T7 single strand DNA binding protein but not T7 helicase is required for DNA double strand break repair

An in vitro system based on Escherichia coli infected with bacteriophage T7 was used to test for involvement of host and phage recombination proteins in the repair of double strand breaks in the T7 genome. Double strand breaks were placed in a unique XhoI site located approximately 17% from the left end of the T7 genome. In one assay, repair of these breaks was followed by packaging DNA recovered from repair reactions and determining the yield of infective phage. In a second assay, the product of the reactions was visualized after electrophoresis to estimate the extent to which the double strand breaks had been closed. Earlier work demonstrated that in this system double strand break repair takes place via incorporation of a patch of DNA into a gap formed at the break site. In the present study, it was found that extracts prepared from uninfected E. coli were unable to repair broken T7 genomes in this in vitro system, thus implying that phage rather than host enzymes are the primary participants in the predominant repair mechanism. Extracts prepared from an E. coli recA mutant were as capable of double strand break repair as extracts from a wild-type host, arguing that the E. coli recombinase is not essential to the recombinational events required for double strand break repair. In T7 strand exchange during recombination is mediated by the combined action of the helicase encoded by gene 4 and the annealing function of the gene 2.5 single strand binding protein. Although a deficiency in the gene 2.5 protein blocked double strand break repair, a gene 4 deficiency had no effect. This argues that a strand transfer step is not required during recombinational repair of double strand breaks in T7 but that the ability of the gene 2.5 protein to facilitate annealing of complementary single strands of DNA is critical to repair of double strand breaks in T7.     

Inactivation of the T7 coliphage by monofunctional alkylating agents. Action of phage adsorption and injection of its DNA.

Alkylation by ethyl or methyl methanesulfonate to an extent that inactivates more than 99.5% of T7 coliphages has no effect on phage adsorption on Escherichia coli B cells, but decreases the amount of phage DNA injected into the host cells. Depurination interferes with the injection of the phage DNA. Failure to inject the whole phage genome thus appears to be a cause of the immediate as well as of the delayed inactivation of the T7 coliphage treated by monofunctional alkylating agents; the hypothesis that it is the only cause of inactivation, although not very likely, cannot be excluded at the present time.     

Host-cell reactivation of alkylated T7 bacteriophage.

Purified T7 phage, treated with methyl methanesulfonate, was assayed on Escherichia coli K-12 host cells deficient in base excision repair. Phage survival, measured immediately after alkylation or following incubation to induce depurination, was lowest on a mutant defective in the polymerase activity of DNA polymerase I (p3478). Strains defective in endonuclease for apurinic sites (AB3027, BW2001) gave a significantly higher level of phage survival, as did the strain defective in the 5'--3' exonuclease activity of DNA polymerase I (RS5065). Highest survival of alkylated T7 phage was observed on the two wild-type strains (AB1157, W3110). These results show that alkylated T7 phage is subject to repair via the base excision repair pathway.     

Role of 3-methyladenine-DNA glycosylase in host-cell reactivation of methylated T7 bacteriophage

Purified T7 phage, treated with methyl methanesulfonate, was assayed on four Escherichia coli K12 host cells: (1) AB1157, wild-type; (2) PK432-1, lacking 3-methyladenine-DNA glycosylase (tag); (3) NH5016, lacking apurinic endonuclease VI (xthA); (4) p3478, lacking DNA polymerase I (polA), the latter three strains being deficient in enzymes of the base excision repair pathway. For inactivation measured immediately after alkylation, phage survival was lowest on strains PK432-1 and p3478; for delayed inactivation, measured after partial depurination of alkylated phage, survival was much lower on strain p3478 than on PK432-1. These results demonstrate the important role played by 3-methyladenine-DNA glycosylase in the survival of methylated T7 phage. Quantitative analysis of the data, using the results of Verly et al. (Verly, W.G., Crine, P., Bannon, P. and Forget, A. (1974) Biochim. Biophys. Acta 349, 204–213) to correlate the dose with the number of methyl groups introduced into phage DNA, revealed that 5–10 3-methyladenine residues per T7 DNA constituted an inactivation hit for the tag mutant. Thus, 3-methyladenine may be as toxic a lesion as an apurinic site.     

