Cloning of the Bacillus subtilis recE+ gene and functional expression of recE+ in B. subtilis.

By use of the Bacillus subtilis bacteriophage cloning vehicle phi 105J23, B. subtilis chromosomal MboI fragments have been cloned that alleviate the pleiotropic effects of the recE4 mutation. The recombinant bacteriophages phi 105Rec phi 1 (3.85-kilobase insert) and phi 105Rec phi 4 (3.3-kilobase insert) both conferred on the recE4 strain YB1015 resistance to ethylmethane sulfonate, methylmethane sulfonate, mitomycin C, and UV irradiation comparable with the resistance observed in recE+ strains. While strain YB1015 (recE4) and its derivatives lysogenized with bacteriophage phi 105J23 were not transformed to prototrophy by B. subtilis chromosomal DNA, strain YB1015 lysogenized with either phi 105Rec phi 1 or phi 105Rec phi 4 was susceptible to transformation with homologous B. subtilis chromosomal DNA. The heteroimmune prophages phi 105 and SPO2 were essentially uninducible in strain YB1015. Significantly, both recombinant prophages phi 105Rec phi 1 and phi 105Rec phi 4 were fully inducible and allowed the spontaneous and mitomycin C-dependent induction of a coresident SPO2 prophage in a recE4 host. The presence of the recombinant prophages also restored the ability of din genes to be induced in strains carrying the recE4 mutation. Finally, both recombinant bacteriophages elaborated a mitomycin C-inducible, 45-kilodalton protein that was immunoreactive with Escherichia coli recA+ gene product antibodies. Collectively, these data demonstrate that the recE+ gene has been cloned and that this gene elaborates the 45-kilodalton protein that is involved in SOB induction and homologous recombination.     

Further characterization of SOS system induction in recBC mutants of Escherichia coli

Expression of several SOS functions such as induction of lambda prophage, inhibition of cell division and induction of both umuC and recA genes after UV-irradiation, nalidixic acid or mitomycin C addition was studied in an RecBC- mutant. UV-irradiation and mitomycin C induced all SOS functions studied in the RecBC- cells but at a lower level and delayed with respect to the wild-type strain. On the contrary, nalidixic acid was unable to trigger any of these SOS functions. In the RecBC- mutant, adenine only had a stimulating effect on the amplification of RecA protein synthesis following UV-irradiation. Nevertheless, in the wild-type strain the stimulating effect occurred in all SOS functions studied following UV-irradiation as well as in the amplification of RecA protein synthesis by nalidixic acid but not in the other SOS functions triggered by this compound. Furthermore, adenine produced a decrease in the mitomycin C-mediated induction of all SOS functions studied in both RecBC- and wild-type strains.     

Regulation of expression of the colicin gene of I1 group plasmid TP110.

The control of expression of the colicin Ib gene of the I1 group plasmid TP110 has been investigated. The colicin promoter was fused to the structural gene for beta-galactosidase, using the Mu d(Aprlac) phage, and the plasmid carrying this fusion was introduced into a variety of bacterial strains defective in genes involved in the "SOS" response. Colicin Ib belongs to that group of genes directly controlled by the repressor produced by the lexA gene, and expression was inducible by DNA-damaging agents. Mutations in uvrA, -B, and -C reduced the efficiency of induction by mitomycin C, as did mutations in recB. Mutations in recA and recF effectively prevented induction by mitomycin C, whereas mutations in lexA had contrasting effects, depending upon their effect on the properties of lexA protein. The spr-51 mutation (which inactivates lexA protein) led to constitutive expression, whereas the lexA3 mutation (which makes lexA protein refractory to cleavage by recA protein) completely inhibited inducible expression. In addition to lexA control, a TP110-coded function was identified which appeared able to inhibit colicin expression when the gene responsible was present in high copy number.     

SOS-like induction in Bacillus subtilis: induction of the RecA protein analog and a damage-inducible operon by DNA damage in Rec+ and DNA repair-deficient strains.

