Capacity for postreplication repair correlated with transducibility in Rec- mutants of Bacillus subtilis

Bacillus subtilis strains deficient in transduction, transformation, or both were examined for the ability to remove pyrimidine dimers and to convert deoxyribonucleic acid newly synthesized after ultraviolet irradiation to high molecular weight. In one strain deficient in both recombination processes, short pieces of deoxyribonucleic acid synthesized after irradiation were not converted to high molecular weight. Two transformable strains deficient in transduction were also deficient in postreplication repair (i.e., joining of newly synthesized DNA fragments), whereas a nontransformable strain that was normal in transduction was proficient in postreplication repair. None of the transformable strains showed deficiencies in repair resynthesis or ligase activity. Our results suggest that some recombinational events may be common to transduction and postreplication repair but not to transformation, emphasizing the difference between these two pathways for genetic exchange.     

Radioadaptive enhancement of the repair of UV-induced postreplication gaps in Escherichia coli DNA

Postreplication DNA repair (PRR) in UV-irradiated Escherichia coli WP2 uvrA (tryptophan-dependent strain) and K12 AB1886 uvrA6 pre-irradiated by gamma-rays in low doses (radioadaptation, the first stress effect) has been investigated. PRR was found to be more effective after incubation in the growth medium (for 45-60 min) than in non-radioadapted cells: the repair of postreplication gaps increased by 6-15%. If cells of WP2 uvrA strain were incubated after UV-irradiation in media lacking tryptophan or casamin acids (the second stress effect), PRR was seen to increase as early as within 15 min of incubation and it is more effective than at the first stress. After a 30-60 min incubation the double stress effect leads to an increase in postreplication gap repair by 23-45%. In this case almost all the gaps prove to be repaired. The second stress alone exerts no influence on PPR efficiency. It is supposed that a preliminary radioadaptation may stimulate synthesis of a protein (proteins) of the SOS-response (presumably DNA polymerase V). The second stress effect apparently induces synthesis of an unknown factor (or depreesses synthesis of a MmrA-like protein), and this in cooperation with a protein newly synthesized during radioadaptation significantly increases the efficiency of PPR.     

rec-2-dependent phage recombination in Haemophilus influenzae.

The genetic transformation mutant Rd(DB117)rec- has a pleiotropic phenotype that includes reduced levels of phage recombination. Physical mapping experiments showed that this strain has a 78.5-kbp insertion in the rec-2 gene. The rec-2 dependence of phage recombination was reexamined to determine whether the defective phenotype in Rd(DB117)rec- was due to the simple disruption of the rec-2 gene or whether trans-acting factors from the inserted DNA were responsible. Analysis of strains with transposon insertions in the rec-2 gene showed that they were also defective for phage recombination. Therefore, the phage recombination defect was due solely to the disruption of the rec-2 gene. Strain KB6 is proficient for phage recombination but has a defect in genetic transformation resembling that of Rd(DB117)rec-. The transformation defect of KB6 could be complemented by the wild-type rec-2 gene, showing that the rec-2 contributions to genetic transformation and phage recombination were uncoupled in this strain. The rec-2-dependent phenotype of KB6 suggests that the rec-2 gene participates in genetic transformation and phage recombination in different ways.     

Mechanisms for recF-dependent and recB-dependent pathways of postreplication repair in UV-irradiated Escherichia coli uvrB.

The molecular mechanisms for the recF-dependent and recB-dependent pathways of postreplication repair were studied by sedimentation analysis of DNA from UV-irradiated Escherichia coli cells. When the ability to repair DNA daughter strand gaps was compared, uvrB recF cells showed a gross deficiency, whereas uvrB recB cells showed only a small deficiency. Nevertheless, the uvrB recF cells were able to perform some limited repair of daughter strand gaps compared with a "repairless" uvrB recA strain. The introduction of a recB mutation into the uvrB recF strain greatly increased its UV radiation sensitivity, yet decreased only slightly its ability to repair daughter strand gaps. Kinetic studies of DNA repair with alkaline and neutral sucrose gradients indicated that the accumulation of unrepaired daughter strand gaps led to the formation of low-molecular-weight DNA duplexes (i.e., DNA double-strand breaks were formed). The uvrB recF cells were able to regenerate high-molecular-weight DNA from these low-molecular-weight DNA duplexes, whereas the uvrB recF recB and uvrB recA cells were not. A model for the recB-dependent pathway of postreplication repair is presented.     

