recA Mutant Cells Research Articles

RecA protein assures fidelity of DNA repair and genome stability in Deinococcus radiodurans

Deinococcus radiodurans is one of the most radiation-resistant organisms known. It can repair hundreds of radiation-induced double-strand DNA breaks without loss of viability. Genome reassembly in heavily irradiated D. radiodurans is considered to be an error-free process since no genome rearrangements were detected after post-irradiation repair. Here, we describe for the first time conditions that frequently cause erroneous chromosomal assemblies. Gross chromosomal rearrangements have been detected in recA mutant cells that survived exposure to 5 kGy γ-radiation. The recA mutants are prone also to spontaneous DNA rearrangements during normal exponential growth. Some insertion sequences have been identified as dispersed genomic homology blocks that can mediate DNA rearrangements. Whereas the wild-type D. radiodurans appears to repair accurately its genome shattered by 5 kGy γ-radiation, extremely high γ-doses, e.g., 25 kGy, produce frequent genome rearrangements among survivors. Our results show that the RecA protein is quintessential for the fidelity of repair of both spontaneous and γ-radiation-induced DNA breaks and, consequently, for genome stability in D. radiodurans. The mechanisms of decreased genome stability in the absence of RecA are discussed.

Roles of ExoI and SbcCD Nucleases in “Reckless” DNA Degradation inrecAMutants ofEscherichia coli

Exponentially growing recA mutant cells of Escherichia coli display pronounced DNA degradation that starts at the sites of DNA damage and depends on RecBCD nuclease (ExoV) activity. As a consequence of this "reckless" DNA degradation, populations of recA mutants contain a large proportion of anucleate cells. We have found that both DNA degradation and anucleate-cell production are efficiently suppressed by mutations in the xonA (sbcB) and sbcD genes. The suppressive effects of these mutations were observed in normally grown, as well as in UV-irradiated, recA cells. The products of the xonA and sbcD genes are known to code for the ExoI and SbcCD nucleases, respectively. Since both xonA and sbcD mutations are required for strong suppression of DNA degradation while individual mutations have only a weak suppressive effect, we infer that ExoI and SbcCD play partially redundant roles in regulating DNA degradation in recA cells. We suggest that their roles might be in processing (blunting) DNA ends, thereby producing suitable substrates for RecBCD binding.

Roles of RecA protein in spontaneous mutagenesis in Escherichia coli

To verify the extent of contribution of spontaneous DNA lesions to spontaneous mutagenesis, we have developed a new genetic system to examine simultaneously both forward mutations and recombination events occurring within about 600 base pairs of a transgenic rpsL target sequence located on Escherichia coli chromosome. In a wild-type strain, the recombination events were occurring at a frequency comparable to that of point mutations within the rpsL sequence. When the cells were UV-irradiated, the recombination events were induced much more sharply than point mutations. In a recA null mutant, no recombination event was observed. These data suggest that the blockage of DNA replication, probably caused by spontaneous DNA lesions, occurs often in normally growing E. coli cells and is mainly processed by cellular functions requiring the RecA protein. However, the recA mutant strain showed elevated frequencies of single-base frameshifts and large deletions, implying a novel mutator action of this strain. A similar mutator action of the recA mutant was also observed with a plasmid-based rpsL mutation assay. Therefore, if the recombinogenic problems in DNA replication are not properly processed by the RecA function, these would be a potential source for mutagenesis leading to single-base frameshift and large deletion in E. coli. Furthermore, the single-base frameshifts induced in the recA-deficient cells appeared to be efficiently suppressed by the mutS-dependent mismatch repair system. Thus, it seems likely that the single-base frameshifts are derived from slippage errors that are not directly caused by DNA lesions but made indirectly during some kind of error-prone DNA synthesis in the recA mutant cells.

The RadB protein from Pyrococcus does not complement E. coli recA mutations in vivo

A previous publication claimed that the radB gene called Pk-REC from Pyrococcus furiosus complemented an E. coli recA mutation. We found that a sequencing error had led to the test of a mutant form of Pk-REC. The wild-type radB gene from P. furiosus cloned in a similar expression vector to the mutant Pk-REC also appeared to complement an E. coli recA mutation. However, the cloned P. furiosus gdh (glutamate dehydrogenase) gene showed the same activity. We therefore concluded that overexpression of any protein can produce an artificial growth inhibition or stationary phase in recA mutant cells, which allows cells to recover from UV damage due to the action of repair systems that do not require RecA-like activity.

Recombinational repair is critical for survival of Escherichia coli exposed to nitric oxide.

