Identification of the recA (tif) gene product of Escherichia coli

Multidrug-resistant Acinetobacter pittii is adapting to and exhibiting potential succession aboard the International Space Station

BACKGROUND

Monitoring the adaptation of microorganisms to the extreme environment of the International Space Station (ISS) is crucial to understanding microbial evolution and infection prevention. Acinetobacter pittii is an opportunistic nosocomial pathogen, primarily impacting immunocompromised patients, that was recently isolated from two missions aboard the ISS.

RESULTS

Here, we report how ISS-associated A. pittii (n = 20 genomes) has formed its own genetically and functionally discrete clade distinct from most Earth-bound isolates (n = 291 genomes). The antimicrobial susceptibility testing of ISS strains and two related clinical isolates demonstrated that ISS strains acquired more resistance, specifically with regard to expanded-spectrum cephalosporins, despite no prediction of increased resistance based on genomic analysis of resistance genes. By investigating 402 longitudinal environmental and host-associated ISS metagenomes, we observed that viable A. pittii is increasing in relative abundance and therefore potentially exhibiting succession, being identified in >2X more metagenomic samples in back-to-back missions. ISS strains additionally contain functions that enable them to survive in harsh environments, including the transcriptional regulator LexA. Via a genome-wide association study, we identified a high level of mutational burden in methionine sulfoxide reductase genes relative to the most closely related Earth strains.

CONCLUSIONS

Overall, these results indicated a step forward in understanding how microorganisms might evolve and alter their antibiotic resistance phenotype in extreme, resource-limited, human-built environments. Video Abstract.

Monitoring of dynamic microbiological processes using real-time flow cytometry

We describe a straightforward approach to continuously monitor a variety of highly dynamic microbiological processes in millisecond resolution with flow cytometry, using standard bench-top instrumentation. Four main experimental examples are provided, namely: (1) green fluorescent protein expression by antibiotic-stressed Escherichia coli, (2) fluorescent labeling of heat-induced membrane damage in an autochthonous freshwater bacterial community, (3) the initial growth response of late stationary E. coli cells inoculated into fresh growth media, and (4) oxidative disinfection of a mixed culture of auto-fluorescent microorganisms. These examples demonstrate the broad applicability of the method to diverse biological experiments, showing that it allows the collection of detailed, time-resolved information on complex processes.

The SMC-like protein complex SbcCD enhances DNA polymerase IV-dependent spontaneous mutation in Escherichia coli

In Escherichia coli, RpoS, the general stress response sigma factor, regulates the activity of the specialized DNA polymerase DNA polymerase IV (Pol IV) both in stationary-phase and in exponential-phase cells. Because during exponential phase dinB, the gene encoding Pol IV, is transcribed independently of RpoS, RpoS must regulate Pol IV activity in growing cells indirectly via one or more intermediate factors. The results presented here show that one of these intermediate factors is SbcCD, an SMC-like protein and an ATP-dependent nuclease. By initiating or participating in double-strand break repair, SbcCD may provide DNA substrates for Pol IV polymerase activity.

The SOS Regulatory Network

All organisms possess a diverse set of genetic programs that are used to alter cellular physiology in response to environmental cues. The gram-negative bacterium, Escherichia coli, mounts what is known as the "SOS response" following DNA damage, replication fork arrest, and a myriad of other environmental stresses. For over 50 years, E. coli has served as the paradigm for our understanding of the transcriptional, and physiological changes that occur following DNA damage (400). In this chapter, we summarize the current view of the SOS response and discuss how this genetic circuit is regulated. In addition to examining the E. coli SOS response, we also include a discussion of the SOS regulatory networks in other bacteria to provide a broader perspective on how prokaryotes respond to DNA damage.

Characterization of the Staphylococcus aureus heat shock, cold shock, stringent, and SOS responses and their effects on log-phase mRNA turnover

Despite its being a leading cause of nosocomal and community-acquired infections, surprisingly little is known about Staphylococcus aureus stress responses. In the current study, Affymetrix S. aureus GeneChips were used to define transcriptome changes in response to cold shock, heat shock, stringent, and SOS response-inducing conditions. Additionally, the RNA turnover properties of each response were measured. Each stress response induced distinct biological processes, subsets of virulence factors, and antibiotic determinants. The results were validated by real-time PCR and stress-mediated changes in antimicrobial agent susceptibility. Collectively, many S. aureus stress-responsive functions are conserved across bacteria, whereas others are unique to the organism. Sets of small stable RNA molecules with no open reading frames were also components of each response. Induction of the stringent, cold shock, and heat shock responses dramatically stabilized most mRNA species. Correlations between mRNA turnover properties and transcript titers suggest that S. aureus stress response-dependent alterations in transcript abundances can, in part, be attributed to alterations in RNA stability. This phenomenon was not observed within SOS-responsive cells.