In Vitro Packaging of UV Radiation-Damaged DNA from Bacteriophage T7

When DNA from bacteriophage T7 is irradiated with UV light, the efficiency with which this DNA can be packaged in vitro to form viable phage particles is reduced. A comparison between irradiated DNA packaged in vitro and irradiated intact phage particles shows almost identical survival as a function of UV dose when Escherichia coli wild type or polA or uvrA mutants are used as the host. Although uvrA mutants perform less host cell reactivation, the polA strains are identical with wild type in their ability to support the growth of irradiated T7 phage or irradiated T7 DNA packaged in vitro into complete phage. An examination of in vitro repair performed by extracts of T7-infected E.coli suggests that T7 DNA polymerase may substitute for E. coli DNA polymerase I in the resynthesis step of excision repair. Also tested was the ability of a similar in vitro repair system that used extracts from uninfected cells to restore biological activity of irradiated DNA. When T7 DNA damaged by UV irradiation was treated with an endonuclease from Micrococcus luteus that is specific for pyrimidine dimers and then was incubated with an extract of uninfected E. coli capable of removing pyrimidine dimers and restoring the DNA of its original (whole genome size) molecular weight, this DNA showed a higher packaging efficiency than untreated DNA, thus demonstrating that the in vitro repair system partially restored the biological activity of UV-damaged DNA.     

Evidence for unique DNA repair activity encoded by a cloned Serratia marcescens gene: suppression of Escherichia coli mutations that reduce repair of alkylated DNA.

A recombinant plasmid containing a Serratia marcescens DNA repair gene has been analyzed biochemically and genetically in Escherichia coli mutants deficient for repair of alkylated DNA. The cloned gene suppressed sensitivity to methyl methanesulfonate of an E. coli strain deficient in 3-methyladenine DNA glycosylases I and II (i.e., E. coli tag alkA) and two different E. coli recA mutants. Attempts to suppress the methyl methanesulfonate sensitivity of the E. coli recA mutant by using the cloned E. coli tag and alkA genes were not successful. Southern blot analysis did not reveal any homology between the S. marcescens gene and various known E. coli DNA repair genes. Biochemical analysis with the S. marcescens gene showed that the encoded DNA repair protein liberated 3-methyladenine from alkylated DNA, indicating that the DNA repair molecular is an S. marcescens 3-methyladenine DNA glycosylase. The ability to suppress both types of E. coli DNA repair mutations, however, suggests that the S. marcescens gene is a unique bacterial DNA repair gene.     

Genetic analysis of gene 1.2 of bacteriophage T7: isolation of a mutant of Escherichia coli unable to support the growth of T7 gene 1.2 mutants.

The product of gene 1.2 of bacteriophage T7 is not required for the growth of T7 in wild-type Escherichia coli since deletion mutants lacking the entire gene 1.2 grow normally (Studier et al., J. Mol. Biol. 135:917-937, 1979). By using a T7 strain lacking gene 1.2, we have isolated a mutant of E. coli that was unable to support the growth of both point and deletion mutants defective in gene 1.2. The mutation, optA1, was located at approximately 3.6 min on the E. coli linkage map in the interval between dapD and tonA; optA1 was 92% cotransducible with dapD. By using the optA1 mutant, we have isolated six gene 1.2 point mutants of T7, all of which mapped between positions 15 and 16 on the T7 genetic map. These mutations have also been characterized by DNA sequence analysis, E. coli optA1 cells infected with T7 gene 1.2 mutants were defective in T7 DNA replication; early RNA and protein synthesis proceeded normally. The defect in T7 DNA replication is manifested by a premature cessation of DNA synthesis and degradation of the newly synthesized DNA. The defect was not observed in E. coli opt+ cells infected with T7 gene 1.2 mutants or in E. coli optA1 cells infected with wild-type T7 phage.     

