Effect of recB21, uvrD3, lexA101 and recF143 mutations on ultraviolet radiation sensitivity and genetic recombination in delta uvrB strains of Escherichia coli K-12

Recombination Mediator Proteins: Misnomers That Are Key to Understanding the Genomic Instabilities in Cancer

Recombination mediator proteins have come into focus as promising targets for cancer therapy, with synthetic lethal approaches now clinically validated by the efficacy of PARP inhibitors in treating BRCA2 cancers and RECQ inhibitors in treating cancers with microsatellite instabilities. Thus, understanding the cellular role of recombination mediators is critically important, both to improve current therapies and develop new ones that target these pathways. Our mechanistic understanding of BRCA2 and RECQ began in Escherichia coli. Here, we review the cellular roles of RecF and RecQ, often considered functional homologs of these proteins in bacteria. Although these proteins were originally isolated as genes that were required during replication in sexual cell cycles that produce recombinant products, we now know that their function is similarly required during replication in asexual or mitotic-like cell cycles, where recombination is detrimental and generally not observed. Cells mutated in these gene products are unable to protect and process replication forks blocked at DNA damage, resulting in high rates of cell lethality and recombination events that compromise genome integrity during replication.

Interplay of DNA repair, homologous recombination, and DNA polymerases in resistance to the DNA damaging agent 4-nitroquinoline-1-oxide in Escherichia coli

Escherichia coli has three DNA damage-inducible DNA polymerases: DNA polymerase II (Pol II), DNA polymerase IV (Pol IV), and DNA polymerase V (Pol V). While the in vivo function of Pol V is well understood, the precise roles of Pol IV and Pol II in DNA replication and repair are not as clear. Study of these polymerases has largely focused on their participation in the recovery of failed replication forks, translesion DNA synthesis, and origin-independent DNA replication. However, their roles in other repair and recombination pathways in E. coli have not been extensively examined. This study investigated how E. coli's inducible DNA polymerases and various DNA repair and recombination pathways function together to convey resistance to 4-nitroquinoline-1-oxide (NQO), a DNA damaging agent that produces replication blocking DNA base adducts. The data suggest that full resistance to this compound depends upon an intricate interplay among the activities of the inducible DNA polymerases and recombination. The data also suggest new relationships between the different pathways that process recombination intermediates.

Decreased survival of UV-irradiated Staphylococcus aureus in the presence of 8-methoxypsoralen in the post-irradiation plating medium

For Staphylococcus aureus, the presence of 8-methoxypsoralen (8-MOP) in the post-irradiation plating medium increased the lethal effect of far-UV light (FUV; approximately 254 nm) and of 8-MOP plus near-UV light (8-MOP+NUV; approximately 365 nm), an effect similar to that caused by acriflavine which inhibits DNA repair. In the repair-proficient strain, the presence of 8-MOP in the plating medium was almost as effective in inhibiting the repair of damage caused by FUV as that caused by 8-MOP photoadditions. Survival data obtained with Rec(-)-like and Uvr(-)-like strains suggest that 8-MOP in the plating medium, although possibly inhibiting recombination repair, was much more effective in inhibiting excision repair of FUV damage. Regarding 8-MOP+NUV treatment, 8-MOP in the plating medium had a lesser effect in the repair-deficient strains, differing from that observed after FUV treatment, which is consistent with the notion that different types of damage are caused by the two treatments.

Control of crossing over

The Holliday junction is a central intermediate in homologous recombination. It consists of a four-way structure that can be resolved by cleavage to give either the crossover or noncrossover products observed. We show here that the formation of these products is controlled by the E. coli resolvasome (RuvABC) in such way that double-strand break repair (DSBR) leads to crossing over and single-strand gap repair (SSGR) does not lead to crossing over. We argue that the positioning of the RuvABC complex and its consequent direction of junction-cleavage is not random. In fact, the action of the RuvABC complex avoids crossing over in the most commonly predicted situations where Holliday junctions are encountered in DNA replication and repair. Our observations suggest that the positioning of the resolvasome may provide a general biochemical mechanism by which cells can control crossing over in recombination.

