Quantification of RecA protein in Deinococcus radiodurans reveals involvement of RecA,but not LexA,in its regulation

RecA protein is essential for the very high level of resistance of Deinococcus radiodurans to DNA damage induced by ionizing radiation or other DNA-damaging agents. Since the mechanism(s) involved in the control of recA expression and the extent of RecA induction following DNA damage in this species are still unclear, we have performed a genetic analysis of the recA locus and quantified the basal and induced levels of RecA protein in wild type, recA, and lexA mutants. We found that the two genes upstream of recA in the predicted cinA ligT recA operon appear to have no role in the regulation of recA expression or function, despite the fact that the reading frames in the operon overlap. By using a translational fusion of recA to a lacZ reporter gene, we showed that induction began with no delay following exposure to gamma-radiation or treatment with mitomycin, and continued at a constant rate until it reached a plateau. The induction efficiency increased linearly with inducer dose, levelling off at a concentration fourfold above the background. The basal concentration of RecA protein measured by Western blotting corresponded to approximately 11,000 monomers per cell, and the induced concentration to around 44,000 monomers per cell. These levels remained unchanged upon disruption of the lexA gene, indicating that LexA does not plays a role in recA regulation. However, inactivation of lexA caused cells to aggregate, suggesting that LexA may control the activity or expression of as yet undefined membrane functions. Cells bearing the recA670 mutation showed an elevated constitutive expression of recA in the absence of DNA damage. This phenotype did not result from the defect in DNA repair associated with the RecA670 protein, since the increased basal level of recA expression was also found in recA670/ recA(+) diploid cells that are proficient in DNA repair. These results suggest that RecA may be involved in regulating its own expression, possibly by stimulating proteolytic modification of other regulatory proteins.     

单增李斯特菌生物膜形成调控机制的研究进展

单增李斯特菌是一种重要的食源性病原菌。单增李斯特菌的分布和存活与其形成生物膜的能力有关,生物膜对逆性环境有抵抗力,细菌会从生物膜中分离导致食品持续性的污染。生物膜的形成、成熟和结构取决于多种外部和内部因素,并且多种调控机制起着重要作用。文中旨在阐述单增李斯特菌生物膜形成过程中的调控机制(包括胞内作用、胞间作用和种间作用),以控制食品加工环境中致病性生物膜的形成,从而为食品安全提供新的干预策略。     

Construction and characterization of Bordetella pertussis RecA− mutants

Abstract Antibiotic drug-resistance cassettes (DRCs) were used to insertionally inactivate the wild-type Bordetella pertussis recA gene cloned into a suicide vector. The mutant allele was mobilized by conjugal gene transfer from Escherichia coli strain SM10 into different genetic backgrounds of B. pertussis . Southern hybridization studies of one of these mutants showed that it contained a DRC integrated within a recA gene situated within a Cla I genomic DNA fragment. Selected mutants were assayed to quantify recombinational and DNA repair deficiencies. These mutants were shown to be highly sensitive to both chemically and physically induced DNA damage. Gene transfer studies of another RecA⁻ mutant also indicated that it was defective in intergenic recombination. No difference in hemolytic activity or production of capsule was detected between the RecA⁻ mutants and their corresponding wild-type strains. The results of this investigation corroborate previous studies with the cloned B. pertussis recA gene, and demonstrate that the expression of the B. pertussis recA gene in the original host promotes both DNA repair and recombination.     

The majority of inducible DNA repair genes in Mycobacterium tuberculosis are induced independently of RecA

In many species of bacteria most inducible DNA repair genes are regulated by LexA homologues and are dependent on RecA for induction. We have shown previously by analysing the induction of recA that two mechanisms for the induction of gene expression following DNA damage exist in Mycobacterium tuberculosis. Whereas one of these depends on RecA and LexA in the classical way, the other mechanism is independent of both of these proteins and induction occurs in the absence of RecA. Here we investigate the generality of each of these mechanisms by analysing the global response to DNA damage in both wild-type M. tuberculosis and a recA deletion strain of M. tuberculosis using microarrays. This revealed that the majority of the genes that were induced remained inducible in the recA mutant stain. Of particular note most of the inducible genes with known or predicted functions in DNA repair did not depend on recA for induction. Amongst these are genes involved in nucleotide excision repair, base excision repair, damage reversal and recombination. Thus, it appears that this novel mechanism of gene regulation is important for DNA repair in M. tuberculosis.     