Development of T7 phage and T7 phage containing apurinic sites in an exonuclease III, endonuclease IV double mutant of Escherichia coli.

The development of bacteriophage T7 was examined in an Escherichia coli double mutant defective for the two major apurinic, apyrimidinic endonucleases (exonuclease III and endonuclease IV, xth nfo). In cells infected with phages containing apurinic sites, the defect in repair enzymes led to a decrease of phage survival and a total absence of bacterial DNA degradation and of phage DNA synthesis. These results directly demonstrate the toxic action of apurinic sites on bacteriophage T7 at the intracellular level and its alleviation by DNA repair. In addition, untreated T7 phage unexpectedly displayed reduced plating efficiency and decreased DNA synthesis in the xth nfo double mutant.     

In vitro host cell reactivation of alkylated bacteriophage T7 deoxyribonucleic acid by repair-deficient strains of Escherichia coli.

An in vitro system capable of packaging bacteriophage T7 deoxyribonucleic acid (DNA) into phage heads to form viable phage particles has been used to monitor the biological consequences of DNA dam aged by alkylating agents, and an in vitro DNA replication system has been used to examine the ability of alkylated T7 DNA to serve as template for DNA synthesis. The survival of phage resulting from in vitro packaging of DNA preexposed to various concentrations of methyl methane sulfonate or ethyl methane sulfonate closely paralleled the in vivo situation, in which intact phage were exposed to the alkylating agents. Host factors responsible for survival of alkylated T7 have been examined by using wild-type strains of EScherichia coli and mutants deficient in DNA polymerase I (polA) or 3-methyladenine-DNA glycosylase (tag). For both in vivo and in vitro situations, a deficiency in 3-methyladenine-DNA glycosylase dramatically reduced phage survival relative to that in the wild type, whereas a deficiency in DNA polymerase I had an intermediate effect. Furthermore, when the tag mutant was used as an indicator strain, phage survival was enhanced when alkylated DNA was packaged with extracts prepared from a wild-type strain in place of the tag mutant or by complementing a tag extract with an uninfected tag+ extract, indicating in vitro repair during packaging.     

Mechanism of inhibition of bacteriophage T7 DNA synthesis in Escherichia coli B cells infected by alkylated bacteriophage T7

Quantitative analysis of DNA replication, in E. coli B cells infected by methyl methanesulfonate-treated bacteriophage T7, showed that production of phage DNA was delayed and decreased. The cause of the delay appeared to be a delay in host-DNA breakdown, the process which provides nucleotides for phage-DNA synthesis. In addition, reutilisation of host-derived nucleotides was impaired. These observations can be accounted for by a model in which methyl groups on phage DNA slow down DNA injection and also reduce the replicational template activity of the DNA once it has entered the cell. Repair of alkylated phage DNA may be required not only for replication but also for normal injection of DNA.     

Repair of cytotoxic lesions induced by N-methyl-N'-nitro-N-nitrosoguanidine in Salmonella typhimurium and Escherichia coli.

The role of nucleotide excision repair and 3-methyladenine DNA glycosylases in removing cytotoxic lesions induced by N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) in Salmonella typhimurium and Escherichia coli cells was examined. Compared to the E. coli wild-type strain, the S. typhimurium wild-type strain was more sensitive to the same dose of MNNG. Nucleotide excision repair in both bacterial species does not contribute significantly to the survival after MNNG treatment, indicating that the observed differences in survival between S. typhimurium and E. coli should be attributed to DNA-repair systems other than nucleotide excision repair. The survival of the E. coli alkA mutant strain is seriously affected by the lack of 3-methyladenine DNA glycosylase II, accentuating the importance of this DNA-repair enzyme in protecting E. coli cells against the lethal effects of methylating agents. Following indications from our experiments, the existence of an alkA gene analogue in S. typhimurium has been questioned. Dot-blot hybridisation, using the E. coli alkA gene as a probe, was performed, and such a nucleotide sequence was not detected on S. typhimurium genomic DNA. The existence of constitutive 3-methyladenine DNA glycosylase, analogous to the E. coli Tag gene product in S. typhimurium cells, suggested by the results is discussed.     