Nitric oxide (NO(.)) is critical to numerous biological processes, including signal transduction and macrophage-mediated immunity. In this study, we have explored the biological effects of NO(.)-induced DNA damage on Escherichia coli. The relative importance of base excision repair, nucleotide excision repair (NER), and recombinational repair in preventing NO(.)-induced toxicity was determined. E. coli strains lacking either NER or DNA glycosylases (including those that repair alkylation damage [alkA tag strain], oxidative damage [fpg nei nth strain], and deaminated cytosine [ung strain]) showed essentially wild-type levels of NO(.) resistance. However, apyrimidinic/apurinic (AP) endonuclease-deficient cells (xth nfo strain) were very sensitive to killing by NO(.), which indicates that normal processing of abasic sites is critical for defense against NO(.). In addition, recA mutant cells were exquisitely sensitive to NO(.)-induced killing. Both SOS-deficient (lexA3) and Holliday junction resolvase-deficient (ruvC) cells were very sensitive to NO(.), indicating that both SOS and recombinational repair play important roles in defense against NO(.). Furthermore, strains specifically lacking double-strand end repair (recBCD strains) were very sensitive to NO(.), which suggests that NO(.) exposure leads to the formation of double-strand ends. One consequence of these double-strand ends is that NO(.) induces homologous recombination at a genetically engineered substrate. Taken together, it is now clear that, in addition to the known point mutagenic effects of NO(.), it is also important to consider recombination events among the spectrum of genetic changes that NO(. ) can induce. Furthermore, the importance of recombinational repair for cellular survival of NO(.) exposure reveals a potential susceptibility factor for invading microbes.

Development of simple and efficient protocol for isolation of plasmids from mycobacteria using zirconia beads.

A two-step protocol has been developed for isolation of plasmids from recombinant mycobacteria via Escherichia coli. First either mycobacterial primary transformants or propagated cultures were lysed in a mini-bead beater using zirconia beads and the lysate thus obtained was used to transform E. coli recA mutant cells. Secondly, plasmid DNA was isolated from recombinant E. coli cells and analysed. Bead beating times of 2 min for Mycobacterium smegmatis, a rapid grower, and 4 min for M. bovis BCG, a slow grower, were found to be optimal for recovery of plasmid DNA. This protocol was also amenable to other mycobacterial species such as M. avium, M. fortuitum and M. tuberculosis H37Ra. Plasmid recovery from the recombinant M. bovis BCG using this protocol is approximately 300-fold higher than that reported for the electroduction method.

Annealing vs. invasion in phage lambda recombination.

Genetic recombination catalyzed by lambda's Red pathway was studied in rec+ and recA mutant bacteria by examining both intracellular lambda DNA and mature progeny particles. Recombination of nonreplicating phage chromosomes was induced by double-strand breaks delivered at unique sites in vivo. In rec+ cells, cutting only one chromosome gave nearly maximal stimulation of recombination; the recombinants formed contained relatively short hybrid regions, suggesting strand invasion. In contrast, in recA mutant cells, cutting the two parental chromosomes at non-allelic sites was required for maximal stimulation; the recombinants formed tended to be hybrid over the entire region between the two cuts, implying strand annealing. We conclude that, in the absence of RecA and the presence of non-allelic DNA ends, the Red pathway of lambda catalyzes recombination primarily by annealing.

Stability of linear DNA in recA mutant Escherichia coli cells reflects ongoing chromosomal DNA degradation.

To study the fate of linear DNA in Escherichia coli cells, we linearized plasmid DNA at a specific site in vivo and monitored its behavior in recA mutant cells deficient in recombinational repair. Earlier, we had found that in wild-type (WT) cells linearized DNA is degraded to completion by RecBCD nuclease. We had also found that in WT cells chi sites on linear DNA inhibit RecBCD degradation by turning off its nucleolytic activities. Now we report that chi sites do not work in the absence of the RecA protein, suggesting that RecA is required in vivo to turn off the degradative activities of the RecBCD enzyme. We also report that the degradation of linearized plasmid DNA, even devoid of chi sites, is never complete in recA cells. Investigation of this linear DNA stability indicates that a fraction of recA cells are recBC phenocopies due to ongoing chromosomal DNA degradation, which titrates RecBCD nuclease. A possible role for RecBCD-promoted DNA degradation in controlling chromosomal DNA replication in E. coli is discussed.

RecA protein of Escherichia coli and chromosome partitioning.

Escherichia coli cells deficient in RecA protein frequently contain an abnormal number of chromosomes after completion of ongoing rounds of DNA replication. This suggests that RecA protein may be required for correct timing of initiation of DNA replication; however, we show here that initiation of DNA replication is properly timed in recA mutants. We also find that more than 10% of recA mutant cells contain no DNA. These anucleate cells appear to arise from partitioning of all the DNA into one daughter cell and no DNA into the other daughter cell. Based on these and previously published results, we propose that RecA protein is required for equal partitioning of chromosomes into the two daughter cells.