Efficient repair of hydrogen peroxide-induced DNA damage by Escherichia coli requires SOS induction of RecA and RuvA proteins

The survival of Escherichia coli following treatment with a low dose (1-3 mM) of hydrogen peroxide (H(2)O(2)) that causes extensive mode-one killing of DNA repair mutants is stimulated by the induction of the SOS regulon. Results for various mutants indicate that induction of recA and RecA protein-mediated recombination are critical factors contributing to the repair of H(2)O(2)-induced oxidative DNA damage. However, because DNA damage activates RecA protein's coprotease activity essential to cleavage of LexA repressor protein and derepression of all SOS genes, it is unclear to what extent induction of RecA protein stimulates this repair. To make this determination, we examined mode-one killing of DeltarecA cells carrying plasmid-borne recA (P(tac)-recA(+)) and constitutively expressing a fully induced level of wild-type RecA protein when SOS genes other than recA are non-inducible in a lexA3 (Ind(-)) genetic background or inducible in a lexA(+) background. At a H(2)O(2) dose resulting in maximal killing, DeltarecA lexA3 (Ind(-)) cells with P(tac)-recA(+) show 40-fold greater survival than lexA3 (Ind(-)) cells with chromosomal recA having a low, non-induced level of RecA protein. However, they still show 10- to 15-fold lower survival than wild-type cells and DeltarecA lexA(+) cells with P(tac)-recA(+). To determine if the inducible RuvA protein stimulates survival, we examined a ruvA60 mutant that is defective for the repair of UV-induced DNA damage. This mutant also shows 10- to 15-fold lower survival than wild-type cells. We conclude that while induction of RecA protein has a pronounced stimulatory effect on the recombinational repair of H(2)O(2)-induced oxidative DNA damage, the induction of other SOS proteins such as RuvA is essential for wild-type repair.     

Acclimation and repair of DNA damage in recombinant bioluminescent Escherichia coli

AIMS: The aim of this study is to understand different adaptive responses in bacteria caused by three different mutagens, namely, an intercalating agent, an alkylating agent and a hydroxylating agent, and the repair systems according to the type of DNA damage, that is, DNA cross-linking and delayed DNA synthesis, alkylation and hydroxylation of DNA. A recombinant bioluminescent Escherichia coli, DPD2794 with the recA promoter fused to luxCDABE originating from Vibrio fischeri, was used in this study. METHODS AND RESULTS: The recombinant bioluminescent E. coli strain DPD2794, containing a recA promoter fused to luxCDABE from V. fischeri, was used to detect adaptive and repair responses to DNA damage caused by mitomycin C (MMC), and these responses were compared with those when the cells were induced with N-methyl-N-nitro-N-nitrosoguanidine (MNNG) and hydrogen peroxide (H2O2). The response ratio between the induced samples and that of the controls decreased suddenly when the induced culture was used in further inductions, indicating a possible adaptive response to DNA damage. DNA damage, or the proteins produced, because of MMC addition does not appear to be completely resolved until the seventh sub-culture after the initial induction, whereas simple damage, such as the base modification caused by MNNG and H2O2, appears to be repaired rapidly as evidenced by the quick recovery of sensitivity. CONCLUSIONS: These results suggest that it takes more time to completely repair DNA damage caused by MMC, as compared with a simple repair such as that required for the damage caused by MNNG and H2O2. Therefore, repair of the damage caused by these three mutagens is controlled by different regulons, even though they all induced the recA promoter. SIGNIFICANCE AND IMPACT OF THE STUDY: Using a bioluminescent E. coli harbouring a recA promoter-lux fusion, it was found that different adaptive responses and repair systems for DNA damage caused by several mutagens exists in E. coli.     

