Host-Mediated Repair of Discontinuities in DNA From T4 Bacteriophage

Discontinuities of T4 DNA which are caused by excision of UV-damaged areas, by decay of (32)P atoms, or which are present in DNA from rII(-)lig(am) (-) phage produced in a host nonpermissive for amber mutants are all repaired by bacterial enzymes after infection in the presence of chloramphenicol. Escherichia coli DNA polymerase I participates in the host-mediated repair, but an approximately 20-fold variation in the levels of host polynucleotide ligase does not affect either the kinetics or the extent of repair observed. Upon removal of chloramphenicol, host-repaired DNA from UV-irradiated phage undergoes a secondary cycle of breakage, which ultimately results in solubilization of most of the phage DNA. If the cells are co-infected with nonirradiated helper phage, the secondary breaks are repaired and the continuity of the polynucleotide chain is restored. The close coincidence in the extent of primary and secondary breakage suggests that phage-coded enzymes recognize and excise areas improperly repaired by the host. In contrast to host-mediated repair, repair mediated by rescuing phage probably restored functionality to the damaged DNA.     

Isolation and Characterization of Conditional Alleles of Bacteriophage T4 Genes uvsX and uvsY

The bacteriophage T4 uvsW, uvsX and uvsY gene functions are required for wild-type levels of recombination and for normal survival and mutagenesis after treatments with ultraviolet (UV) and ionizing radiations. The ability of uvsX and uvsY mutations to suppress the lethality of gene 49 mutations was used to select temperature-sensitive and amber alleles of these two genes. (uvsW mutations do not suppress gene 49 mutations.) A simple and powerful complementation test was developed to assist in assigning uvs mutations to genes. The amber alleles of uvsX and uvsY behave as simple null alleles, fully suppressing a gene 49 defect, enhancing UV killing and abolishing UV mutagenesis. However, the properties of the ts alleles of uvsX and uvsY demonstrated that suppression of a gene 49 defect, sensitivity to UV-induced inactivation and UV mutability can be partially uncoupled. These results prompt the hypothesis that radiation mutagenesis occurs during DNA chain elongation past template damage within a recombinational intermediate rather than within a conventional replication fork.     

Role of Gene 52 in Bacteriophage T4 DNA Synthesis

In an attempt to elucidate the mechanism of delayed DNA synthesis in phage T4, Escherichia coli B cells were infected with H17 (an amber mutant defective in gene 52 possessing a "DNA-delay" phenotype). The fate of (14)C-labeled H17 parental DNA after infection was followed: we could show that this DNA sediments more slowly in neutral sucrose than wild-type DNA 3 min postinfection. In pulse-chase experiments progeny DNA was found to undergo detachment from the membrane at 12 min postinfection. Reattachment to the membrane was found to be related to an increase in rate of DNA synthesis. A nucleolytic activity that is absent from cells infected by wild-type phage and from uninfected cells could be detected in extracts prepared from mutant-infected cells. In contrast, degradation of host DNA was found to be less extensive in am H17 compared with wild-type infected cells. Addition of chloramphenicol to mutant-infected cells 10 min postinfection inhibited the appearance of a nuclease activity on one hand and suppressed the "DNA-delay" phenotype on the other hand. We conclude that the gene 52 product controls the activity of a nuclease in infected cells whose main function may be specific strand nicking in association with DNA replication. This gene product might directly attack both E. coli and phage T4 DNA, or indirectly determine their sensitivity to degradation by another nuclease.     

A New Epistasis Group for the Repair of DNA Damage in Bacteriophage T4: Replication Repair

The gene 32 mutation amA453 sensitizes bacteriophage T4 to the lethal effects of ultraviolet (UV) irradiation, methyl methanesulfonate and angelicin-mediated photodynamic irradiation when treated particles are plated on amber-suppressing host cells. The increased UV sensitivity caused by amA453 is additive to that caused by mutations in both the T4 excision repair (denV) and recombination repair (uvsWXY) systems, suggesting the operation of a third kind of repair system. The mutation uvs79, with many similarities to amA453 but mapping in gene 41, is largely epistatic to amA453. The mutation mms1, also with many similarities to amA453, maps close to amA453 within gene 32 and is largely epistatic to uvs79. Neither amA453 nor uvs79 affect the ratio of UV-induced mutational to lethal hits, nor does amA453 affect spontaneous or UV-enhanced recombination frequencies. Gene 32 encodes the major T4 ssDNA-binding protein (the scaffolding of DNA replication) and gene 41 encodes a DNA helicase, both being required for T4 DNA replication. We conclude that a third repair process operates in phage T4 and suggest that it acts during rather than before or after DNA replication.     

Requirement of a Functional Gene 32 Product of Bacteriophage T4 in UV Repair

A temperature-sensitive mutation in gene 32 was used to study the role of gene 32 protein in the repair of UV-damaged DNA of bacteriophage T4. It was possible to distinguish between repair and replication of DNA at 33 C. At this temperature, DNA replication continued, and the intracellular DNA was stable. In contrast, no significant repair of UV-damaged DNA was observed even 40 min after the irradiation. Therefore, it was concluded that the defect in the repair mechanism at this temperature is not a simple consequence of the defect in DNA replication but that gene 32 apparently has an independent role for DNA repair. It was reported previously that gene 32 product is required for both T4 DNA replication and genetic recombination. In addition to these findings, this study has given direct evidence that, in vivo, this protein is also essential for the UV repair mechanism.     