Different effects of recJ and recN mutations on the postreplication repair of UV-damaged DNA in Escherichia coli K-12.

Two mutations known to affect recombination in a recB recC sbsBC strain, recJ284::Tn10 and recN262, were examined for their effects on the postreplication repair of UV-damaged DNA. The recJ mutation did not affect the UV radiation sensitivity of uvrB and uvrB recF cells, but it increased the sensitivity of uvrB recN (approximately 3-fold) and uvrB recB (approximately 8-fold) cells. On the other hand, the recN mutation did not affect the UV sensitivity of uvrB recB cells, but it increased the sensitivity of uvrB (approximately 1.5-fold) and uvrB recF (approximately 4-fold) cells. DNA repair studies indicated that the recN mutation produced a partial deficiency in the postreplication repair of DNA double-strand breaks that arise from unrepaired daughter strand gaps, while the recJ mutation produced a deficiency in the repair of daughter strand gaps in uvrB recB cells (but not in uvrB cells) and a deficiency in the repair of both daughter strand gaps and double-strand breaks in uvrA recB recC shcBC cells. Together, these results indicate that the recJ and recN genes are involved in different aspects of postreplication repair.     

Role of DNA polymerase I in postreplication repair: a reexamination with Escherichia coli delta polA.

Using strains of Escherichia coli K-12 that are deleted for the polA gene, we have reexamined the role of DNA polymerase I (encoded by polA) in postreplication repair after UV irradiation. The polA deletion (in contrast to the polA1 mutation) made uvrA cells very sensitive to UV radiation; the UV radiation sensitivity of a uvrA delta polA strain was about the same as that of a uvrA recF strain, a strain known to be grossly deficient in postreplication repair. The delta polA mutation interacted synergistically with a recF mutation in UV radiation sensitization, suggesting that the polA gene functions in pathways of postreplication repair that are largely independent of the recF gene. When compared to a uvrA strain, a uvrA delta polA strain was deficient in the repair of DNA daughter strand gaps, but not as deficient as a uvrA recF strain. Introduction of the delta polA mutation into uvrA recF cells made them deficient in the repair of DNA double-strand breaks after UV irradiation. The UV radiation sensitivity of a uvrA polA546(Ts) strain (defective in the 5'----3' exonuclease of DNA polymerase I) determined at the restrictive temperature was very close to that of a uvrA delta polA strain. These results suggest a major role for the 5'----3' exonuclease activity of DNA polymerase I in postreplication repair, in the repair of both DNA daughter strand gaps and double-strand breaks.     

Effects of chloramphenicol on the postreplication repair and sister recombinational DNA exchanges in ultraviolet-irradiated Micrococcus luteus

The filling of about one third of postreplication DNA gaps in u.v.-irradiated Micrococcus luteus ATCC 4698 is blocked by chloramphenicol (CA) added just before irradiation. Addition of CA 15 min after u.v.-irradiation does not prevent the complete repair of the gaps. U.v.-sensitive M. luteus mutants (ML 6 and ML 15) are identified as defective in different steps of inducible postreplication DNA repair (PRR). PRR in unexcising M. luteus strain G7 is accompanied by the transfer of about 20% of pyrimidine dimers from parental to daughter DNA strands, which indicates the existance of recombinational pathway of PRR. Recombinational PRR in M. luteus is not inhibited by CA.     

Cloning of the rec-2 locus of Haemophilus influenzae

A collection of transposon mutants of Haemophilus influenzae was constructed by additive transformation with mutagenized chromosomal DNA. A rec-2::miniTn10 km mutation was cloned from a transformation-defective member of the mutant collection, followed by the reconstruction of the wild-type rec-2 locus by recombination to create pDM62. Southern blots showed that the commonly studied Rec-2 mutant, Rd(DB117)rec-, contained either a large deletion or a substitution that removed part of rec-2 locus. A collection of transposon mutations in pDM62 was used to characterize the rec-2 locus by complementation. A corresponding collection of mutants was also constructed. A single segment was required to complement the transformation defect in Rd(DB117)rec-. All of the transformation-defective transposon mutants failed to translocate donor DNA into then cell, in agreement with previous studies of Rd(DB117)rec-.     