The ultraviolet-sensitizing function of plasmid R391 interferes with a late step of postreplication repair in Escherichia coli

The conjugative plasmid R391 increases the UV radiation sensitivity of wild-type, uvrA, and lexA cells of Escherichia coli, but not recA strains. To investigate the UV-sensitizing function of R391, we examined the effect of R391 on the repair of DNA daughter-strand gaps and on the UV radiation sensitivities of various repair and/or recombination-deficient mutants. The presence of R391 did not significantly inhibit the repair of DNA daughter-strand gaps in uvrB cells. The presence of R391 increased the UV radiation sensitivity of uvrA, uvrA recF, uvrB, uvrB recF, uvrB recB, and uvrB ssb-113 cells to UV irradiation, but did not significantly increase the UV radiation sensitivity of uvrA ruvA and uvrA ruvC strains. Based on these results, we propose that the UV-sensitizing activity of R391 acts by inhibiting or interfering with the ruvABC-mediated postsynapsis step of recombinational repair.

Involvement of RecF pathway recombination genes in postreplication repair in UV-irradiated Escherichia coli cells

Mutations affecting the RecF pathway of recombination (recF, recG, recJ, recN, recO, recQ, recR, ruvA, ruvC) were systematically introduced into two sets of strains: (a) uvrA and uvrA recA2020, (b) uvrA recBC sbcBC and uvrA recBC sbcBC recA2020. We examined: (i) the effect of these mutations on the repair of DNA daughter-strand gaps which are produced in the nascent DNA synthesized after UV irradiation, and (ii) the ability of recA2020 (a suppressor for the recF mutation) to suppress the UV radiation sensitivity caused by these mutations. In the uvrA cells, mutations in recF, recR or recO genes produced a major deficiency in the repair of daughter-strand gaps, whereas mutations in recJ, recG, recN, recQ, ruvA or ruvC genes had no effect on the repair of daughter-strand gaps. In both uvrA and uvrA recBC sbcBC backgrounds, the UV radiation sensitivity caused by recF, recG, recR, recO, ruvA, or ruvC mutations was partially suppressed by recA2020, whereas the UV radiation sensitivity caused by recJ, recN, or recQ mutations was not suppressed by recA2020. Partial suppression of the UV sensitivity of recG, ruvA and ruvC mutants was not observed with other suppressors for recF, i.e., recA441, recA720 and recA730. Taken together, these results further support the notion that the recF, recR and recO gene products (abbreviated as RecFOR) function at the same step in recombination repair, possible as a complex. It also suggests that this putative RecFOR complex does not contain proteins encoded by other genes involved in the RecF pathway of recombination.

Cosuppression of recF, recR and recO mutations by mutant recA alleles in Escherichia coli cells

The ability of recA718, recA720, recA730, recA750 and two known recA(Srf) alleles (recA2020 and recA441) to act as suppressors of recF, recR and recO mutations was examined by studying their UV radiation sensitivity in uvrA cells of Escherichia coli. With the exception of recA718, all the mutant recA alleles examined were able to suppress the UV radiation sensitivity caused by recF, recR or recO mutations, but not by the recB mutation. The suppression by recA750 was minimal. The suppression of recF, recR and recO mutations by other recA alleles was more pronounced, but none of them could exert full suppression. Heterozygotes containing a mutant recA allele (recA720, recA730 or recA441) and recA2020 (or recA803, another known recA(Srf) allele) failed to produce any additive or synergistic suppression of recF, indicating that these suppressors did not use different mechanisms for their suppression. Similar to a requirement of recJ+ in the suppression of recF, the suppression of recR and recO mutations by mutant recA alleles also required recJ+. The similar phenotypes conferred by recF, recR, and recO mutations and the observations that a number of mutant recA alleles can cosuppress these three mutations suggest that the recF, recR and recO gene products may function together as a complex.

A plant cDNA that partially complements Escherichia coli recA mutations predicts a polypeptide not strongly homologous to RecA proteins

A plant (Arabidopsis thaliana) cDNA previously selected for its ability to partially complement the UV sensitivity of Escherichia coli RecA-UvrC-Phr- mutants and designated DRT100 (DNA-damage repair/toleration) was subcloned into a high-copy-number plasmid and expressed via a bacterial promotor. It increased resistance of RecA-UvrB-Phr- bacteria to mitomycin C and methyl methanesulfonate as well as to UV light. This lack of specificity, and its ability to increase resistance in both UvrB- and UvrC- mutants, suggested that Drt100 activity might be complementing RecA- phenotypes. DRT100 partially complemented three RecA- phenotypes thought to reflect deficiencies in homologous recombination--namely, inability to plate lambda red-gam- phages and P1 phages and to recombinationally integrate donor DNA during conjugal crosses--but did not complement inability to induce E. coli SOS functions. The 395-amino acid DRT100 open reading frame encodes an apparent N-terminal chloroplast transit peptide and a putative 322-residue mature protein with a conserved nucleotide binding motif, but otherwise little global homology with bacterial RecA proteins. There are several tandemly repeated leucine-rich motifs. DNA from two closely related plants, but not from maize, hybridized strongly to a DRT100 cDNA probe.

