Repair and recombination of nonreplicating UV-irradiated phage DNA in E. coli III. Enhancement of excision repair in UV-treated bacteria

Summary The question of whether induction of the SOS response in Escherichia coli increases the efficiency of excision repair was addressed by measuring repair of UV-damaged nonreplicating lambda phage DNA in previously irradiated bacteria. Prior UV irradiation of lex ⁺ bacteria enhanced both the rate of regeneration of infective phage DNA (about 10-fold) and the rate of cyclobutane dimer removal early in repressed infections. Indirect induction of SOS-regulated repair activities by the nonreplicating irradiated phage DNA itself seemed negligible. Prior bacterial irradiation reduced the frequency of recombination (loss of a tandem chromosomal duplication) of nonreplicating UV-irradiated DNA. In this respect UV-stimulated recombination of nonreplicating DNA differs from RecF-dependent recombination processes that are stimulated by increased SOS expression.Surprisingly, prior UV irradiation of lexA3 bacteria caused a small but reproducible increase in the regeneration of infective phage DNA.     

Damaged-site independent mutagenesis of phage lambda produced by inducible error-prone repair

The existence of damaged-site independent mutagenesis is confirmed here by scoring the appearance of clear-plaque (c-) or virulent (vir) forward mutations on intact (non-irradiated) phage lambda grown on UV-irradiated E. coli K12 hosts. The mutation frequency was measured as a function of the incubation time between the occurrence of host DNA lesions and phage infection. The time course of mutagenesis of intact phage followed the induction pattern observed upon UV-reactivation of UV-damaged phage by Defais et al. (1976). Intact phage did not mutate in UV-irradiated hosts carrying the uvm-25 mutation known to prevent the occurrence of UV-reactivation. These findings suggest that damaged-site independent mutagenesis results from inducible error-prone repair. Clear-plaque mutations arising on intact phage were mostly found in phage bursts consisting of clear and turbid plaque formers whereas UV-damaged phage gave rise to mostly clear-plaque formers. Contrarily to damaged-site dependent mutagenesis, damaged-site independent mutagenesis can arise even at late times during the phage replication cycle. Our data indicate that about half of the phage mutations that arise upon UV-reactivation are damaged-site independent mutations. Replication of intact phage DNA in a host during induction of SOS functions provides a sensitive assay for the detection of damaged-site independent mutagenesis.     

Indirect induction of SOS functions in Salmonella typhimurium

Infection of non-UV-irradiated cells of Salmonella typhimurium with UV-damaged P22 or KB1 phage induces recA-dependent inhibition of cell division, cell mutagenesis and prophage induction but not inhibition of respiration. On the contrary, respiration and ATP concentration are increased after treatment with UV-damaged phage in both RecA+ and RecA- strains, showing that this increase is not recA-dependent. Furthermore, infection with UV-damaged phage prevents both inhibition of respiration and decrease in ATP level in the UV-irradiated RecA+ strain. This indirect induction of SOS functions is related to degradation of phage DNA as well as to the multiplicity of infection used, suggesting that DNA degradation may play an important role in the mechanism of expression of the SOS system. Our results give also support to the hypothesis that there exists a differentiation in the expression of the various SOS functions.     

Kinetics of induction and decay of error-prone DNA repair activity in Escherichia coli after treatment with nalidixic acid

Inducible error-prone DNA repair activity was detected by infecting nalidixic acid-pretreated E. coli cells with UV-irradiated phage phi X174. Induction and decay kinetics of reactivation very much resembled that of mutagenesis of the UV-damaged phage. Repair as well as mutagenic activity increased for about 30 min. The maximal error-prone repair capacity, which was induced in the cell during the 30 min nalidixic acid treatment, rapidly died out during subsequent cell growth in absence of nalidixic acid. Induction of this repair mode was not observed in a recA- mutant. In the presence of nalidixic acid plus rifampicin both repair and mutagenic effects were abolished.     