Dependence of Vegetative Recombination Among Haemophilus influenzae Bacteriophage on the Host Cell

Vegetative recombination of temperature-sensitive mutants of Haemophilus influenzae phage HP1 cl was measured in wild-type H. influenzae strain Rd and in strain DB117, an ultraviolet-sensitive, transformation-defective mutant of the Rd strain. Recombinants are formed with low frequency in wild-type cells, but no recombination was detectable in DB117. It is concluded that these phage make use of the host cell enzymes for vegetative recombination. Lysogenization readily takes place in both strains.     

The involvement of DNA polymerase I in the postreplication repair of ultraviolet radiation-induced damage in Escherichia coli K-12.

Summary A deficiency in DNA polymerase I increased the ultraviolet (UV) radiation sensitivity of a uvrA strain of Escherichia coli K-12 when plated on minimal growth medium. The slope of the survival curve for the uvrA polA strain was 2.0-times greater than that for the uvrA strain. The fluence-dependent yield of unrepaired deoxyribonucleic acid (DNA) parental-strand breaks following UV irradiation and incubation in minimal growth medium was similar in both strains. However, the fluence-dependent yield of unrepaired DNA daughter-strand gaps observed following UV irradiation was 1.8-fold greater in the uvrA polA strain than in the uvrA strain. These results suggest that DNA polymerase I is involved in the filling of at least some daughter-strand gaps during postreplication repair. Also, the uvrA polA strain was sensitized by a post-UV treatment with chloramphenicol (CAP) to a similar extent as was the uvrA strain, indicating that DNA polymerase I is not involved in the CAP-inhibitable pathway of postreplication repair.     

Genetic and kinetic evidence for different types of postreplication repair in Escherichia coli B.

The changes in molecular weight of deoxyribonucleic acid (DNA) synthesized after ultraviolte irradiation of Escherichia coli WP28 uvrA, and strains additionally mutant at polA, exrA, recA, and exrA and polA loci, were examined by alkaline sucrose gradient centrifugation. In a repari=deficient uvrA recA strain, the frequency of breaks in newly synthesized DNA was equal to that for pyrimidine dimers in parental DNA. Measurements of the amounts and rates of postreplication repair of these breaks indicate that (i) repair is two to three times faster when DNA polymerase I is present, although (ii) almost all breaks are repaired regardless of DNA polymerase I activity. (iii) Increased ultraviolet doses lead to an increase in the proportion of breaks remaining unrepaired in uvrA recA, UVRA exrA, and uvrA exrA polA strains. The numbers of unrepaired breaks resemble the numbers expected if repair of one lesion is prevented by proximity of a second lesion.     

Radioadaptive enhancement of the repair of UV-induced postreplication gaps in Escherichia coli cells deficient in DNA repair

In UV-irradiated E. coli WP2 uvrA, deficient in excision repair of DNA with pyrimidine dimers, gamma-irradiation in low doses (radioadaptation) before UV-irradiation leads to the intensification of postreplication repair of DNA. This process in WP2 uvrA polA and uvrA lexA mutants is less than in WP2 uvrA cells, but in WP2 uvrA recA both postreplication repair and its radioadaptive intensification are absent. In E. coli AB1157 excising pyrimidine dimers the radioadaptive intensification of postreplication repair of DNA is expressed almost to the same extent as in WP2 uvrA. In GW2100 umuC mutant, deficient in DNA polymerase V, postreplication repair of DNA is expressed, but its radioadaptive intensification is absent, while in AB2463 recA13 both postreplication repair of DNA and radioadaptive intensification of postreplication repair of DNA are absent. The above data suggest that DNA polymerase I and LexA protein are needed for radioadaptive intensification of postreplication repair of DNA in uvrA strain, and DNA polymerase V is needed for radioadaptive intensification in E. coli AB1157, and that RecA protein is required for postreplication repair and radioadaptive intensification of postreplication repair of DNA.     