Similar-sized daughter-strand gaps are produced in the leading and lagging strands of DNA in UV-irradiated E. coli uvrA cells

The nascent DNA synthesized after UV irradiation contained discontinuity, i.e., daughter-strand gaps. The sizes of these gaps produced in the leading and lagging strands of UV-irradiated Escherichia coli cells were determined by using strand-specific DNA probes. The DNA isolated from irradiated uvrA delta(lac-pro) cells was hybridized with the 32P-labeled single-stranded DNA probes. After digestion with S1 nuclease, the sizes of the bound radioactive DNA fragments were determined by electrophoresis in an alkaline agarose gel. It was found that the average size of gaps produced in the leading strand was about 0.12 kb, whereas those produced in the lagging strand was slightly smaller than 0.12 kb. No gaps larger than 0.5 kb were detected.

Effect of rec mutations on viability and processing of DNA damaged by methylmethane sulfonate in xth nth nfo cells of Escherichia coli

The role of recombination genes in the processing of DNA damaged by methlymethane sulfonate (MMS) was examined in an xth nth nfo strain of Escherichia coli K-12. Introduction of a recQ mutation did not increase the cell's sensitivity to MMS treatment. The presence of recF, recJ or recN mutation slightly increased the cell's sensitivity to MMS treatment. The introduction of recA or recB mutation into the cells led to inviability. Taken together, we suggest that replication of DNA containing apurinic/apyrimidinic (AP) sites in vivo will lead to the formation of secondary lesions. The repair of these secondary lesions requires the function of recA and recB genes, but does not appear to require recF, recJ, recQ or recN genes.

Purification and preliminary characterization of the Escherichia coli K-12 recF protein

The recF gene of Escherichia coli is known to encode an Mr-40,000 protein that is involved in DNA recombinationa nd postreplication DNA repair. To characterize the role of the recF gene product in these processes, the recF gene was cloned downstream of a tac promoter to facilitate overproduction of the recF gene product. The RecF protein was overproduced and purified to apparent homogeneity. N-terminal protein sequence analysis demonstrated that the purified protein had the sequence that was predicted from the DNA sequence of the recF gene, except that the predicted N-terminal Met was not present. The RecF protein bound to single-stranded oligonucleotides in filter binding and gel filtration assays. Maximal binding required 2 to 3 min of incubation at 37 degrees C; the binding reaction had a pH optimum of 7.0, did not require divalent cations, and was inhibited by NaCl concentrations of greater than 250 mM. The Kd of RecF protein binding to a 59-base single-stranded oligonucleotide was on the order of 1.3 X 10(-7) M, and the reaction did not show cooperativity. Experiments measuring the binding to various DNA substrates and competition binding experiments with different DNA molecules demonstrated that RecF protein binds preferentially to single-stranded, linear DNA molecules.

Cellular role of DNA polymerase I

Escherichia coli possesses three well-established DNA polymerases, I, II, and III. DNA polymerase I (Pol I) is the main repair polymerase in E. coli and also has a minor but important role in chromosomal replication. A major advantage of Pol I as an experimental system is its simplicity; unlike other replication enzymes, it is active as a single subunit. To a large extent, mutagenesis appears to be the result of (dis)functions of the DNA replication machinery. It is the purpose of this review to provide an integrated view of this relationship with particular emphasis on the role of Pol I in mutagenic events.

Discontinuous DNA replication in a lig-7 strain of Escherichia coli is not the result of mismatch repair, nucleotide-excision repair, or the base-excision repair of DNA uracil

After pulse-labeling with 3H-thymidine for 30 s at 42 degrees C, the newly-synthesized DNA from uvrB5 lig-7, uvrB5 lig-7 ung-1 (or ung152), uvrB5 lig-7 mutL218 (or mutS215), and uvrB5 lig-7 ung-1 mutL218 (or mutS215) cells sedimented very slowly in alkaline sucrose gradients. The bulk of these DNA molecules were smaller than 2,000 nucleotides long (i.e., about the size of Okazaki fragments), and none of the 3H-radioactivity was found to sediment as high-molecular-weight DNA. These results indicate that the apparent discontinuous DNA replication observed in lig-7 strains is not the result of mismatch repair, nucleotide-excision repair, or the base-excision repair of DNA uracil.