Inducible reactivation of UV-irradiated cholera phage e5 in Vibrio cholerae MAK757

Summary The survival of UV-irradiated cholera phage e5 was found to increase when the host cells, Vibrio cholerae MAK757, were exposed to a low dose of UV irradiation before phage infection (Weigle reactivation), indicating the existence of a UV-inducible DNA repair pathway (SOS repair) in V. cholerae MAK757. The induction signal generated by UV irradiation was transient in nature and lasted about 20–30 min at 37°C. Maximal weigle reactivation of the phage was obtained when the host cells were irradiated with a UV dose of 16 J/m². V. cholerae MAK757 was also found to possess efficient photoreactivation and host cell reactivation of UV-damaged DNA in phage e5.     

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.     

Effects of UV irradiation on the fate of 5-bromodeoxyuridine-substituted bacteriophage T4 DNA.

We have carried out a series of experiments designed to characterize the impact of UV irradiation (260 nm) on 5-bromodeoxyuridine-labeled (heavy) T4 bacteriophage, both before and after infection of Escherichia coli. In many respects, these effects differ greatly from those previously described for non-density-labeled (light) phage. Moreover, our results have led us to propose a model for a novel mechanism of host-mediated repair synthesis, in which excision of UV-damaged areas is followed by initiation of replication, strand displacement, and a considerable amount of DNA replication. UV irradiation of 5-bromodeoxyuridine-labeled phage results in single-stranded breaks in a linear, dose-dependent manner (1.3 to 1.5 breaks per genomic strand per lethal hit). This damage does not interfere with injection of the phage genome, but some of the UV-irradiated heavy phage DNA undergoes additional intracellular breakdown (also dose dependent). However, a minority (25%) of the injected parental DNA is protected, maintaining its preinjection size. This protected moiety is associated with a replicative complex of DNA and proteins, and is more efficiently replicated than is the parental DNA not so associated. Most of the progeny DNA is also found with the replicative complex. The 5-bromodeoxyuridine of heavy phage DNA is debrominated by UV irradiation, resulting in uracil which is removed by host uracil glycosylase. Unlike the simple gap-filling repair synthesis after infection with UV-irradiated light phage, the repair replication of UV-irradiated heavy phage is extensive as determined by density shift of the parental label in CsC1 gradients. The newly synthesized segments are covalently attached to the parental fragments. The repair replication takes place even in the presence of chloramphenicol, a protein synthesis inhibitor, suggesting it is host mediated. Furthermore, the extent of the repair replication is greater at higher doses of UV irradiation applied to the heavy phage. This abundant synthesis results ultimately in dispersion of the parental sequences as short stretches in the midst of long segments of newly synthesized progeny DNA. Together, the extensive replication and the resulting distribution pattern of parental sequences, without significant solubilization of parental label, are most consistent with a model of repair synthesis in which the leading strand displaces, rather than ligates to, the encountered 5' end.     

Replacing tryptophan-128 of T4 endonuclease V with a serine residue results in decreased enzymatic activity in vitro and in vivo.

Endonuclease V of bacteriophage T4 possesses two enzymatic activities, a DNA N-glycosylase specific for cyclobutane pyrimidine dimers (CBPD) and an associated apurinic/apyrimidinic (AP) lyase. Extensive structural and functional studies of endonuclease V have revealed that specific amino acids are associated with these two activities. Controversy still exists regarding the role of the aromatic amino acid stretch close to the carboxyl terminus, in particular the tryptophan at position 128. We have expressed wild-type and mutant W128S endonuclease V in Escherichia coli from an inducible tac promoter. Purified W128S endonuclease V demonstrated substantially decreased N-glycosylase (approximately 5-fold) and AP lyase (10- to 20-fold) activities in vitro compared to the wild-type enzyme when a UV-irradiated poly(dA)-poly(dT) substrate was used. However, a much smaller difference in AP lyase activity between the two forms was observed with a site-specific abasic oligonucleotide. The difference in enzymatic activity was qualitatively, but not quantitatively, reflected in the survival of UV-irradiated bacteria, that is the W128S cells were slightly less UV resistant than wild-type cells. No difference was observed in the complementation of UV repair using UV-damaged denV- T4 phage. A more pronounced difference between the wild-type and W128S proteins was observed in human xeroderma pigmentosum group A cells by host-cell reactivation of a UV-irradiated reporter gene. The relatively large discrepancy between the in vitro and in vivo results observed with bacteria may be because saturated levels of DNA repair are obtained in vivo with relatively low levels of endonuclease V. However, under limiting in vitro conditions and in human cells in vivo a considerable difference between the W128S mutant and wild-type endonuclease V activities can be detected. Our results demonstrate that tryptophan-128 is important for endonuclease V activity.     