A minor pathway of postreplication repair in Escherichia coli is independent of the recB, recC and recF genes

After ultraviolet (UV) irradiation, an Escherichia coli K12 uvrB5 recB21 recF143 strain (SR1203) was able to perform a limited amount of postreplication repair when incubated in minimal growth medium (MM), but not if incubated in a rich growth medium. Similarly, this strain showed a higher survival after UV irradiation if plated on MM versus rich growth medium (i.e., it showed minimal medium recovery (MMR]. In fact, its survival after UV irradiation on rich growth medium was similar to that of a uvrB5 recA56 strain, which does not show MMR or postreplication repair. The results obtained with a uvrB5 recF332::Tn3 delta recBC strain and a uvrB5 recF332::Tn3 recB21 recC22 strain were similar to those obtained for strain SR1203, suggesting that the recB21 and recF143 alleles are not leaky in strain SR1203. The treatment of UV-irradiated uvrB5 recB21 recF143 and uvrB5 recF332::Tn3 delta recBC cells with rifampicin for 2 h had no effect on survival or the repair of DNA daughter-strand gaps. Therefore, a pathway of postreplication repair has been demonstrated that is constitutive in nature, is inhibited by postirradiation incubation in rich growth medium, and does not require the recB, recC and recF gene products, which control the major pathways of postreplication repair.     

Non-mutagenic and mutagenic post-replicative DNA repair in prokaryotic and eukaryotic cells

The review is devoted to mechanisms of repair gaps in DNA daughter strand, formed during the stall of moving replication forks and restart of replication in cells after the action of DNA damaging agents (predominantly--UV light). The repair of daughter DNA, or postreplication DNA repair (PRR), is realized by error-free (non-mutagenic) and error-prone (mutagenic) pathways. The former is a recombination repair, or recombination between two sister duplexes. By this way the major part of postreplication gaps is eliminated. The second way is related with the induction of SOS-response. In Escherichia coli cells mutagenic SOS-response is realized by proteins RecA, UmuD, UmuC, DNA-polymerase III holoenzyme and others. In E. coli some mutagenic enzymes--DNA-polymerase IV (the product of dinB gene) and DNA-polymerase V (the product of umuDC genes) have been recently discovered. In Saccharomyces cerevisiae cells postreplicative translesion synthesis is realized by newly discovered enzymes deoxycytidilmonophosphatetransferase (encoded by REV1 gene), DNA-polymerase zeta (encoded by REV3 gene), DNA-polymerase eta (encoded by RAD30 gene). All the three enzymes share a great homology with UmuC enzyme of E. coli. DNA polymerase eta correctly inserts adenine residues in the daughter strand opposite noncoded thymine residues in cyclobutane pyrimidine dimer. Based on RAD6 gene of S. cerevisiae, human cells hREV1, hREV3 and hRAD30A have been obtained to encode, respectively, deoxycytidiltransferase, DNA-polymerase zeta and DNA-polymerase eta. It has been shown that the defect of PRR DNA in xeroderma pigmentosum variant is associated with DNA-polymerase eta deficiency. This defect is corrected by the extract of intact HeLa cells. The importance of newly discovered enzymes in the system of mechanisms of DNA repair and replication is discussed.     

Postreplication repair of deoxyribonucleic acid and daughter strand exchange in uvr- mutants of Bacillus subtilis

The fate of pyrimidine dimers in deoxyribonucleic acid (DNA) newly synthesized by Bacillus subtilis after ultraviolet irradiation was monitored by use of a damage-specific endonuclease that introduces single-strand breaks adjacent to nearly all of the dimer sites. Two Uvr- strains, one defective in the initiation of dimer excision and the other defective in a function required for efficient dimer excision, were found to be similar to their wild-type parent in the kinetics and extent of converting low-molecular-weight DNA newly synthesized after ultraviolet irradiation to high molecular weight. In the Uvr- strains large molecules of newly synthesized DNA remained susceptible to nicking by the damage-specific endonuclease even after extended incubation in growth medium, whereas the enzyme-sensitive sites were rapidly removed from both preexisting and newly synthesized DNA in Uvr+ cells. Our results support the hypothesis that postreplication repair in bacteria includes recombination between dimer-containing parental DNA strands and newly synthesized strands.     