Synthesis of a Bacillus subtilis small, acid-soluble spore protein in Escherichia coli causes cell DNA to assume some characteristics of spore DNA

Small, acid-soluble proteins (SASP) of the alpha/beta-type are associated with DNA in spores of Bacillus subtilis. Induction of synthesis of alpha/beta-type SASP in Escherichia coli resulted in rapid cessation of DNA synthesis, followed by a halt in RNA and then protein accumulation, although significant mRNA and protein synthesis continued. There was a significant loss in viability associated with SASP synthesis in E. coli: recA+ cells became extremely long filaments, whereas recA mutant cells became less filamentous. The nucleoids of cells with alpha/beta-type SASP were extremely condensed, as viewed in both light and electron microscopes, and immunoelectron microscopy showed that the alpha/beta-type SASP were associated with the cell DNA. Induction of alpha/beta-type SASP synthesis in E. coli increased the negative superhelical density of plasmid DNA by approximately 20%; UV irradiation of E. coli with alpha/beta-type SASP gave reduced yields of thymine dimers but significant amounts of the spore photoproduct. These changes in E. coli DNA topology and photochemistry due to alpha/beta-type SASP are similar to the effects of alpha/beta-type SASP on the DNA in Bacillus spores, further suggesting that alpha/beta-type SASP are a major factor determining DNA properties in bacterial spores.

Cloning of the recA gene of Bordetella pertussis and characterization of its product

A recA gene of Bordetella pertussis was identified in a plasmid library by complementation of a recA mutation in E coli and subcloned as a 2.1-kb Sph I DNA fragment. Southern hybridization experiments showed no similarity to the E coli recA gene, but very strong similarity to other Bordetella species. E coli recA mutant cells containing the B pertussis recA gene at high gene dosage were resistant to DNA-damaging agents such as methyl methane sulfonate or 4-nitroquiline- N-oxide, displayed induction of SOS functions, and were able to promote DNA recombination, but not induction of phage λ. The latter phenotype distinguishes the B pertussis recA gene product from the corresponding proteins from most other Gram-negative organisms. Amino acid sequence comparisons revealed a high degree of structural conservation between prokaryotic RecA proteins.

Effect of UV irradiation on macromolecular synthesis and colony formation in Bacteroides fragilis.

Irradiation of Bacteroides fragilis cells with far-UV light resulted in the immediate, rapid and extensive degradation of DNA which continued for 40 to 60 min after irradiation. During the degradation phase, DNA synthesis was decreased but was never totally inhibited. DNA degradation after irradiation was inhibited by chloramphenicol and caffeine. DNA synthesis in irradiated cells was reduced by chloramphenicol but resumed after 100 min at the same exponential rate as in irradiated cells without chloramphenicol. Irradiated cells continued to synthesize DNA for 40 min in the presence of caffeine but after this time DNA synthesis was completely inhibited and never recovered. RNA and protein synthesis were decreased by UV irradiation and the degree of inhibition was proportional to the UV dose. Colony formation was not affected immediately by UV irradiation and continued for a dose-dependent period before inhibition. There was an inverse relationship between UV dose and inhibition of colony formation which occurred sooner in cells irradiated with lower doses of UV light. The characteristics of DNA synthesis in B. fragilis cells after UV irradiation differ from those in wild-type Escherichia coli cells, where DNA synthesis is stopped immediately by UV irradiation, but resemble those in E. coli recA mutant cells where extensive degradation occurs following UV irradiation.

Identification of the uvrD gene product of Escherichia coli as DNA helicase II and its induction by DNA-damaging agents.

Taking advantage of overproduction of the uvrD protein in cells that harbor multicopy plasmids carrying the uvrD gene, we have purified protein to physical homogeneity. The purified protein possesses single-stranded DNA-dependent ATPase and ATP-dependent DNA unwinding activities, and both activities are equally inactivated by antibodies raised against DNA helicase II. Molecular weight (75,000) and chromatographic properties of the uvrD protein are also similar to those of DNA helicase II and DNA-dependent ATPase I (Richet, E., and Kohiyama, M. (1976) J. Biol. Chem. 251, 808-812; Abdel-Monem, M., Dürwald, H., and Hoffmann-Berling, H. (1977) Eur. J. Biochem. 79, 39-45). Thus, it is concluded that the uvrD protein is identical with DNA helicase II and DNA-dependent ATPase I. Expression of the uvrD gene, as assayed by DNA-dependent ATPase activity, was stimulated by exposure of bacteria to nalidixic acid or mitomycin C. No increase in ATPase activity was observed with recA mutant cells, although basic levels of DNA-dependent ATPase activity in recA+ and recA- strains were almost the same. Thus, the uvrD gene is constitutively expressed but also regulated in a recA-dependent fashion.

Mechanism of conjugation and recombination in bacteria XVI

The formation of mating pairs between F- and Hfr cells resulted in increased sensitivity of recipient deoxyribonucleic acid (DNA) to single-strand-specific S1 nuclease, from 3.6% to 23.5% after 30 min conjugation. A comparable amount of single strand regions in the DNA of mated wild type and recA mutant cells was detected. 10 min of conjugation resulted in almost the same amount of single-strand recipient DNA as 30 min of continuous transfer of donor DNA. Also the transfer of plasmid DNA from F+ recA strain led to the occurrence of single-strand recipient DNA. In similar experiments with Hfr tra mutant no such effect was observed. We conclude that alterations in the sechases of conjugation associated with the formation of mating pairs and/or initiation of transfer donor DNA.