The recA gene of Chlamydia trachomatis: Cloning, sequence, and characterization in Escherichia coli

Abstract The recA gene of Chlamydia trachomatis was isolated by complementation of an Escherichia coli recA mutant. The cloned gene restored resistance to methyl methanesulfonate in E. coli recA mutants. The DNA sequence of the chlamydial gene was determined and the deduced protein sequence compared with other RecA proteins. In E. coli recA deletion mutants, the cloned gene conferred moderate recombinational activity as assayed by Hfr matings. The chlamydial recA gene was efficient in repairing alkylated DNA but less so in repairing of UV damage when compared with the E. coli homologue. As detected by an SOS gene fusion, a small but measurable amount of LexA co-cleavage was indicated.     

Construction and characterization of a Streptomyces rimosus recA mutant: the RecA-deficient strain remains viable

Although previously reported attempts to construct recA null mutants in Streptomyces spp. have been unsuccessful, we have used the suicide plasmid pErmdeltaRecA to inactivate the recA gene in Streptomyces rimosus by gene disruption. pErmdeltaRecA carries the erythromycin resistance gene ermE and a 451-bp fragment of the S. rimosus recA gene (encoding amino acids 2-151). An erythromycin-resistant clone with single plasmid integration into the recA gene on the chromosome was analyzed in detail. This clone possesses one inactive copy of recA which lacks the entire promoter region and the ATG start codon, and a second, truncated gene that encodes only first 151 amino acids of the RecA protein. This S. rimiosus rec A mutant can therefore be considered a completely RecA-deficient strain. The mutant strain is highly sensitive to UV light. Introduction of a plasmid carrying the wild type S. rimosus recA gene completely restored the UV resistance of the recA mutant to wild-type levels. recA genes encoding RecA proteins with short deletions at the C-terminus (21 and 51 amino acids) could not fully rescue the UV sensitivity of the S. rimosus recA strain, when introduced in the same way.     

Cloning and characterization of the Aeromonas caviae recA gene and construction of an A. caviae recA mutant.

A recombinant plasmid carrying the recA gene of Aeromonas caviae was isolated from an A. caviae genomic library by complementation of an Escherichia coli recA mutant. The plasmid restored resistance to both UV irradiation and to the DNA-damaging agent methyl methanesulfonate in the E. coli recA mutant strain. The cloned gene also restored recombination proficiency as measured by the formation of lac+ recombinants from duplicated mutant lacZ genes and by the ability to propagate a strain of phage lambda (red gam) that requires host recombination functions for growth. The approximate location of the recA gene on the cloned DNA fragment was determined by constructing deletions and by the insertion of Tn5, both of which abolished the ability of the recombinant plasmid to complement the E. coli recA strains. A. caviae recA::Tn5 was introduced into A. caviae by P1 transduction. The resulting A. caviae recA mutant strain was considerably more sensitive to UV light than was its parent. Southern hybridization analysis indicated that the A. caviae recA gene has diverged from the recA genes from a variety of gram-negative bacteria, including A. hydrophila and A. sobria. Maxicell labeling experiments revealed that the RecA protein of A. caviae had an Mr of about 39,400.     

Molecular cloning and characterization of the recA gene of Pseudomonas aeruginosa PAO.

The recA gene of Pseudomonas aeruginosa PAO has been isolated and introduced into Escherichia coli K-12. Resistance to killing by UV irradiation was restored in several RecA-E. coli K-12 hosts by the P. aeruginosa gene, as was resistance to methyl methanesulfonate. Recombination proficiency was also restored, as measured by HfrH-mediated conjugation and by the ability to propagate Fec-phage lambda derivatives. The cloned P. aeruginosa recA gene restored both spontaneous and mitomycin C-stimulated induction of lambda prophage in lysogens of a recA strain of E. coli K-12.     

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.     

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.     

Overcoming a defect in generalized recombination in the marine fish pathogen Vibrio anguillarum 775: construction of a recA mutant by marker exchange.