Amplified expression of the tag+ and alkA+ genes in Escherichia coli: identification of gene products and effects on alkylation resistance.

We have constructed plasmids which overproduce the tag and alkA gene products of Escherichia coli, i.e., 3-methyladenine DNA glycosylases I and II. The tag and alkA gene products were identified radiochemically in maxi- or minicells as polypeptides of 21 and 30 kilodaltons, respectively, which are consistent with the gel filtration molecular weights of the enzyme activities, thus confirming the identity of the cloned genes. High expression of the tag+-coded glycosylase almost completely suppressed the alkylation sensitivity of alkA mutants, indicating that high levels of 3-methyladenine DNA glycosylase I will eliminate the need for 3-methyladenine DNA glycosylase II in repair of alkylated DNA. Furthermore, overproduction of the alkA+-coded glycosylase greatly sensitizes wild-type cells to alkylation, suggesting that only a limited expression of this enzyme will allow efficient DNA repair.     

Nonessential genes of phage phiYeO3-12 include genes involved in adaptation to growth on Yersinia enterocolitica serotype O:3

Bacteriophage phiYeO3-12 is a T7/T3-related lytic phage that naturally infects Yersinia enterocolitica serotype O:3 strains by using the lipopolysaccharide O polysaccharide (O antigen) as its receptor. The phage genome is a 39,600-bp-long linear, double-stranded DNA molecule that contains 58 genes. The roles of many of the genes are currently unknown. To identify nonessential genes, the isolated phage DNA was subjected to MuA transposase-catalyzed in vitro transposon insertion mutagenesis with a lacZ' gene-containing reporter transposon. Following electroporation into Escherichia coli DH10B and subsequent infection of E. coli JM109/pAY100, a strain that expresses the Y. enterocolitica O:3 O antigen on its surface, mutant phage clones were identified by their beta-galactosidase activity, manifested as a blue color on indicator plates. Transposon insertions were mapped in a total of 11 genes located in the early and middle regions of the phage genome. All of the mutants had efficiencies of plating (EOPs) and fitnesses identical to those of the wild-type phage when grown on E. coli JM109/pAY100. However, certain mutants exhibited altered phenotypes when grown on Y. enterocolitica O:3. Transposon insertions in genes 0.3 to 0.7 decreased the EOP on Y. enterocolitica O:3, while the corresponding deletions did not, suggesting that the low EOP was not caused by inactivation of the genes per se. Instead, it was shown that in these mutants the low EOP was due to the delayed expression of gene 1, coding for RNA polymerase. On the other hand, inactivation of gene 1.3 or 3.5 by either transposon insertion or deletion decreased phage fitness when grown on Y. enterocolitica. These results indicate that phiYeO3-12 has adapted to utilize Y. enterocolitica as its host and that these adaptations include the products of genes 1.3 and 3.5, DNA ligase and lysozyme, respectively.     

Repair of benzo[a]pyrene diol epoxide damaged bacteriophage T7 DNA determined by survival of phage made by in vitro packaging

DNA from bacteriophage T7 was treated with benzo[a]pyrene diol epoxide (BPDE) and the number of covalently bound adducts per T7 genome was determined. BPDE treated T7 DNA was then incubated in an in vitro DNA packaging system so as to form infective T7 phage. The observed reduced survival of these phage measured with Escherichia coli uvrA- indicator bacteria showed that the BPDE treated DNA was in fact utilized by the in vitro packaging system and that the resulting phage contained DNA damage caused by in vitro exposure to BPDE. T7 DNA damage by BPDE was also incubated in an in vitro DNA repair system that used partially purified uvrABC proteins from E. coli. Alkaline sucrose gradient analysis demonstrated that nicks were introduced into the damaged DNA and that these incisions were repaired to yield nearly intact DNA molecules of about the size of a T7 genome. Encapsulation of the repaired DNA with the packaging system yielded phage that showed higher survival than the unrepaired control when plated on uvrA- indicator bacteria.     