Suppression of constitutive SOS expression by recA4162 (I298V) and recA4164 (L126V) requires UvrD and RecX in Escherichia coli K-12

Sensing DNA damage and initiation of genetic responses to repair DNA damage are critical to cell survival. In Escherichia coli , RecA polymerizes on ssDNA produced by DNA damage creating a RecA–DNA filament that interacts with the LexA repressor inducing the SOS response. RecA filament stability is negatively modulated by RecX and UvrD. recA730 (E38K) and recA4142 (F217Y) constitutively express the SOS response. recA4162 (I298V) and recA4164 (L126V) are intragenic suppressors of the constitutive SOS phenotype of recA730 . Herein, it is shown that these suppressors are not allele specific and can suppress SOS^C expression of recA730 and recA4142 in cis and in trans . recA4162 and recA4164 single mutants (and the recA730 and recA4142 derivatives) are Rec⁺, UV^R and are able to induce the SOS response after UV treatment like wild-type. UvrD and RecX are required for the suppression in two ( recA730,4164 and recA4142,4162 ) of the four double mutants tested. To explain the data, one model suggests that recA ^C alleles promote SOS^C expression by mimicking RecA filament structures that induce SOS and the suppressor alleles mimic RecA filament at end of SOS. UvrD and RecX are attracted to these latter structures to help dismantle or destabilize the RecA filament.     

Therefore,what are recombination proteins there for?

The order of discovery can have a profound effect upon the way in which we think about the function of a gene. In E. coli, recA is nearly essential for cell survival in the presence of DNA damage. However, recA was originally identified, as a gene required to obtain recombinant DNA molecules in conjugating bacteria. As a result, it has been frequently assumed that recA promotes the survival of bacteria containing DNA damage by recombination in which DNA strand exchanges occur. We now know that several of the processes that interact with or are controlled by recA, such as excision repair and translesion synthesis, operate to ensure that DNA replication occurs processively without strand exchanges. Yet the view persists in the literature that recA functions primarily to promote recombination during DNA repair. With the benefit of hindsight and more than three decades of additional research, we reexamine some of the classical experiments that established the concept of DNA repair by recombination, and we consider the possibilities that recombination is not an efficient mechanism for rescuing damaged cells, and that recA may be important for maintaining processive replication in a manner that does not generally promote recombination.     

Mutagenic lesion bypass and two functionally different RecA proteins in Deinococcus deserti

RecA is essential for extreme radiation tolerance in Deinococcus radiodurans . Interestingly, Sahara bacterium Deinococcus deserti has three recA genes ( recA _C, recA _P1, recA _P3) that code for two different RecA proteins (RecA_C, RecA_P). Moreover, and in contrast to other sequenced Deinococcus species, D. deserti possesses homologues of translesion synthesis (TLS) DNA polymerases, including ImuY and DnaE2. Together with a lexA homologue, imuY and dnaE2 form a gene cluster similar to a widespread RecA/LexA-controlled mutagenesis cassette. After having developed genetic tools, we have constructed mutant strains to characterize these recA and TLS polymerase genes in D. deserti . Both RecA_C and RecA_P are functional and allow D. deserti to survive, and thus repair massive DNA damage, after exposure to high doses of radiation. D. deserti is mutable by UV, which requires ImuY, DnaE2 and RecA_C, but not RecA_P. RecA_C, but not RecA_P, facilitates induced expression of imuY and dnaE2 following UV exposure. We propose that the extra recA _P1 and recA _P3 genes may provide higher levels of RecA protein for efficient error-free repair of DNA damage, without further increasing error-prone lesion bypass by ImuY and DnaE2, whereas limited TLS may contribute to adaptation to harsh conditions by generating genetic variability.     