We quantitated the induction of the Bacillus subtilis Rec protein (the analog of Escherichia coli RecA protein) and the B. subtilis din-22 operon (representative of a set of DNA damage-inducible operons in B. subtilis) following DNA damage in Rec+ and DNA repair-deficient strains. After exposure to mitomycin C or UV irradiation, each of four distinct rec (recA1, recB2, recE4, and recM13) mutations reduced to the same extent the rates of both Rec protein induction (determined by densitometric scanning of immunoblot transfers) and din-22 operon induction (determined by assaying beta-galactosidase activity in din-22::Tn917-lacZ fusion strains). The induction deficiencies in recA1 and recE4 strains were partially complemented by the E. coli RecA protein, which was expressed on a plasmid in B. subtilis; the E. coli RecA protein had no effect on either induction event in Rec+, recB2, or recM13 strains. These results suggest that (i) the expression of both the B. subtilis Rec protein and the din-22 operon share a common regulatory component, (ii) the recA1 and recE4 mutations affect the regulation and/or activity of the B. subtilis Rec protein, and (iii) an SOS regulatory system like the E. coli system is highly conserved in B. subtilis. We also showed that the basal level of B. subtilis Rec protein is about 4,500 molecules per cell and that maximum induction by DNA damage causes an approximately fivefold increase in the rate of Rec protein accumulation.     

Constitutive SOS expression and damage-inducible AddAB-mediated recombinational repair systems for Coxiella burnetii as potential adaptations for survival within macrophages

Coxiella burnetii , a Gram-negative obligate intracellular pathogen, replicates within an parasitophorous vacuole with lysosomal characteristics. To understand how C. burnetii maintains genomic integrity in this environment, a database search for genes involved in DNA repair was performed. Major components of repair, SOS response and recombination were identified, including recA and ruvABC , but lexA and recBCD were absent. Instead, C. burnetii possesses addAB orthologous genes, functional equivalents to recBCD . Survival after treatment with UV, mitomycin C (MC) or methyl methanesulfonate (MMS), as well as homologous recombination in Hfr mating was restored in Escherichia coli deletion strains by C. burnetii recA or addAB . Despite the absence of LexA, co-protease activity for C. burnetii RecA was demonstrated. Dominant-negative inhibition of C. burnetii RecA by recA mutant alleles, modelled after E. coli recA1 and recA56 , was observed and more apparent with expression of C. burnetii RecAG159D mutant protein. Expression of a subset of repair genes in C. burnetii was monitored and, in contrast to the non-inducible E. coli recBCD , addAB expression was strongly upregulated under oxidative stress. Constitutive SOS gene expression due to the lack of LexA and induction of AddAB likely reflect a unique repair adaptation of C. burnetii to its hostile niche.     

Expression of the SOS system in Escherichia coli growing under nitrate respiration conditions

Induction of several SOS functions by mitomycin C, bleomycin or thermal treatment of a recA441 mutant growing under nitrate respiration conditions was studied in Escherichia coli. Mitomycin C caused inhibition of cell division, induction of prophages and expression of umuC gene but like in aerobically growing cells, it did not trigger the cessation of cell repiration. On the contrary, both recA⁺ and recA441 cultures either treated with bleomycin or incubated at 42°C failed to induce any of the different SOS functions cited above.Furthermore, after bleomycin addition or thermal treatment both recA⁺ and recA441 cultures did not present any variation in the cellular ATP level, contrary to what happens under aerobic growth. The blocking of the expression of some SOS functions under nitrate respiration conditions is not an irreversible process because cells incubated under these anaerobic conditions were able to induce the SOS system when changed to an aerobic medium 30 min after the SOS-inducing treatment had been applied.     

Cloning, sequencing and complementation analysis of the recA gene from Prevotella ruminicola

Abstract Degenerate PCR primers based on conserved RecA protein regions were used to amplify a portion of recE from Prevotella ruminicola strain 23, which was used as a probe to isolate the full-length recA gene from the P. ruminicola genomic library. The P. ruminicola recA gene encoded a protein of 340 amino acids with a molecular mass of 36.81 kDa. P. ruminicola RecA was highly similar to other RecA proteins and most closely resembled that of Bacteroides fragilis (75% identity). It alleviated the methyl methanesulfonate and mitomycin C sensitivities of Escherichia coli recA mutants, but did not restore the resistance to UV-light irradiation. Mitomycin C treatment of otherwise isogenic E. coli strains showed a higher level of prophage induction in a recA harboring lysogen.     