A defect in generalized recombination has prevented the use of marker exchange for the construction of specific chromosomal mutations in the marine fish pathogen Vibrio anguillarum 775. Through the use of large segments of homologous DNA, we were successful in overcoming this defect and used marker exchange to construct a recA mutant of V. anguillarum H775-3. A recombinant cosmid carrying the recA gene of V. anguillarum 775 in the center of a 25-kb cloned DNA insert was isolated by complementation of methyl methanesulfonate (MMS) sensitivity in Escherichia coli HB101. The recA gene was inactivated by inserting a kanamycin resistance gene into recA, and the mutant gene was subsequently introduced into V. anguillarum H775-3 by conjugal mobilization. Isolation of recombinants between cosmid-borne recA::kan sequences and chromosomal DNA was facilitated by the introduction of an incompatible plasmid, and Southern hybridization was used to verify the presence of recA::kan in the chromosomal DNA of the recA mutant. V. anguillarum carrying recA::kan was considerably more sensitive to UV radiation and to MMS than was its parent, and near wild-type levels of resistance to MMS and UV light were restored by introduction of cloned recA genes from both E. coli and V. anguillarum. These results indicate that recA is required for DNA repair in V. anguillarum and demonstrate the utility of this modified marker exchange technique for the construction of mutations in this economically important fish pathogen.     

Influence of disruption of the recA gene on genetic instability and genome rearrangement in Streptomyces lividans.

Streptomyces lividans TK23 gives rise to chloramphenicol-sensitive (Cml(s)) mutants at a frequency of about 0.5%. This is due to the frequent occurrence of very large chromosomal deletions removing the corresponding chloramphenicol resistance gene. A mutant in which the recA gene has been disrupted (S. lividans FrecD3 [G. Muth, D. Frese, A. Kleber, and W. Wohlleben, personal communication]) segregated about 70 times more chloramphenicol-sensitive mutants than the parental strain. An enhancement of the deletion frequency was responsible for this mutator phenotype. The amplifiable locus AUD1 has a duplicated structure in some S. lividans strains and is frequently highly amplified in some mutants generated by genetic instability. The chromosomal AUD1 is not amplified in strain TK23 because of the lack of one duplication. Nevertheless, AUD1-derived amplifiable units presenting the typical duplicated organization amplified very well in TK23 when carried on a plasmid. No amplification of these units was observed in the recA mutant. The ability to amplify was restored when the wild-type recA gene was introduced into the plasmid carrying the amplifiable unit. These results suggest that the RecA protein plays a role in reducing the level of genetic instability and chromosomal deletions and show that the recA gene is necessary to achieve high-copy-number amplification of AUD1.     

Molecular analysis of the Deinococcus radiodurans recA locus and identification of a mutation site in a DNA repair-deficient mutant, rec30

Deinococcus radiodurans strain rec30, which is a DNA damage repair-deficient mutant, has been estimated to be defective in the deinococcal recA gene. To identify the mutation site of strain rec30 and obtain information about the region flanking the gene, a 4.4-kb fragment carrying the wild-type recA gene was sequenced. It was revealed that the recA locus forms a polycistronic operon with the preceding cistrons (orf105a and orf105b). Predicted amino acid sequences of orf105a and orf105b showed substantial similarity to the competence-damage inducible protein (cinA gene product) from Streptococcus pneumoniae and the 2'-5' RNA ligase from Escherichia coli, respectively. By analyzing polymerase chain reaction (PCR) fragments derived from the genomic DNA of strain rec30, the mutation site in the strain was identified as a single G:C to A:T transition which causes an amino acid substitution at position 224 (Gly to Ser) of the deinococcal RecA protein. Furthermore, we succeeded in expressing both the wild-type and mutant recA genes of D. radiodurans in E. coli without any obvious toxicity or death. The gamma-ray resistance of an E. coli recA1 strain was fully restored by the expression of the wild-type recA gene of D. radiodurans that was cloned in an E. coli vector plasmid. This result is consistent with evidence that RecA proteins from many bacterial species can functionally complement E. coli recA mutants. In contrast with the wild-type gene, the mutant recA gene derived from strain rec30 did not complement E. coli recA1, suggesting that the mutant RecA protein lacks functional activity for recombinational repair.     