Effects of the Escherichia coli recF suppressor mutation, recA801, on recF-dependent DNA-repair associated phenomena

In recb recC sbcB mutants genetic recombination is dependent upon the recF gene. recA801, recA802 and recA803 (formerly called srfA mutations) were originally isolated as mutations that suppress recombination deficiency caused by a recF mutation in a recB recC sbcB genetic background. Since the recA801 mutation also suppressed some of the UV sensitivity due to recF143, we sought to determine what DNA-repair pathways were actually being restored by the recA801 mutation in this genetic background. In this paper we show that the suppression of recF143 by recA801 does not extend to the recF143-mediated defects in induced repair of UV-damaged phages. In addition, we show that recA801 suppresses only slightly the recF143-associated defect in induced expression of the SOS-regulated muc genes of pKM101. These results suggest that recA801 suppresses primarily the RecF pathway of recombinational repair.     

Specific amino acid changes enhance the anti-recombination activity of the UmuD'C complex

In addition to being an essential component of trans-lesion synthesis, the UmuD'C complex is an antagonist of RecA-mediated homologous recombination. When constitutively expressed at an elevated concentration, the UmuD'C complex sensitizes recA+ bacteria to DNA damage, whereas it has no effect on bacteria expressing a RecA [UmuR] protein that overcomes recombination inhibition. Using as a genetic screen enhanced cell killing on mitomycin plates, we isolated novel umuD' and umuC mutations that restored mitomycin sensitivity to recA D112G [UmuR] bacteria overproducing the UmuD'C complex. The mutations were named [Rin++] because a characterization in a recA+ as well in a recA D112G background showed that they enhanced UmuD'C-promoted recombination inhibition in two assays, conjugational recombination and recombinational repair of palindrome-containing DNA. The [Rin++] mutations affect five amino acids, G25D, S28T, P29L, E35K, and T95R, in UmuD' and seven, F10L, Y270C, K277E, F287L, F287S, K342Q and F351I, in UmuC. These amino acids might play a key role in the UmuD'C anti-recombination activity. None of the [Rin++] mutations enhanced UmuD'C-promoted mutagenic bypass of UV lesions, in contrast, several lead to a defect in this process. In this study, we discuss a few molecular mechanisms that could account for the recombination and mutagenesis phenotypes of a mutant UmuD'C [Rin++] complex.     

Multiple pathways for repair of hydrogen peroxide-induced DNA damage in Escherichia coli.

The repair response of Escherichia coli to hydrogen peroxide has been examined in mutants which show increased sensitivity to this agent. Four mutants were found to show increased in vivo sensitivity to hydrogen peroxide compared with wild type. These mutants, in order of increasing sensitivity, were recA, polC, xthA, and polA. The polA mutants were the most sensitive, implying that DNA polymerase I is required for any repair of hydrogen peroxide damage. Measurement of repair synthesis after hydrogen peroxide treatment demonstrated normal levels for recA mutants, a small amount for xthA mutants, and none for polA mutants. This is consistent with exonuclease III being required for part of the repair synthesis seen, while DNA polymerase I is strictly required for all repair synthesis. Sedimentation analysis of cellular DNA after hydrogen peroxide treatment showed that reformation was absent in xthA, polA, and polC(Ts) strains but normal in a recA cell line. By use of a lambda phage carrying a recA-lacZ fusion, we found hydrogen peroxide does not induce the recA promoter. Our findings indicate two pathways of repair for hydrogen peroxide-induced DNA damage. One of these pathways would utilize exonuclease III, DNA polymerase III, and DNA polymerase I, while the other would be DNA polymerase I dependent. The RecA protein seems to have little or no direct function in either repair pathway.     