DNA repair mechanisms affecting cytotoxicity by streptozotocin in E. coli

Mechanisms underlying cytotoxicity by the monofunctional nitrosourea streptozotocin (STZ) were evaluated in DNA repair-deficient E. coli mutants. Strains not proficient in recombinational repair which lack either RecA protein or RecBC gene products were highly sensitive to STZ. In contrast, cells that constitutively synthesize RecA protein and cannot initiate SOS repair mechanisms because of uncleavable LexA repressor (recAo98 lexA3) were resistant to this drug compared to a lexA3 strain. Further, E. coli cells lacking both 3-methyladenine DNA glycosylases I (tag) and II (alkA) also were highly sensitive to STZ. DNA synthesis was most inhibited by STZ in recA and alkA tag E. coli mutants, but was suppressed less markedly in wild-type and recBC cells. DNA degradation was most extensive in recA E. coli after STZ treatment, while comparable in recBC, alkA tag, and wild-type cells. Although increased single-stranded DNA breaks were present after STZ treatment in recA and recBC mutants compared to the wild type, no significant increase in DNA single-stranded breaks was noted in alkA tag E. coli. Further, DNA breaks in recBC cells were repaired, while those present in recA cells were not. These findings establish the critical importance of both recombinational repair and 3-methyladenine DNA glycosylase in ameliorating cytotoxic effects and DNA damage caused by STZ in E. coli.     

Rescue of abortive T7 gene 2 mutant phage infection by rifampin.

Infection of Escherichia coli with T7 gene 2 mutant phage was abortive; concatemeric phage DNA was synthesized but was not packaged into the phage head, resulting in an accumulation of DNA species shorter in size than the phage genome, concomitant with an accumulation of phage head-related structures. Appearance of concatemeric T7 DNA in gene 2 mutant phage infection during onset of T7 DNA replication indicates that the product of gene 2 was required for proper processing or packaging of concatemer DNA rather than for the synthesis of T7 progeny DNA or concatemer formation. This abortive infection by gene 2 mutant phage could be rescued by rifampin. If rifampin was added at the onset of T7 DNA replication, concatemeric DNA molecules were properly packaged into phage heads, as evidenced by the production of infectious progeny phage. Since the gene 2 product acts as a specific inhibitor of E. coli RNA polymerase by preventing the enzyme from binding T7 DNA, uninhibited E. coli RNA polymerase in gene 2 mutant phage-infected cells interacts with concatemeric T7 DNA and perturbs proper DNA processing unless another inhibitor of the enzyme (rifampin) was added. Therefore, the involvement of gene 2 protein in T7 DNA processing may be due to its single function as the specific inhibitor of the host E. coli RNA polymerase.     

Gene 1.2 protein of bacteriophage T7. Effect on deoxyribonucleotide pools

The gene 1.2 protein of bacteriophage T7, a protein required for phage T7 growth on Escherichia coli optA1 strains, has been purified to apparent homogeneity and shown to restore DNA packaging activity of extracts prepared from E. coli optA1 cells infected with T7 gene 1.2 mutants (Myers, J. A., Beauchamp, B. B., White, J. H., and Richardson, C. C. (1987) J. Biol. Chem. 262, 5280-5287). After infection of E. coli optA1 by T7 gene 1.2 mutant phage, under conditions where phage DNA synthesis is blocked, the intracellular pools of dATP, dTTP, and dCTP increase 10-40-fold, similar to the increase observed in an infection with wild-type T7. However, the pool of dGTP remains unchanged in the mutant-infected cells as opposed to a 200-fold increase in the wild-type phage-infected cells. Uninfected E. coli optA+ strains contain severalfold higher levels of dGTP compared to E. coli optA1 cells. In agreement with this observation, dGTP can fully substitute for purified gene 1.2 protein in restoring DNA packaging activity to extracts prepared from E. coli optA1 cells infected with T7 gene 1.2 mutants. dGMP or polymers containing deoxyguanosine can also restore packaging activity while dGDP is considerably less effective. dATP, dTTP, dCTP, and ribonucleotides have no significant effect. The addition of dGTP or dGMP to packaging extracts restores DNA synthesis. Gene 1.2 protein elevates the level of dGTP in these packaging extracts and restores DNA synthesis, thus suggesting that depletion of a guanine deoxynucleotide pool in E. coli optA1 cells infected with T7 gene 1.2 mutants may account for the observed defects.     