Purification of an SOS repressor from Bacillus subtilis.

We have identified in Bacillus subtilis a DNA-binding protein that is functionally analogous to the Escherichia coli LexA protein. We show that the 23-kDa B. subtilis protein binds specifically to the consensus sequence 5'-GAACN4GTTC-3' located within the putative promoter regions of four distinct B. subtilis DNA damage-inducible genes: dinA, dinB, dinC, and recA. In RecA+ strains, the protein's specific DNA binding activity was abolished following treatment with mitomycin C; the decrease in DNA binding activity after DNA damage had a half-life of about 5 min and was followed by an increase in SOS gene expression. There was no detectable decrease in DNA binding activity in B. subtilis strains deficient in RecA (recA1, recA4) or otherwise deficient in SOS induction (recM13) following mitomycin C treatment. The addition of purified B. subtilis RecA protein, activated by single-stranded DNA and dATP, abolished the specific DNA binding activity in crude extracts of RecA+ strains and strains deficient in SOS induction. We purified the B. subtilis DNA-binding protein more than 4,000-fold, using an affinity resin in which a 199-bp DNA fragment containing the dinC promoter region was coupled to cellulose. We show that B. subtilis RecA inactivates the DNA binding activity of the purified B. subtilis protein in a reaction that requires single-stranded DNA and nucleoside triphosphate. By analogy with E. coli, our results indicate that the DNA-binding protein is the repressor of the B. subtilis SOS DNA repair system.     

Cloning and expression of the Escherichia coli recA gene in Bacillus subtilis

By means of homopolymer dG-dC tailing, using PstI linearized pBR327 as vector, we constructed small plasmids containing the entire Escherichia coli recA gene. The 1.8-kb inserts were recloned in the Bacillus subtilis expression vector pPL608 in a B. subtilis recE4 strain. Analysis of plasmid-coded proteins showed expression of the E. coli recA gene both in minicells and whole cells of B. subtilis. Expression was under control of the bacteriophage SP02 promoter, which is part of pPL608. A recA-expressing plasmid completely abolished the transformation deficiency of the recE4 mutant as well as its sensitivity to mitomycin C (MC). The expressed recA gene also restored recombination in other B. subtilis strains lacking the recE gene product. These results indicate a high similarity between the functions of the E. coli RecA and B. subtilis RecE proteins.     

Suppression of Escherichia coli recF mutations by recA-linked srfA mutations.

Suppressors of recF (srfA) were found by selection for resistance to mitomycin C and UV irradiation in a recB21 recC22 sbcB15 recF143 strain. srfA mutations map in recA and are dominant to srfA+. They suppress both the DNA repair and the recombination deficiencies due to recF mutations. Therefore, RecA protein which is altered by the srfA mutation can allow genetic recombination to proceed in the absence of recB, recC, and recF functions. recF is also required for induction of the SOS response after UV damage. We propose that recF+ normally functions to allow the expression of two recA activities, one that is required for the RecF pathway of recombination and another that is required for SOS induction. The two RecA activities are different and are separable by mutation since srfA mutations permit recombination to proceed but have not caused a dramatic increase in SOS induction in recF mutants. According to this hypothesis, one role for recF in DNA repair and recombination is to modulate RecA activities to allow RecA to participate in these recF-dependent processes.     

No genetic barriers between Salmonella enterica serovar typhimurium and Escherichia coli in SOS-induced mismatch repair-deficient cells

Conjugational crosses trigger SOS induction in Escherichia coli F(-) cells mated with Salmonella enterica serovar Typhimurium Hfr donors. Using an epigenetic indicator of SOS induction, we showed that a strong SOS response occurring in a subpopulation of mated mismatch repair-deficient cells totally abolishes genetic barriers between these two genera.     

