daltons). The fast-sedimenting, rapidly labeled DNA satisfies certain criteria for being a concatenated replicative intermediate. Observations in the electron microscope revealed linear concatemers in the faster-sedimenting material and circular phage-sized DNA in the slower-sedimenting DNA. When induced cells are gently lysed with lysozyme and Brij 58 to maintain DNA-membrane associations and sedimented in neutral sucrose over a cesium chloride shelf, the concatemer is found with the cell-membrane-wall complex. Membrane-associated label chases to membrane-free material sedimenting like deproteinized HP1c1 DNA. When membrane-associated DNA from the cesium chloride shelf is deproteinized and resedimented in neutral sucrose, the sedimentation profile reveals that sedimentation rates of labeled DNA from this complex are indicative of sizes ranging from 2 x 10(8) daltons down to phage-sized pieces of 2 to 3 x 10(7) daltons. A model is presented which places HP1c1-DNA replication on the cell membrane where a concatemer of phage DNA is synthesized and subsequently degraded to phage-equivalent DNA. Phage-equivalent DNA is then either released from the membrane for packaging or is packaged while still membrane associated. Thus, the cell membrane is not only the site of DNA replication during which phage DNA is synthesized in multiple phage-equivalent concatemers but it is also the site at which these concatemers are selectively reduced to phage-sized pieces.     

A preformed, topologically stable replication fork. Characterization of leading strand DNA synthesis catalyzed by T7 DNA polymerase and T7 gene 4 protein

This paper describes the construction of a DNA molecule containing a topologically stable structure that simulates a replication fork. This preformed DNA molecule is a circular duplex of 7.2 X 10(3) base pairs (M13mp6 DNA) from which arises, at a unique BamHI recognition site, a noncomplementary 5'-phosphoryl-terminated single strand of 237 nucleotides (SV40 DNA). This structure has two experimental attributes. 1) Templates for both leading and lagging strand synthesis exist as stable structures prior to any DNA synthesis. 2) DNA synthesis creates a cleavage site for the restriction endonuclease BamHI. Form I of T7 DNA polymerase, alone, catalyzes limited DNA synthesis at the preformed replication fork whereas Form II, alone, polymerizes less than 5 nucleotides. However, when T7 gene 4 protein is present, Form II of T7 DNA polymerase catalyzes rapid and extensive synthesis via a rolling circle mode. Kinetic analysis of this synthesis reveals that the fork moves at a rate of 300 bases/s at 30 degrees C. We conclude that the T7 gene 4 protein requires a single-stranded DNA binding site from which point it translocates to the replication fork where it functions as a helicase. The phage T4 DNA polymerase catalyzes DNA synthesis at this preformed replication fork in the presence of gene 4 protein, but the amount of DNA synthesized is less that 3% of the amount synthesized by the combination of Form II of T7 DNA polymerase and gene 4 protein. We conclude that T7 DNA polymerase and T7 gene 4 protein interact specifically during DNA synthesis at a replication fork.     

Inhibition of bacteriophage PBS2 replication in Bacillus subtilis by phleomycin.

Phleomycin is an effective inhibitor of the replication of Bacillus subtilis bacteriophage PBS2, whose DNA contains uracil instead of thymine. Phleomycin does not affect the induction of the known phage enzymes involved in deoxyribonucleotide metabolism. But phage DNA synthesis is severely inhibited by phleomycin, and late virion protein synthesis is eliminated. These effects appear to result from a phleomycin-induced degradation of the parental phage DNA. Similar inhibitory and degradative effects on DNA are seen in phleomyinc-treated, uninfected cells. This system is unaffected by the related antibiotic, bleomycin.     

RNA-linked nascent DNA pieces in phage T7-infected Escherchia coli. II. Primary structure of the RNA portion.

Short DNA chains were purified from phage T7 infected E. coli cells and 5' ends were labeled with 32P. By an alkali-treatment, pNp's rich in pAp and pCp were liberated from the T7 short DNA chains. After digestion of the [5'-32P] short DNA with the 3' to 5' exonuclease of T4 DNA polymerase, [5'-32P] mono- to pentaribonucleotides tipped with a deoxyribonucleotide residue at their 3' ends were isolated. 5' terminal ribonucleotides were; exclusively AMP in the penta- and the tetraribonucleotides, mostly CMP in the triribonucleotide and mainly CMP and AMP in di- and monoribonucleotides. The 5' terminal dinucleotide of the penta- and the tetraribonucleotides was pApC. The nucleotide sequence of the tetraribonucleotide was mainly pApCpCpN and some pApCpApN, where N was mainly A and C. These results indicate that oligoribonucleotides shorter than trinucleotide may result from in vivo degradation of the tetra- and pentaribonucleotides. A possibility that the tetra- and pentaribonucleotides with a 5' triphosphate terminus are the intact primers for the discontinuous T7 DNA replication is discussed.