Impact of DNA gyrase inhibition by antisense ribozymes on rec A in <Emphasis Type="Italic">E. coli</Emphasis>

The chromosome of E. coli is maintained in a negatively supercoiled state, and supercoiling levels are affected by growth phase and a variety of environmental stimuli. Regulation of DNA supercoiling yields a complex spectrum of effects on the E. coli recA system. Previous studies indicated that inhibition of DNA gyrase by antibiotics that act on the DNA gyrase A subunit results in turning on the recA system. Here we show that antisense ribozymes that act on the DNA gyrase A subunit can also induce recA. We used real time PCR and immunoblot to analyze the impact of DNA gyrase A inhibition by antisense ribozymes on recA expression. When gyrase A was inhibited by the RNase P mediated antisense ribozymes the expression of recA was induced around 130-fold as seen by real time PCR analysis. This suggests that repair pathway is induced by antisense ribozymes against DNA gyrase A and the damage produced by these ribozymes may be similar to that produced by fluroquinolones.     

Influence of temperature on biofilm formation by Listeria monocytogenes on various food-contact surfaces: relationship with motility and cell surface hydrophobicity

Aims:  To assess the ability of Listeria monocytogenes to form biofilm on different food-contact surfaces with regard to different temperatures, cellular hydrophobicity and motility.
Methods and Results:  Forty-four L. monocytogenes strains from food and food environment were tested for biofilm formation by crystal violet staining. Biofilm levels were significantly higher on glass at 4, 12 and 22°C, as compared with polystyrene and stainless steel. At 37°C, L. monocytogenes produced biofilm at significantly higher levels on glass and stainless steel, as compared with polystyrene. Hydrophobicity was significantly ( P  < 0·05) higher at 37°C than at 4, 12 and 22°C. Thirty (68·2%) of 44 strains tested showed swimming at 22°C and 4 (9·1%) of those were also motile at 12°C. No correlation was observed between swimming and biofilm production.
Conclusions:  L. monocytogenes can adhere to and form biofilms on food-processing surfaces. Biofilm formation is significantly influenced by temperature, probably modifying cell surface hydrophobicity.
Significance and Impacts of the Study:  Biofilm formation creates major problems in the food industry because it may represent an important source of food contamination. Our results are therefore important in finding ways to prevent contamination because they contribute to a better understanding on how L. monocytogenes can establish biofilms in food industry and therefore survive in the processing environment.     

Azaserine: further evidence for DNA damage in Escherichia coli

Azaserine causes DNA damage in stationary-phase cells. In our investigation of this damage, we used strains of Escherichia coli differing in repair capabilities to study azaserine-induced DNA damage, detected as DNA strand breaks by sucrose gradient sedimentation techniques. Reduced sedimentation in alkaline and neutral sucrose gradients indicated the presence of both alkali-labile sites and in situ strand breaks. Azaserine induced DNA single-strand breaks (SSBs) abundantly in all but the recA strain, in which SSBs were greatly reduced. Treatment of purified DNA with azaserine from bacteriophages T4 and PM2 produced no detectable SSBs. Several other studies also failed to detect DNA damage induced directly by azaserine. Increased levels of beta-galactosidase were induced in an E. coli strain possessing a rec::lac fusion, providing further evidence for azaserine induction of the recA gene product. In addition, azaserine induced adaptation against killing but not against mutagenesis in wild-type E. coli strain.     

An alternative pathway of recombination of chromosomal fragments precedes recA-dependent recombination in the radioresistant bacterium Deinococcus radiodurans.

Deinococcus radiodurans R1 and other members of this genus are able to repair and survive extreme DNA damage induced by ionizing radiation and many other DNA-damaging agents. The ability of R1 to repair completely > 100 double-strand breaks in its chromosome without lethality or mutagenesis is recA dependent. However, during the first 1.5 h after irradiation, recA+ and recA cells show similar increases in the average size of chromosomal fragments. In recA+ cells, DNA continues to enlarge to wild-type size within 29 h. However, in recA cells, no DNA repair is observed following the first 1.5 h postirradiation. This recA-independent effect was studied further, using two slightly different Escherichia coli plasmids forming adjacent duplication insertions in the chromosome, providing repetitive sequences suitable for circularization by non-recA-dependent pathways following irradiation. After exposure to 1.75 Mrad (17,500 Gy), circular derivatives of the integration units were detected in both recA+ and recA cells. These DNA circles were formed in the first 1.5 h postirradiation, several hours before the onset of detectable recA-dependent homologous recombination. By comparison, D. radiodurans strains containing the same E. coli plasmids as nonrepetitive direct insertions did not form circular derivatives of the integration units before or after irradiation in recA+ or recA cells. The circular derivatives of the tandemly integrated plasmids were formed before the onset of recA-dependent repair and have structures consistent with the hypothesis that DNA repair occurring immediately postirradiation is by a recA-independent single-strand annealing reaction and may be a preparatory step for further DNA repair in wild-type D. radiodurans.     