Role of ruvAB genes in UV- and gamma-radiation and chemical mutagenesis in Escherichia coli

Escherichia coli umuC122::Tn 5 was mutagenized with N-methyl-N'-nitro-N-nitrosoguanidine to isolate mutations that block the residual gamma-radiation mutagenesis observed in umuC strains. Two of these mutations were shown by transductional mapping and plasmid complementation to map in the ruvA and ruvB genes (i.e., ruvA200 and ruvB201). Whereas ruvA200 was complemented by ruvA+ plasmids, the only other known ruvA mutation, ruvA59::Tn10 required both the ruvA+ and ruvB+ genes to show complementation. The ruvA200, ruvB201, ruvA59::Tn10 and ruvB60::Tn10 mutations all reduced gamma-radiation-induced ochre reversion [argE3(Oc)----Arg+] to about 30% of the wild-type level, and they all reduced UV-radiation-induced ochre reversion to about 15% of the wild-type level. The ruvA200 and ruvB201 mutants also showed reduced gamma- and UV-radiation mutagenesis with two other assays [hisG4(Oc)----His+ and Rifs----Rifr]. Streptozotocin mutagenesis (Rifr) was reduced to about half of the wild-type level in ruv strains, but ethyl methanesulfonate mutagenesis was normal. While the umuC strain did not show the oxygen enhancement of gamma-radiation mutagenesis, the ruvA200 strain showed an oxygen effect that was similar to that shown by the wild-type strain. When the ruvA200 mutation was combined with the umuC mutation, gamma-radiation mutagenesis was further reduced to 5% of the wild-type level and cells showed a synergistic sensitization to UV- and gamma-radiation-induced killing. A mutational spectrum analysis indicates a general depression of both umuC-dependent and umuC-independent gamma-radiation mutagenesis in the ruvA strain, which is in contrast with the site-specific reduction in gamma-radiation mutagenesis that is observed in the umuC mutant. The reduced radiation mutagenesis in the ruvA strain could not be correlated with a reduction in transcription of the recA or umuC genes.

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.

recA-dependent DNA repair in UV-irradiated Escherichia coli

UV-radiation-induced lesions in DNA result in the formation of excision gaps, daughter-strand gaps (DSG) and double-strand breaks (DSB), which are repaired by several different mechanisms. Postreplication repair. The recA gene is a master gene that controls all of the pathways of postreplication repair. The repair of DSG proceeds by one pathway that is also recF dependent, and one pathway that is constitutive and independent of the recF and recBC genes. A small fraction of the recF recB-independent repair of DSG is dependent upon the umuC gene, and may define an error-prone pathway of postreplication repair. Unrepaired DSG can be converted to DSB, which are normally repaired by the RecBCD pathway. However, in the recBC sbcB background, these DSB are repaired by a recF-dependent process. The RecF pathways of postreplication repair appear to utilize DNA containing a single-stranded region (either a gap or a DSB with a single-stranded end), while the RecBCD pathway appears to utilize the blunt ends of duplex DNA to promote the recombinational repair of DSB. The polA gene (especially the 5'----3' exonuclease activity of DNA polymerase I) functions in pathways of postreplication repair (both for the repair of DSG and DSB) that are largely independent of the recF gene. Nucleotide excision repair. The repair of excision gaps is independent of the recA gene in cells with unreplicated chromosomes, but is recA dependent in cells with partially replicated chromosomes at the time of UV irradiation. This recA-dependent repair of excision gaps appears to be analogous to the recF- and recB-dependent pathways of postreplication repair, i.e. the RecF pathway repairs DNA gaps, and the RecBCD pathway repairs the DSB that arise at unrepaired gaps.

recA (Srf) suppression of recF deficiency in the postreplication repair of UV-irradiated Escherichia coli K-12