Bacteriophage T4 Gene 32 Participates in Excision Repair as Well as Recombinational Repair of Uv Damages

Gene 32 of phage T4 has been shown previously to be involved in recombinational repair of UV damages but, based on a mutant study, was thought not to be required for excision repair. However, a comparison of UV-inactivation curves of several gene 32 mutants grown under conditions permissive for progeny production in wild-type or polA- hosts demonstrates that gene 32 participates in both kinds of repair. Different gene 32 mutations differentially inactivate these repair functions. Under conditions permissive for DNA replication and progeny production, all gene 32 mutants investigated here are partially defective in recombinational repair, whereas only two of them, P7 and P401, are also defective in excision repair. P401 is the only mutant whose final slope of the inactivation curve is significantly steeper than that of wild-type T4. These results are discussed in terms of interactions of gp32, a single-stranded DNA-binding protein, with DNA and with other proteins.     

Replicative Hybrid of T4 Bacteriophage DNA

Hybrid density replicative T4 DNA was isolated from CsCl, sheared, and reanalyzed in CsCl. The results rule out a branched model for T4 DNA replication and confirm that T4 DNA replicates to a conventional, semiconservative, colinear hybrid.     

Studies on the Recombination Genes of Bacteriophage T4: Suppression of uvsX and uvsY Mutations by uvsW Mutations

Genes uvsW, uvsX and uvsY are dispensable for T4 growth but are implicated in recombination and in the repair of damaged DNA. We found that large-plaque mutants arose efficiently from small-plaque uvsX and uvsY mutants at 42 degrees and were pseudorevertants containing a new mutation in uvsW. Using reconstructed double mutants, we confirmed that a mutation in uvsW partially increases the burst size and UV resistance of uvsX and uvsY mutants. At 41 degrees the uvsW mutation completely restores the arrest in DNA synthesis caused by mutations in genes uvsX, uvsY and 46, but at 30 degrees it only partially restores DNA synthesis in a gene 46 mutant and does not restore DNA synthesis in uvsX and uvsY mutants. Restored DNA synthesis at 41 degrees was paralleled by the overproduction of single-stranded DNA and gene 32 protein. Based on these findings, we propose that the uvsW gene regulates the production of single-stranded DNA and we discuss the phenotype of uvsW mutants and their suppression of some uvsX and uvsY phenotypes. Infection of restrictive cells with am uvsW mutants revealed a defect in the synthesis of a protein of molecular weight 53,000 daltons, suggesting that this protein is the uvsW gene product.     

In Vitro Repair of Gaps in Bacteriophage T7 DNA

An in vitro system based upon extracts of Escherichia coli infected with bacteriophage T7 was used to study the mechanism of double-strand break repair. Double-strand breaks were placed in T7 genomes by cutting with a restriction endonuclease which recognizes a unique site in the T7 genome. These molecules were allowed to repair under conditions where the double-strand break could be healed by (i) direct joining of the two partial genomes resulting from the break, (ii) annealing of complementary versions of 17-bp sequences repeated on either side of the break, or (iii) recombination with intact T7 DNA molecules. The data show that while direct joining and single-strand annealing contributed to repair of double-strand breaks, these mechanisms made only minor contributions. The efficiency of repair was greatly enhanced when DNA molecules that bridge the region of the double-strand break (referred to as donor DNA) were provided in the reaction mixtures. Moreover, in the presence of the donor DNA most of the repaired molecules acquired genetic markers from the donor DNA, implying that recombination between the DNA molecules was instrumental in repairing the break. Double-strand break repair in this system is highly efficient, with more than 50% of the broken molecules being repaired within 30 min under some experimental conditions. Gaps of 1,600 nucleotides were repaired nearly as well as simple double-strand breaks. Perfect homology between the DNA sequence near the break site and the donor DNA resulted in minor (twofold) improvement in the efficiency of repair. However, double-strand break repair was still highly efficient when there were inhomogeneities between the ends created by the double-strand break and the T7 genome or between the ends of the donor DNA molecules and the genome. The distance between the double-strand break and the ends of the donor DNA molecule was critical to the repair efficiency. The data argue that ends of DNA molecules formed by double-strand breaks are typically digested by between 150 and 500 nucleotides to form a gap that is subsequently repaired by recombination with other DNA molecules present in the same reaction mixture or infected cell.     