Characterization of postreplication repair in Saccharomyces cerevisiae and effects of rad6, rad18, rev3 and rad52 mutations

Summary Postreplication repair of nuclear DNA was examined in an excision defective haploid strain of yeast lacking mitochondrial DNA (ral ⁰). The size of the DNA synthesized in cells exposed to various fluences of ultraviolet light (UV) corresponds approximately to the average interdimer distance in the parental DNA. Upon further incubation of cells following exposure to 2.5 J/m², the DNA increases in size; by 4 h, it corresponds to DNA from uniformly labeled cells. The alkaline sucrose sedimentation pattern of DNA pulse labeled at various times after UV irradiation, for up to 4 h, does not change substantially, indicating that dimers continue to block DNA replication. A significant amount of postreplication repair requires de novo protein synthesis, as determined by its inhibition by cycloheximide. The rad6 mutant does not carry out postreplication repair, the rad18 and rad52 mutants show great inhibition while the rev3 mutation does not affect postreplication repair. Both recombinational and nonrecombinational repair mechanisms may function in postreplication repair and most of postreplication repair is error free.     

An analysis of the repair processes in ultraviolet-irradiated Micrococcus luteus using purified ultraviolet-endonuclease

The measurement of the frequency of endonucleolytic incisions in ultraviolet-irradiated DNA serves as the test for the presence of pyrimidine dimers. In accordance with this approach, the lysates of three Micrococcus luteus strains containing radioactively labeled chromosomes were treated with purified M. luteus ultraviolet-endonuclease to trace segregation of dimers amongst parental and newly synthesized DNA and their removal during postreplication and excision DNA repair. A considerable proportion of the dimers in all strains tested proved to be insensitive to the action of exogenous incising enzyme. The use of chloramphenicol as an inhibitor of postirradiation protein synthesis in combination which ultraviolet-endonuclease treatment of DNA allowed to reveal at least two alternative pathways of postreplication repair: constitutively active recombinational pathway and inducible nonrecombinational one.     

Role of the umuC gene in postreplication repair in UV-irradiated Escherichia coli K-12 uvrB

The role of the umuC gene product in postreplication repair was studied in UV-irradiated Escherichia coli K-12 uvrB cells. A mutation at umuC increased the UV radiation sensitivities of uvrB, uvrB recF, uvrB recB, and uvrB recF recB cells; it also increased the deficiencies in the repair of DNA daughter-strand gaps in these strains, but it did not affect the repair of DNA double-strand breaks that arose from unrepaired DNA daughter-strand gaps. We suggest that the umuC gene product is involved in a minor system for the repair of DNA daughter-strand gaps, possibly the repair of overlapping DNA daughter-strand gaps.     

recF-dependent and recF recB-independent DNA gap-filling repair processes transfer dimer-containing parental strands to daughter strands in Escherichia coli K-12 uvrB.

The processes for repairing DNA daughter-strand gaps were studied in UV-irradiated uvrB, uvrB recB, uvrB recF, and uvrB recB recF cells of Escherichia coli K-12. The dimer-containing parental DNA was found to be joined to daughter strands during postreplication repair in all four strains examined. Therefore, both the major (recF-dependent) and the minor (recF recB-independent) gap-filling processes repair DNA daughter-strand gaps by transferring parental strands into daughter strands.     

An analysis of the repair processes in ultraviolet-irradiated Micrococcus luteus using purified ultraviolet-endonuclease

The measurement of the frequency of endonucleolytic incisions in ultraviolet-irradiated DNA serves as the test for the presence of pyrimidine dimers. In accordance with this approach, the lysates of three Micrococcus luteus strains containing radioactively labeled chromosomes were treated with purified M. luteus ultraviolet-endonuclease to trace segregation of dimers amongst parental and newly synthesized DNA and their removal during postreplication and excision DNA repair. A considerable proportion of the dimers in all strains tested proved to be insensitive to the action of exogenous incising enzyme. The use of chloramphenicol as an inhibitor of postirradiation protein synthesis in combination with ultraviolet-endonuclease treatment of DNA allowed to reveal at least two alternative pathways of postreplication repair: constitutively active recombinational pathway and inducible nonrecombinational one.