The mechanism by which recA (Srf) mutations (recA2020 and recA801) suppress the deficiency in postreplication repair shown by recF mutants of Escherichia coli was studied in UV-irradiated uvrB and uvrA recB recC sbcB cells. The recA (Srf) mutations partially suppressed the UV radiation sensitivity of uvrB recF, uvrB recF recB, and uvrA recB recC sbcB recF cells, and they partially restored the ability of uvrB recF and uvrA recB recC sbcB recF cells to repair DNA daughter-strand gaps. In addition, the recA (Srf) mutations suppressed the recF deficiency in the repair of DNA double-strand breaks in UV-irradiated uvrA recB recC sbcB recF cells. The recA2020 and recA801 mutations do not appear to affect the synthesis of UV radiation-induced proteins, nor do they appear to produce an altered RecA protein, as detected by two-dimensional gel electrophoresis. These results are consistent with the suggestion (M. R. Volkert and M. A. Hartke, J. Bacteriol. 157:498-506, 1984) that the recA (Srf) mutations do not act by affecting the induction of SOS responses; rather, they allow the RecA protein to participate in the recF-dependent postreplication repair processes without the need of the RecF protein.

Role of the radB gene in postreplication repair in UV-irradiated Escherichia coli uvrB

In UV-irradiated Escherichia coli, the radB101 mutation sensitized uvrB recF cells 4-fold and uvrB recB cells 1.2-fold, but did not sensitize uvrB recB recF cells. The radB mutation had very little effect (1.2-fold or less) on the repair of UV radiation-induced DNA daughter-strand gaps in uvrB cells, but it did cause about a 3-fold deficiency in the repair of the DNA double-strand breaks that arise in association with nonrepaired daughter-strand gaps in UV-irradiated uvrB recF cells. Thus, the radB gene does not appear to be involved in the recF-dependent or recF recB-independent processes for the repair of DNA daughter-strand gaps, but is involved in the recB-dependent postreplication repair of DNA double-strand breaks.

Repair of DNA double-strand breaks in UV-irradiated Escherichia coli uvrB recF cells is inhibited by rich growth medium

Ultraviolet (UV)-irradiated uvrB recF and uvrB recB cells of Escherichia coli K-12 showed similar radiation sensitivities when plated on minimal growth medium (MM), however, the uvrB recF cells were much more UV radiation-sensitive than the uvrB recB cells when plated on rich growth medium. Sedimentation analysis of the DNA from UV-irradiated uvrB recF cells suggests that the rich medium killing of uvrB recF cells is due to the inhibition of the repair of UV-radiation-induced DNA double-strand breaks, i.e., the killing is due to the inhibition of the recB-dependent pathway of postreplication repair. Furthermore, we demonstrated that the DNA double-strand breaks that were formed in UV-irradiated uvrB recA200(Ts) cells incubated at 42 degrees C in rich growth medium were not repaired whether the medium during subsequent repair incubation at 30 degrees C was MM or rich growth medium, while DNA double-strand breaks that were formed in MM at 42 degrees C could be repaired in MM or in rich growth medium at 30 degrees C. How the absence of an abrupt slowing of DNA synthesis when UV-irradiated cells are held in rich growth medium (Sharma and Smith, 1985b) may prevent the repair of these DNA double-strand breaks is discussed.

Inviability of dam recA and dam recB cells of Escherichia coli is correlated with their inability to repair DNA double-strand breaks produced by mismatch repair

The molecular basis for the inviability of dam-3 recA200(Ts) and dam-3 recB270(Ts) cells was studied. The dam-3 recA200(Ts) cells were inviable in yeast extract-nutrient broth or in minimal medium at 42 degrees C. Although the dam-3 recB270(Ts) cells were inviable in yeast extract-nutrient broth at 42 degrees C, they were viable at 42 degrees C in minimal medium, in which the high salt content suppresses the mutant phenotype caused by the recB270(Ts) mutation at 42 degrees C. Under the growth conditions rendering dam rec cells inviable, the cells accumulated double-strand breaks in their DNA. Introduction of a mutL or mutS mutation restored the viability of dam-3 recB270(Ts) cells grown in yeast extract-nutrient broth at 42 degrees C and eliminated the formation of DNA double-strand breaks in these cells. We conclude that the inability to repair DNA double-strand breaks produced by the mismatch repair process accounts for the inviability of the dam recA and dam recB cells.

Postreplicational formation and repair of DNA double-strand breaks in UV-irradiated Escherichia coli uvrB cells

The number of DNA double-strand breaks formed in UV-irradiated uvrB recF recB cells correlates with the number of unrepaired DNA daughter-strand gaps, and is dependent on DNA synthesis after UV-irradiation. These results are consistent with the model that the DNA double-strand breaks that are produced in UV-irradiated excision-deficient cells occur as the result of breaks in the parental DNA opposite unrepaired DNA daughter-strand gaps. By employing a temperature-sensitive recA200 mutation, we have devised an improved assay for studying the formation and repair of these DNA double-strand breaks. Possible mechanisms for the postreplication repair of DNA double-strand breaks are discussed.