W-reactivation and W-mutagenesis in UV-irradiated phage phil05 of Bacillus subtilis]

The survival of UV-irradiated phage ?105 on the lawns of several strains of Bacillus subtilis: wild type (strain 168) and 11 recombination-defficient mutants (recA1, recB2, recB3, recB19, recD27, recF15, recF18, recK4, recM13, recL16 and recO61) was investigated. All rec mutants have the phenotype Hcr+, i.e. normally host-cell reactivate UV-damaged phage. Small doses of UV-irradiation given to the wild type (rec+) cells increase the probability of survival of UV-irradiated ?105 phage (W-reactivation) and significantly enhance the frequency of c-mutants (W-mutagenesis). Maximal frequency of clear mutations in conditions of W-mutagenesis is 3-10(-3), i.e. is 100 times higher than the spontaneous background. Various rec mutations of host cells only diminish the level of W-reactivation but do not eliminate it completely. The most deficient in W-reactivation is recD27 mutant. Mutations recB2, B3, B19 and O61 have no effect on W-mutagenesis of UV-irradiated phage ?105 and on UV-induction of ?105, F15,F18 and L16 mutants. UV-irradiation of lysogenic cells of these mutants does not induce ?105 prophage.     

DNA Structures Generated during Recombination Initiated by Mismatch Repair of Uv-Irradiated Nonreplicating Phage DNA in Escherichia Coli: Requirements for Helicase, Exonucleases, and Recf and Recbcd Functions

During infection of homoimmune Escherichia coli lysogens (``repressed infections'), undamaged non-replicating λ phage DNA circles undergo very little recombination. Prior UV irradiation of phages dramatically elevates recombinant frequencies, even in bacteria deficient in UvrABC-mediated excision repair. We previously reported that 80-90% of this UvrABC-independent recombination required MutHLS function and unmethylated d(GATC) sites, two hallmarks of methyl-directed mismatch repair. We now find that deficiencies in other mismatch-repair activities--UvrD helicase, exonuclease I, exonuclease VII, RecJ exonuclease--drastically reduce recombination. These effects of exonuclease deficiencies on recombination are greater than previously observed effects on mispair-provoked excision in vitro. This suggests that the exonucleases also play other roles in generation and processing of recombinagenic DNA structures. Even though dsDNA breaks are thought to be highly recombinagenic, 60% of intracellular UV-irradiated phage DNA extracted from bacteria in which recombination is low--UvrD(-), ExoI(-), ExoVII(-), or RecJ(-)--displays (near-)blunt-ended dsDNA ends (RecBCD-sensitive when deproteinized). In contrast, only bacteria showing high recombination (Mut(+) UvrD(+) Exo(+)) generate single-stranded regions in nonreplicating UV-irradiated DNA. Both recF and recB recC mutations strikingly reduce recombination (almost as much as a recF recB recC triple mutation), suggesting critical requirements for both RecF and RecBCD activity. The mismatch repair system may thus process UV-irradiated DNA so as to initiate more than one recombination pathway.     

Induced reactivity of UV-damaged phage gamma in E. coli K12 host cells treated with aflatoxin B1 metabolites.