Molecular cloning and biological characterization of the recA gene from Pseudomonas syringae.

We have identified a recombinant plasmid, pCUV8, from a cosmid library of Pseudomonas syringae genomic DNA which contains a functional analog of the Escherichia coli recA gene. The plasmid was initially identified by its ability to restore UV resistance to E. coli HB101. Quantitative analysis demonstrated that it restored both recombination proficiency and UV resistance to an E. coli recA deletion mutant. By these criteria, pCUV8 appears to contain the P. syringae recA gene. Several pathogenic and epiphytic strains of P. syringae, but not E. coli, showed sequence homology to pCUV8 under normal stringency.     

Construction of an Agrobacterium tumefaciens C58 recA mutant.

Clones encoding the recA gene of Agrobacterium tumefaciens C58 were isolated from a cosmid bank by complementation of an Escherichia coli recA mutation. Subcloning and mutagenesis with the lacZ fusion transposon Tn3HoHo1 located the Agrobacterium recA gene to a 1.3-kilobase segment of DNA. beta-Galactosidase expression from the fusions established the direction in which the gene was transcribed. The gene restored homologous recombination as well as DNA repair functions in E. coli recA mutants. Similar complementation of DNA repair functions was observed in the UV-induced Rec- Agrobacterium mutant, LBA4301. The Agrobacterium recA gene was disrupted by insertion of a cassette encoding resistance to erythromycin, and the mutated gene was marker exchanged into the chromosome of strain NT-1. The resulting strain, called UIA143, was sensitive to UV irradiation and methanesulfonic acid methyl ester and unable to carry out homologous recombination functions. The mutation was stable and had no effect on other genetic properties of the Agrobacterium strain, including transformability and proficiency as a conjugal donor or recipient. Furthermore, strain UIA143 became tumorigenic upon introduction of a Ti plasmid, indicating that tumor induction is independent of recA functions. Sequence homology was detected between the recA genes of strain C58 and E. coli as well as with DNA isolated from agrobacteria representing the three major biochemically differentiated biovars of this genus. In some cases, biovar-specific restriction fragment length polymorphisms were apparent at the recA locus.     

Cloning of the Serratia marcescens recA gene and construction of a Serratia marcescens recA mutant

A recombinant plasmid, pSM2513, containing an 8.5 kb DNA insert was isolated from a genomic library of Serratia marcescens by using interspecific complementation. This plasmid conferred resistance to methyl methanesulphonate and UV irradiation upon recA mutants of Escherichia coli and enhanced recombination proficiency, as measured by Hfr-mediated conjugation, in recA mutants of E. coli. Furthermore, when recA mutants of E. coli harbouring pSM2513 were subjected to UV irradiation, filamentation of the cells was observed. This did not occur upon UV irradiation of the same mutants harbouring the cloning vector alone. These results imply that the S. marcescens recA gene on pSM2513 is functionally similar to the E. coli recA gene in several respects. Restriction enzyme analysis and subcloning studies revealed that the S. marcescens recA gene was located on a 2.7 kb Bg/II-KpnI fragment of pSM2513, and its gene product of approximately 39 kDa resembled the E. coli RecA protein in molecular mass. Using transformation-mediated marker rescue, a recA mutant of S. marcescens was successfully constructed; its proficiency both in homologous recombination and in DNA repair was abolished compared with its parent.     

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.     

Expression of Serratia marcescens extracellular proteins requires recA.