RecA and RadA proteins of Brucella abortus do not perform overlapping protective DNA repair functions following oxidative burst

Very little is known about the role of DNA repair networks in Brucella abortus and its role in pathogenesis. We investigated the roles of RecA protein, DNA repair, and SOS regulation in B. abortus. While recA mutants in most bacterial species are hypersensitive to UV damage, surprisingly a B. abortus recA null mutant conferred only modest sensitivity. We considered the presence of a second RecA protein to account for this modest UV sensitivity. Analyses of the Brucella spp. genomes and our molecular studies documented the presence of only one recA gene, suggesting a RecA-independent repair process. Searches of the available Brucella genomes revealed some homology between RecA and RadA, a protein implicated in E. coli DNA repair. We considered the possibility that B. abortus RadA might be compensating for the loss of RecA by promoting similar repair activities. We present functional analyses that demonstrated that B. abortus RadA complements a radA defect in E. coli but could not act in place of the B. abortus RecA. We show that RecA but not RadA was required for survival in macrophages. We also discovered that recA was expressed at high constitutive levels, due to constitutive LexA cleavage by RecA, with little induction following DNA damage. Higher basal levels of RecA and its SOS-regulated gene products might protect against DNA damage experienced following the oxidative burst within macrophages.

Recombinational DNA repair in bacteria and the RecA protein

In bacteria, the major function of homologous genetic recombination is recombinational DNA repair. This is not a process reserved only for rare double-strand breaks caused by ionizing radiation, nor is it limited to situations in which the SOS response has been induced. Recombinational DNA repair in bacteria is closely tied to the cellular replication systems, and it functions to repair damage at stalled replication forks, Studies with a variety of rec mutants, carried out under normal aerobic growth conditions, consistently suggest that at least 10-30% of all replication forks originating at the bacterial origin of replication are halted by DNA damage and must undergo recombinational DNA repair. The actual frequency may be much higher. Recombinational DNA repair is both the most complex and the least understood of bacterial DNA repair processes. When replication forks encounter a DNA lesion or strand break, repair is mediated by an adaptable set of pathways encompassing most of the enzymes involved in DNA metabolism. There are five separate enzymatic processes involved in these repair events: (1) The replication fork assembled at OriC stalls and/or collapses when encountering DNA damage. (2) Recombination enzymes provide a complementary strand for a lesion isolated in a single-strand gap, or reconstruct a branched DNA at the site of a double-strand break. (3) The phi X174-type primosome (or repair primosome) functions in the origin-independent reassembly of the replication fork. (4) The XerCD site-specific recombination system resolves the dimeric chromosomes that are the inevitable by-product of frequent recombination associated with recombinational DNA repair. (5) DNA excision repair and other repair systems eliminate lesions left behind in double-stranded DNA. The RecA protein plays a central role in the recombination phase of the process. Among its many activities, RecA protein is a motor protein, coupling the hydrolysis of ATP to the movement of DNA branches.

Application of two-dimensional protein gels in biotechnology

The optimal use of biological systems for technologically developed products will not be achieved until biological systems are completely defined in biochemical terms. Two-dimensional polyacrylamide gel electrophoresis, 2-D gels, are contributing to this goal. These gels separate complex mixtures of proteins into individual polypeptide species. The ultimate use of 2-D gels is the construction of cellular 2-D gel databases which identify the proteins on the gels and catalog their responses to different environmental conditions. In addition to these global analyses, many applications for 2-D gels in basic, applied and clinical research have been shown.

Gene sequence of recA+ and construction of recA mutants of Vibrio cholerae

The recA+ gene of Vibrio cholerae O1 has been cloned, its nucleotide sequence determined and the product characterized. A deletion mutation was constructed in the recA gene and mutants showed the typical sensitivity to UV and to DNA-damaging agents, as well as an inability to mediate homologous DNA recombination. The chromosomal recA deletion mutants in V. cholerae do not show altered virulence in the infant mouse cholera model and are thus ideal strains for use in complementation studies.

The gene-protein database of Escherichia coli: edition 5

The gene-protein database of Escherichia coli is both an index relating a gene to its protein product on two-dimensional gels, and a catalog of information about the function, regulation, and genetics of individual proteins obtained from two-dimensional gel analysis or collated from the literature. Edition 5 has 102 new entries--a 15% increase in the number of annotated two-dimensional gel spots. The large increase in this edition was accomplished in part by the use of a new method for expression analysis of ordered segments of the E. coli genome, which has resulted in linking 50 gel spots to their genes (or open reading frames) and another 45 to specific regions of the chromosome awaiting the availability of DNA sequence information. Communication of information from the scientific community resulted in additional identifications and regulatory information. To increase accessibility of the database it has been placed in the repository at the National Center for Biotechnology Information (NCBI) at the National Library of Medicine under the name ECO2DBASE. It will be updated twice yearly. This edition of the gene-protein database is estimated to contain entries for one-sixth of the protein-encoding genes of E. coli.