The metabolites of aflatoxin B1, the most potent hepatocarcinogen so far known, promote in E. coli K12 cells the reactivation of phage lambda damaged by ultraviolet (UV) radiation. This reactivation process is error prone; 25% of the phage DNA lesions are repaired, but mutagenesis, scored as clear plaque formation, is increased as much as 10-fold. Such reactivation of UV-damaged phage lambda, which occurs in wild-type and in uvrA but not in recA bacteria, is inducible: phage reactivation is obtained even after a long delay following treatment of the host by the short-lived metabolites. This induced reactivation of UV-damaged phage in hosts treated with metabolites of aflatoxin B1 is similar to direct of indirect UV reactivation. Metabolites of aflatoxin B1 produce induced phage reactivation as well as prophage lambda induction in lysogens and cell filamentation in non-lysogens. These cellular events are also triggered by DNA lesions caused by UV radiation and result from the induction of a metabolic pathway (SOS functions). We postulate that, in eucaryotes, carcinogens may induce cellular SOS functions similar to those in E. coli. Induction of such functions might be responsible for the transformation of mammalian cells.     

Weigle reactivation of diploid M13 phage

Summary The limited ability of ultraviolet (UV)-irradiated E. coli cells to W-reactivate UV-irradiated, single-stranded DNA phages fd and M13 was investigated. The kinetics of induction for W-reactivation of UV-irradiated fd phage are different from that for other SOS functions. W-reactivation of UV-irradiated M13 phage was studied using phage particles that contain at least two single-stranded DNA genomes. No effect on the extent of W-reactivation of diploid phage was observed, compared to that of normal haploid phage, indicating that the mechanism of W-reactivation of single-stranded DNA phages does not involve recombination between partially replicated genomes.     

Translesion synthesis is the main component of SOS repair in bacteriophage lambda DNA.

Agents that interfere with DNA replication in Escherichia coli induce physiological adaptations that increase the probability of survival after DNA damage and the frequency of mutants among the survivors (the SOS response). Such agents also increase the survival rate and mutation frequency of irradiated bacteriophage after infection of treated bacteria, a phenomenon known as Weigle reactivation. In UV-irradiated single-stranded DNA phage, Weigle reactivation is thought to occur via induced, error-prone replication through template lesions (translesion synthesis [P. Caillet-Fauquet, M: Defais, and M. Radman, J. Mol. Biol. 117:95-112, 1977]). Weigle reactivation occurs with higher efficiency in double-stranded DNA phages such as lambda, and we therefore asked if another process, recombination between partially replicated daughter molecules, plays a major role in this case. To distinguish between translesion synthesis and recombinational repair, we studied the early replication of UV-irradiated bacteriophage lambda in SOS-induced and uninduced bacteria. To avoid complications arising from excision of UV lesions, we used bacterial uvrA mutants, in which such excision does not occur. Our evidence suggests that translesion synthesis is the primary component of Weigle reactivation of lambda phage in the absence of excision repair. The greater efficiency in Weigle reactivation of double-stranded DNA phage could thus be attributed to some inducible excision repair unable to occur on single-stranded DNA. In addition, after irradiation, lambda phage replication seems to switch prematurely from the theta mode to the rolling circle mode.     

The kinetics of bacterial DNA synthesis during indirect induction of prophage lambda

Summary The possibility that the processes of direct and indirect induction of prophage can be unified on the basis of a temporary inhibition of bacterial DNA synthesis has been examined. The kinetics of DNA synthesis in non-lysogenic bacteria were not significantly affected during a 60 min mating with UV-irradiated ColI drd donor cells. In contrast, direct irradiation of the bacteria with a UV dose which induced phage development with an efficiency similar to that obtained by indirect induction caused an abrupt cessation of DNA synthesis lasting for about 12 min. It is concluded that indirect induction of prophage differs from most treatments which induce directly in that it is not associated with an inhibition of host DNA synthesis.     

Involvement of DNA polymerase alpha in host cell reactivation of UV-irradiated herpes simplex virus.