Mechanism of sbcB-suppression of the recBC-deficiency in postreplication repair in UV-irradiated Escherichia coli K-12

The mechanism by which an sbcB mutation suppresses the deficiency in postreplication repair shown by recB recC mutants of Escherichia coli was studied. The presence of an sbcB mutation in uvrA recB recC cells increased their resistance to UV radiation. This enhanced resistance was not due to a suppression of the minor deficiency in the repair of DNA daughter-strand gaps or to an inhibition of the production of DNA double-strand breaks in UV-irradiated uvrA recB recC cells; rather, the presence of an sbcB mutation enabled uvrA recB recC cells to carry out the repair of DNA double-strand breaks. In the uvrA recB recC sbcB background, a mutation at recF produced a huge sensitization to UV radiation, and it rendered cells deficient in the repair of both DNA daughter-strand gaps and DNA double-strand breaks. Thus, an additional sbcB mutation in uvrA recB recC cells restored their ability to perform the repair of DNA double-strand breaks, but the further addition of a recF mutation blocked this repair capacity.

A mechanism for rich-medium inhibition of the repair of daughter-strand gaps in the deoxyribonucleic acid of UV-irradiated Escherichia coli K12 uvrA

Ultraviolet-irradiated Escherichia coli K12 uvrA(B,C) cells show higher survival if plated on minimal growth medium (MM) rather than on rich growth medium (RM). This phenomenon has been referred to as 'minimal medium recovery' (MMR). UV-irradiated (4 J/m2) uvrA cells showed a similar rate of protein synthesis, whether incubated in MM or RM, however, they showed a severe depression in DNA synthesis when incubated in MM that lasted for about 30 min, and the normal rate of DNA synthesis was not reestablished until about 60 min after irradiation. When a sample of these same cells was switched to RM immediately after UV-irradiation, there was only a slight slowing of DNA synthesis, and the normal rate of synthesis was reestablished by 60 min. An additional mmrA mutation or growth retardation by valine blocked both this extra DNA synthesis in RM, and the inhibitory effect of RM on survival. These findings suggest that the absence of a marked delay in DNA synthesis observed in RM may be responsible for the inhibitory effect of RM on the survival of UV-irradiated excision-deficient cells. Two hypotheses, which are not mutually exclusive, are proposed and supported by data to explain why a fast rate of DNA synthesis after UV-irradiation partially inhibits postreplication repair and enhances cell lethality.

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.

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.

New mutation (mmrA1) in Escherichia coli K-12 that affects minimal medium recovery and postreplication repair after UV irradiation

After UV irradiation, Escherichia coli uvrA mutant cells show higher survival on minimal than on rich growth medium, i.e., they show minimal-medium recovery. This effect of rich growth medium on survival is not observed in a uvrA mutant carrying an mmrA1 mutation, and the uvrA mmrA strain showed the same survival rate on minimal and rich growth media as the uvrA strain did on minimal medium plates. The mmrA1 mutation was isolated as a hidden mutation from a uvrA polA mutant strain and shown to map at 84.3 min on the E. coli K-12 linkage map. In contrast to the uvrA strain, the repair of DNA daughter strand gaps was not inhibited in the uvrA mmrA strain by rich growth medium after irradiation. However, the uvrA and uvrA mmrA strains were similar in their ability to repair DNA when compared in minimal medium. These data are consistent with the idea that the mmr gene product is not involved directly in the repair of UV radiation-induced DNA damage, but rather allows rich growth medium to inhibit a portion of postreplication repair.

Effects of the ssb-1 and ssb-113 mutations on survival and DNA repair in UV-irradiated delta uvrB strains of Escherichia coli K-12

The molecular defect in DNA repair caused by ssb mutations (single-strand binding protein) was studied by analyzing DNA synthesis and DNA double-strand break production in UV-irradiated Escherichia coli delta uvrB strains. The presence of the ssb-113 mutation produced a large inhibition of DNA synthesis and led to the formation of double-strand breaks, whereas the ssb-1 mutation produced much less inhibition of DNA synthesis and fewer double-strand breaks. We suggest that the single-strand binding protein plays an important role in the replication of damaged DNA, and that it functions by protecting single-stranded parental DNa opposite daughter-strand gaps from nuclease attack.