Bacteriophage T4 proteins replicate plasmids with a preformed R loop at the T4 ori(uvsY) replication origin in vitro

Bacteriophage T4 DNA replication proteins catalyze complete unidirectional replication of plasmids containing the T4 ori(uvsY) replication origin in vitro, beginning with a preformed R loop at the position of the origin R loop previously identified in vivo. T4 DNA polymerase, clamp, clamp loader, and 32 protein are needed for initial elongation of the RNA, which serves as the leading-strand primer. Normal replication is dependent on T4 41 helicase and 61 primase and is strongly stimulated by the 59 helicase loading protein. 59 protein slows replication without the helicase. As expected, leading-strand synthesis stalls prematurely in the absence of T4 DNA topoisomerase. A DNA unwinding element (DUE) is essential for replication, but the ori(uvsY) DUE can be replaced by other DUE sequences.     

Host- and Phage-Mediated Repair of Radiation Damage in Bacteriophage T4

T4+ exhibits increased ultraviolet sensitivity on derivatives of Escherichia coli K12 or B lacking deoxyribonucleic acid (DNA) polymerase I. However, the sensitivity of T4v is not affected by the absence of host DNA polymerase. T4x and T4y also show increased sensitivity on DNA polymerase-deficient strains, but to a lesser extent than observed with wild-type T4. When T4x or T4y, but not T4+, are plated on a double mutant lacking both DNA polymerase and the uvrA gene product, a partial suppression of the polymerase effect is observed. Host ligase appears to be able to suppress to some extent the T4y phenotype but has no effect on wild-type T4 or other T4 mutants. T4xv incubated in E. coli B or B(s-1) in the presence of chloramphenicol (50 mug/ml) shows increased resistance over directly plated irradiated phage. Increased survival under the same conditions was not observed with T4+ or other T4 mutants. The repair of X-ray-damaged T4 was investigated by examining survival curves of T4+, T4x, T4y, T4ts43, and T4ts30. The repair processes were further defined by observing the effects of plating irradiated phage on various hosts including strains lacking DNA polymerase I or polynucleotide ligase. Two classes of effects were observed. Firstly, the x and y gene products seem to be involved in a repair system utilizing host ligase. Secondly, in the absence of host DNA polymerase, phage sensitivity is increased in an unknown manner which is enhanced by the presence of host uvrA gene product.     

Expression and Properties of Bacteriophage T4 Gene Product 11

A plasmid vector for expression of bacteriophage T4 gene product 11 (gp11) in E. coli cells has been constructed. Gp11 is a baseplate protein that connects short tail fibers providing irreversible adsorption of the virus on a cell. A method based on chromatography on hydroxyapatite has been developed for purification of recombinant gp11. The protein is active in an in vitro complementation assay and transforms defective phage particles lacking gp11 into infective ones. Gel filtration data suggest that the biologically active protein is a trimer. According to CD spectroscopy and sequence analysis data, the polypeptide chain of gp11 contains not less than 20% -helical segments, about 30% -structure, and belongs to the class of / structural proteins.     

Repair of Double-Strand Breaks in Bacteriophage T4 by a Mechanism That Involves Extensive DNA Replication

We investigated double-strand break (dsb) repair in bacteriophage T4 using a physical assay that involves a plasmid substrate with two inverted DNA segments. A dsb introduced into one repeat during a T4 infection induces efficient dsb repair using the second repeat as a template. This reaction is characterized by the following interesting features. First, the dsb induces a repair reaction that is directly coupled to extensive plasmid replication; the repaired/replicated product is in the form of long plasmid concatemers. Second, repair of the dsb site is frequently associated with exchange of flanking DNA. Third, the repair reaction is absolutely dependent on the products of genes uvsX, uvsY, 32, 46, and 59, which are also required for phage genomic recombination-dependent DNA replication. Fourth, the coupled repair/replication reaction is only partly dependent on endonuclease VII (gp49), suggesting that either another Holliday-junction-cleaving activity or an alternate resolution pathway is active during T4 infections. Because this repair reaction is directly coupled to extensive replication, it cannot be explained by the SZOSTAK et al. model. We present and discuss a model for the coupled repair/replication reaction, called the extensive chromosome replication model for dsb repair.     

Mutation to Overproduction of Bacteriophage T4 Gene Products

R9 was isolated as one of several mutations that enhanced the growth of a leaky amber (am) mutant of bacteriophage T4 gene 62 (product required for phage DNA synthesis) under conditions of partial suppression by ribosomal ambiguity. R9 also enhanced the growth of leaky am mutants of some, but not all, other T4 “early” gene functions. R9 mapped between mutations in genes 43 and 62. By using assays involving polyacrylamide slab gel electrophoresis in the presence of sodium dodecyl sulfate, we observed the following. (i) R9 resulted in an overproduction of many T4 “early” proteins in infected cells. The most pronounced effects of R9 were observed when phage DNA synthesis and/or the functions of maturation genes 55 and 33 were not expressed. (ii) In rifampintreated infected cells, the capacity to synthesize T4 “early” proteins decayed more slowly in the presence of the R9 mutation than in the presence of the wild-type counterpart of R9. R9 appeared to have no effect on the rates of RNA synthesis either during early or late times after infection. The results suggest that the R9 mutation leads to increased functional stability of T4 “early” messengers.     

Suppression of DNA Arrest Mutants in Bacteriophage T4

A mutation in gene 49 of phage T4 was not able to restore DNA synthesis in a gene 46 mutant.