Inactivation of the Spirochete recA Gene Results in a Mutant with Low Viability and Irregular Nucleoid Morphology

Recently, we have shown the first evidence for allelic exchange in Leptospira spp. By using the same methodology, the cloned recA of Leptospira biflexa was interrupted by a kanamycin resistance cassette, and the mutated allele was then introduced into the L. biflexa chromosome by homologous recombination. The recA double-crossover mutant showed poor growth in liquid media and was considerably more sensitive to DNA-damaging agents such as mitomycin C and UV light than the wild-type strain. The efficiency of plating of the recA mutant was about 10% of that of the parent strain. In addition, microscopic observation of the L. biflexa recA mutant showed cells that are more elongated than those of the wild-type strain. Fluorescent microscopy of stained cells of the L. biflexa wild-type strain revealed that chromosomal DNA is distributed throughout most of the length of the cell. In contrast, the recA mutant showed aberrant nucleoid morphologies, i.e., DNA is condensed at the midcell. Our data indicate that L. biflexa RecA plays a major role in ensuring cell viability via mechanisms such as DNA repair and, indirectly, active chromosome partitioning.     

Variability of RNA Quality Extracted from Biofilms of Foodborne Pathogens Using Different Kits Impacts mRNA Quantification by qPCR

The biofilm formation by foodborne pathogens is known to increase the problem related with surface disinfection procedure in the food processing environment and consequent transmission of these pathogens into the population. Messenger RNA has been increasingly used to understand the action and the consequences of disinfectants in the virulence on such biofilms. RNA quality is an important requirement for any RNA-based analysis since the quality can impair the mRNA quantification. Therefore, we evaluated five different RNA extraction kits using biofilms of the foodborne pathogens Listeria monocytogenes, Escherichia coli, and Salmonella enterica. The five kits yielded RNA with different quantities and qualities. While for E. coli the variability of RNA quality did not affect the quantification of mRNA, the same was not true for L. monocytogenes or S. enterica. Therefore, our results indicate that not all kits are suitable for RNA extraction from bacterial biofilms, and thus, the selection of RNA extraction kit is crucial to obtain accurate and meaningful mRNA quantification.     

Duplication Mutation as an Sos Response in Escherichia Coli: Enhanced Duplication Formation by a Constitutively Activated Reca

The SOS response in Escherichia coli involves the induction of a multioperon regulatory system, which copes with the presence of DNA lesions that interfere with DNA replication. Induction depends on activation of the RecA protein to cleave the LexA repressor of SOS operons. In addition to inducible DNA repair, the SOS system produces a large increase in the frequency of point mutations. To examine the possibility that other types of mutations are induced as part of the SOS response, we have studied the production of tandem duplications. To avoid the complications of indirect effects of the DNA lesions, we have activated the SOS response by a constitutive mutation in the recA gene, recA730. The introduction of the recA730 mutation results in an increase in duplications in the range of tenfold or greater, as judged by two different criteria. Based on its genetic requirements, the pathway for induced duplication formation is distinct from the point mutation pathway and also differs from the major normal recombination pathway. The induction of pathways for both duplications and point mutations shows that the SOS system produces a broad mutagenic response. We have suggested previously that many types of mutations might be induced by severe environmental stress, thereby enhancing genetic variation in an endangered population.