Aphidicolin is a potent inhibitor of both host cell DNA polymerase alpha and herpes simplex virus (HSV)-induced DNA polymerase but has no effect on DNA polymerases beta and gamma of host cells. By using an aphidicolin-resistant mutant (Aphr) of HSV, a possible involvement of DNA polymerase alpha in host cell reactivation of UV-damaged HSV was studied. Plaque formation by UV-irradiated Aphr was markedly inhibited by 1 microgram of aphidicolin per ml, which did not affect the plating efficiency of nonirradiated Aphr. Aphidicolin added before 12 h postinfection inhibited plaque formation by irradiated Aphr, which became aphidicolin insensitive after 36 h postinfection. The results strongly suggest that host cell DNA polymerase alpha is involved in the repair of UV-irradiated HSV DNA.     

UV-sensitivity and UV-mutability of infectious lambdaDNA: reactivation, protection and mutability in various assay systems

Summary The UV-sensitivity of phage and its infectious DNA have been compared in experiments involving infection of normal cells by phage and transfection of lysozyme-EDTA spheroplasts or Ca⁺⁺-treated cells by phage DNA. It is shown that UV-irradiated DNA undergoes extensive HCR. Since intact phage and free phage DNA have the same survival after UV-irradiation in Hcr^- spheroplasts and cells, resp., and since survival is also identical in Ca⁺⁺-treated Hcr⁺ cells it is concluded that DNA in solution or packaged in the phage head provides the same target for the induction of lethal UV lesions. This conclusion is supported by the observation that cysteamine provides a similar radioprotection to the intact phage and its free DNA. Spheroplasts of Hcr⁺ cells, however, have an HCR capacity reduced by about 20% when compared with normal or Ca⁺⁺-treated cells. Moreover, UV-reactivation of irradiated DNA, which is absent in spheroplasts, occurs efficiently in Ca⁺⁺-treated cells. Possible reasons for the physiological difference between spheroplasts and normal cells are discussed. c-mutations, which are readily induced by UV in phage assayed with E. coli mul ^-, could not be induced in DNA when assayed with spheroplasts or Ca⁺⁺-treated cells of this strain. No mutants were also found with DNA extracted from UV-irradiated phage. The significance of the mode of entry of UV-irradiated DNA into a cell for the production of mutations is discussed.     

The effect of ultraviolet light on the production of bacterial virus protein

The amount of phage-specific protein in T2-infected bacteria growing in a medium containing radiosulfur, S³⁵, has been studied by measuring the radioactivity in specific antiphage serum precipitates of lysates. In the course of normal infection, non-infective phage antigen has been found to make its first intracellular appearance shortly before the end of the eclipse period, in agreement with the findings of Maaløe and Symonds with phage T4. No such phage antigen is produced either in bacteria infected with UV-inactivated T2 or in T2-infected bacteria whose survival as an infective center has been destroyed by UV irradiation during the early stages of the eclipse period. If the infected bacteria are UV-irradiated only at later stages of the eclipse period however, then phage antigenic protein continues to be synthesized in those infected cells in which DNA synthesis and, a fortiori, production of infective progeny have been almost completely suppressed. It is concluded from these results that once the mechanism for formation of phage-specific protein has been established within the infected cell under the influence of the parental DNA, synthesis of phage-specific protein can continue independently of the synthesis of phage DNA. The possibility that the phage DNA controls the specificity of the phage protein indirectly through substances other than DNA is discussed.     

UV-inducible DNA repair in the cyanobacteria Anabaena spp.

Strains of the filamentous cyanobacteria Anabaena spp. were capable of very efficient photoreactivation of UV irradiation-induced damage to DNA. Cells were resistant to several hundred joules of UV irradiation per square meter under conditions that allowed photoreactivation, and they also photoreactivated UV-damaged cyanophage efficiently. Reactivation of UV-irradiated cyanophage (Weigle reactivation) also occurred; UV irradiation of host cells greatly enhanced the plaque-forming ability of irradiated phage under nonphotoreactivating conditions. Postirradiation incubation of the host cells under conditions that allowed photoreactivation abolished the ability of the cells to perform Weigle reactivation of cyanophage N-1. Mitomycin C also induced Weigle reactivation of cyanophage N-1, but nalidixic acid did not. The inducible repair system (defined as the ability to perform Weigle reactivation of cyanophages) was relatively slow and inefficient compared with photoreactivation.