A previously described regulatory mutation which abolishes expression of the extracellular nuclease of Serratia marcescens is shown to be a mutation of the Serratia recA gene. The defect in nuclease expression could be restored by introducing a plasmid carrying the recA gene of Escherichia coli. The DNA sequence of the Serratia gene is very similar to that of the E. coli gene. The putative LexA-binding site of the Serratia recA gene is almost identical to that of E. coli, along with the promoter. A similar LexA-binding site can also be found upstream of the nuclease gene. As expected from this finding, we show that nuclease expression can be induced by SOS-inducing agents such as mitomycin C. Although inducible in S. marcescens, the nuclease was expressed only at the uninduced levels in E. coli and could not be induced by mitomycin C. The extracellular chitinase and lipase were similarly affected by the mutations altering nuclease expression and were also induced by mitomycin C.     

Genetic control of heat resistance and thermotolerance by recA and uvrA in E. coli K12

Several recA and uvrA derivatives of E. coli K12 AB1157 develop a transient increase in heat resistance, i.e. induced thermotolerance after a brief exposure to 43.5 degrees C (less than 1 h). Thermotolerance was identified from the appearance of an inflection in the survival curve or from the loss of heat resistance in the presence of chloramphenicol (CAM) or rifampicin. Heat resistance and induced thermotolerance were enhanced by recA and uvrA gene functions and their contribution was roughly as follows: AB1157 (recA+ uvrA+) greater than AB2463 (recA- uvrA+) greater than AB1886 (recA+ uvrA-) greater than AB2480 (recA- uvrA-). In heat resistance, uvrA and recA contributed approximately equally and their effects were additive. Induced thermotolerance developed sooner and was maintained at a higher level in the presence of uvrA as compared with recA. Since uvrA-dependent excision repair is scheduled prior to recA-dependent (postreplication) repair, induction of thermotolerance may be linked to DNA repair. Although recA and uvrA play a distinct role, they are not essential, and thermotolerance can develop in the absence of either one or both of these gene functions. Furthermore, since thermotolerance can be induced in recA mutants (AB2463 and AB2480), its biochemical pathway must be different from that of the recA-dependent SOS system.     

The Mycobacterium tuberculosis recA intein can be used in an ORFTRAP to select for open reading frames

The DNA repair protein RecA of Mycobacterium tuberculosis contains an intein, a self-splicing protein element. We have employed this Mtu recA intein to create a selection system for successful intein splicing by inserting it into a kanamycin-resistance gene so that functional antibiotic resistance can only be restored upon protein splicing. We then proceeded to develop an ORFTRAP, i.e., a selection system for the cloning of open reading frames (ORFs). The ORFTRAP exploits the self-splicing properties of inteins (which depend on full-length in-frame translation of a precursor protein) by allowing protein splicing to occur when DNA fragments encoding ORFs are inserted into the Mtu recA intein, whereas DNA fragments containing non-ORFs are selected against. Regions of the Mtu recA intein that tolerate the insertion of additional amino acids were identified by Bgl II linker scanning mutagenesis, and a respective construct was chosen as the ORFTRAP. To test the maximum insert size that could be cloned into ORFTRAP, DNA fragments of increasing length from the Listeria monocytogenes hly gene as well as a genomic library of Haemophilus influenzae were inserted and it was found that the longest permissive inserts were 425 bp and 251 bp, respectively. The H. influenzae ORFTRAP library also demonstrated the strength (strong selection power) and weakness (insertion of very small fragments) of the system. Further modifications should make the ORFTRAP useful for protein expression, epitope mapping, and antigen screening.     

Molecular cloning of the recA analog from the marine fish pathogen Vibrio anguillarum 775.

The recA analog from Vibrio anguillarum 775 was isolated by complementation of recA mutations in Escherichia coli, and its protein product was identified. The recA analog promoted recombination between two partially deleted lactose operons, stimulated both spontaneous and mitomycin C-induced phage production in RecA- lambda lysogens, and restored near wild-type levels of resistance to UV radiation and methyl methanesulfonate.