Cloning of the recA gene from a free-living leptospire and distribution of RecA-like protein among spirochetes

A recombinant plasmid carrying the recA gene of Leptospira biflexa serovar patoc was isolated from a cosmid library of genomic DNA by complementation of an Escherichia coli recA mutation. The cloned serovar patoc recA gene efficiently restored resistance to UV radiation and methyl methanesulfonate. Recombination proficiency was also restored, as measured by the formation of Lac+ recombinants from duplicated mutant lacZ genes. Additionally, the cloned recA gene increased the spontaneous and mitomycin C-induced production of lambda phage in lysogens of an E. coli recA mutant. The product of the cloned recA gene was identified in maxicells as a polypeptide with an Mr of 43,000. Antibodies prepared against the E. coli RecA protein cross-reacted with the serovar patoc RecA protein, indicating structural conservation. Southern hybridization data showed that the serovar patoc recA gene has diverged from the recA gene of L. interrogans, Leptonema illini, and E. coli. With the exception of the RecA protein of L. interrogans serovar hardjo, the RecA protein of the Leptospira serovars and L. illini were synthesized at elevated levels following treatment of cells with nalidixic acid. The level of detectable RecA correlated with previous studies demonstrating that free-living cells of L. biflexa serovars and L. illini were considerably more resistant to DNA-damaging agents than were those of parasitic L. interrogans serovars. RecA protein was not detected in cells of virulent Treponema pallidum or Borrelia burgdorferi.     

The recE(A)+ gene of B subtilis and its gene product: further characterization of this universal protein

Although the SOS system of E coli and the SOB system of B subtilis share many similarities, there are distinct differences with respect to the regulation and specificity of the phenomena that constitute these global regulons. One of these differences resides in the regulation of the respective RecA and RecA-like proteins. In B subtilis the RecA-like protein, the RecE protein, shares 60% amino acid homology with its E coli counterpart. The E coli recA gene can complement most, but not all, of the functions that are lost in strains of B subtilis that do not produce a functional RecE protein. The DNA sequence of the recE+ gene as well as the sequence of the recE4 allele and the recA73 allele of B subtilis has demonstrated that mutants of the recE and recA loci of this bacterium actually represent alleles of the same complex gene. Accordingly, the major recombination protein of B subtilis should be referred to as RecA and the gene that encodes this protein as recA+.     

Cloning of the recA gene from a free-living leptospire and distribution of RecA-like protein among spirochetes.

A recombinant plasmid carrying the recA gene of Leptospira biflexa serovar patoc was isolated from a cosmid library of genomic DNA by complementation of an Escherichia coli recA mutation. The cloned serovar patoc recA gene efficiently restored resistance to UV radiation and methyl methanesulfonate. Recombination proficiency was also restored, as measured by the formation of Lac+ recombinants from duplicated mutant lacZ genes. Additionally, the cloned recA gene increased the spontaneous and mitomycin C-induced production of lambda phage in lysogens of an E. coli recA mutant. The product of the cloned recA gene was identified in maxicells as a polypeptide with an Mr of 43,000. Antibodies prepared against the E. coli RecA protein cross-reacted with the serovar patoc RecA protein, indicating structural conservation. Southern hybridization data showed that the serovar patoc recA gene has diverged from the recA gene of L. interrogans, Leptonema illini, and E. coli. With the exception of the RecA protein of L. interrogans serovar hardjo, the RecA protein of the Leptospira serovars and L. illini were synthesized at elevated levels following treatment of cells with nalidixic acid. The level of detectable RecA correlated with previous studies demonstrating that free-living cells of L. biflexa serovars and L. illini were considerably more resistant to DNA-damaging agents than were those of parasitic L. interrogans serovars. RecA protein was not detected in cells of virulent Treponema pallidum or Borrelia burgdorferi.     

Induction of the SOS response by hydroxyurea in Escherichia coli K12

Hydroxyurea at concentrations higher than 10(-2) M induced the recA and sfiA genes of E. coli as well as the lambda prophage by a pathway independent of the recBC genes. In addition, the hydroxyurea-mediated induction of the SOS response is accompanied by a recA-dependent decrease on the cellular ATP pool. The presence of the multicopy plasmid pPS2, harboring the nrdAB genes (encoding the ribonucleoside reductase enzyme), abolished the hydroxyurea-induced expression of the recA gene. These data lead us to suggest that induction of the SOS response by hydroxyurea is due to the blocking of DNA replication by the inhibition of the ribonucleoside reductase complex activity.