Role of the Gp16 lytic transglycosylase motif in bacteriophage T7 virions at the initiation of infection

The predicted catalytic glutamate residue for transglycosylase activity of bacteriophage T7 gp16 is not essential for phage growth, but is shown to be beneficial during infection of Escherichia coli cells grown to high cell density, conditions in which murein is more highly cross-linked. In the absence of the putative transglycosylase, internalization of the phage genome is significantly delayed during infection. The lytic transglycosylase motif of gp16 is essential for phage growth at temperatures below 20 degrees C, indicating that these growth conditions also lead to increased cross-linking of peptidoglycan. Overexpression of sltY, E. coli soluble lytic transglycosylase, partially complements the defect in infection of mutant phage particles, allowing them to infect at higher efficiencies. Conversely, an sltY deletion increases the latent period of wild-type phage.     

Purification and characterization of 3-methyladenine DNA glycosylase I from Escherichia coli.

We have purified 3-methyladenine DNA glycosylase I from Escherichia coli to apparent physical homogeneity. The enzyme preparation produced a single band of Mr 22,500 upon sodium dodecyl sulphate/polyacrylamide gel electrophoresis in good agreement with the molecular weight deduced from the nucleotide sequence of the tag gene (Steinum, A.-L. and Seeberg, E. (1986) Nucl. Acids Res. 14, 3763-3772). HPLC confirmed that the only detectable alkylation product released from (3H)dimethyl sulphate treated DNA was 3-methyladenine. The DNA glycosylase activity showed a broad pH optimum between 6 and 8.5, and no activity below pH 5 and above pH 10. MgSO4, CaCl2 and MnCl2 stimulated enzyme activity, whereas ZnSO4 and FeCl3 inhibited the enzyme at 2 mM concentration. The enzyme was stimulated by caffeine, adenine and 3-methylguanine, and inhibited by p-hydroxymercuribenzoate, N-ethylmaleimide and 3-methyladenine. The enzyme showed no detectable endonuclease activity on native, depurinated or alkylated plasmid DNA. However, apurinic sites were introduced in alkylated DNA as judged from the strand breaks formed by mixtures of the tag enzyme and the bacteriophage T4 denV enzyme which has apurinic/apyrimidinic endonuclease activity. It was calculated that wild-type E. coli contains approximately 200 molecules per cell of 3-methyladenine DNA glycosylase I.     

Isolation and partial characterization of a bacteriophage T5 mutant unable to induce thymidylate synthetase and its use in studying the effect of uracil incorporation into DNA on early gene expression.

A mutant of phage T5 which is unable to induce thymidylate synthetase was isolated. T5 thy mutants synthesized less DNA than did wild-type T5, and the burst size of progeny phage was correspondingly reduced two- to threefold in thy+ Escherichia coli. No DNA or progeny phage were made in E. coli thy hosts grown in the absence of exogenous thymine. When the T5 thy mutation was recombined with a T5 dut mutation (unable to induce dUTPase), replication resulted in progeny which contained significant amounts of uracil in their DNA, and these phage failed to produce plaques unless the plating host was deficient in uracil-DNA glycosylase. T5 phage containing various amounts of uracil in their DNA were prepared and used to determine the effect of uracil on the induction of the early enzyme dTMP kinase. The presence of uracil in the parental DNA increased the rate of induction of this enzyme by about 2.5-fold. The T5 thy gene was mapped and is located near the T5 frd gene on the B region of the T5 genome.