The gene-protein database of Escherichia coli: edition 4

The gene-protein database of Escherichia coli has as its core an index that links each of the protein spots from a two-dimensional polyacrylamide gel to the gene that encodes the protein. Additional information about each protein and its gene is generated from two-dimensional gel analysis or collated from the literature to form the database. Earlier editions of the database have provided periodic updates of information. The current edition does this, but also introduces a new reference gel image produced by an electrophoresis system recently adopted in this laboratory. The new gel system was chosen because it offers an improved opportunity for other investigations to produce close replicas of the reference gel pattern, thereby allowing easier access to the information of the database and encouraging independent contribution to the database. The new gel format also is larger and hence more compatible with computer assisted image analysis, which has become essential for a project of this magnitude. This edition continues the use of the former reference gel images, but adds a reference image of an equilibrium gel of E. coli strain W3110 produced by the new standardized gel system. At this time, 55% of the protein spots annotated on the previous equilibrium reference gel for this organism have been located on the new reference image, and these identifications are included in the tables of the database.

Gene-protein database of Escherichia coli K-12: edition 3

The first two editions of the E. coli Gene-Protein Index were published to provide identifications of protein spots resolved by two-dimensional gel electrophoresis as the products of known genes. This third edition has been expanded to include information about genes and proteins gained directly from two-dimensional gel analysis--including information about protein spots not yet characterized genetically or biochemically--and is therefore more properly called a cellular protein database. An alpha-numeric designation has been uniquely assigned to each of the 616 polypeptide spots in the current database. To this, information is linked about the polypeptide's identification (protein name, gene name, Enzyme Commission--EC number), location on reference gels (x-y coordinates), genetics (Genbank code, DNA sequence reference), biochemistry (molecular weight, isoelectric point), and physiology (steady state level of the protein as a function of media and temperature, membership in various regulons and stimulons).

Construction of an Azospirillum brasilense Sp7 recA mutant

Cosmid clones encoding the recA gene of Azospirillum brasilense were isolated by intergeneric complementation of an Escherichia coli recA mutant. Site-directed Tn5 mutagenesis and subcloning of one complementing cosmid clone allowed us to localize the A. brasilense recA gene on a 1.2 kb DNA fragment. One Tn5 insertion that inactivates the cloned recA gene was crossed into the chromosome of A. brasilense by marker exchange. The resulting A. brasilense recA mutant showed increased sensitivity to the DNA methylating agent methyl methanesulfonate and to ultraviolet light and had at least one hundredfold reduced recombinational activity compared to the parent strain.

A new gene controlling the frequency of cell division per round of DNA replication in Escherichia coli

A novel mutant of Escherichia coli, named cfcA1, was isolated from a temperature-sensitive dnaB42 strain, and found to have the following characteristics. Division arrest and lethality induced by inhibition of DNA replication was reduced and delayed in the cfcA1 dnaB42 strain, as compared with the parental dnaB42 strain. Two types of inhibition of division induced by the addition of nalidixic acid or hydroxyurea were suppressed by the cfcA1 mutation. Under permissive conditions for DNA replication, the colony forming ability of cfcA1 cells was significantly reduced as compared with that of cfc+ cells; conversely the division rate of cfcA1 cells was higher than that of cfc+ cells. The cfcA1 mutation partially restored division arrest induced in the thermosensitive ftsZ84 mutant at the restrictive temperature and suppressed the UV sensitivity of the lon mutation. The mutation was mapped at 79.2 min on the E. coli chromosome. Taking these properties into account, it is hypothesized that the cfcA gene is involved in determining the frequency of cell division per round of DNA replication by interacting with the FtsZ protein which is essential for cell division.

Constitutive expression of the SOS response in recA718 mutants of Escherichia coli requires amplification of RecA718 protein

In recA718 lexA+ strains of Escherichia coli, induction of the SOS response requires DNA damage. This implies that RecA718 protein, like RecA+ protein, must be converted, by a process initiated by the damage, to an activated form (RecA) to promote cleavage of LexA, the cellular repressor of SOS genes. However, when LexA repressor activity was abolished by a lexA-defective mutation [lexA(Def)], strains carrying the recA718 gene (but not recA+) showed strong SOS mutator activity and were able to undergo stable DNA replication in the absence of DNA damage (two SOS functions known to require RecA activity even when cleavage of LexA is not necessary). lambda lysogens of recA718 lexA(Def) strains exhibited mass induction of prophage, indicative of constitutive ability to cleave lambda repressor. When the cloned recA718 allele was present in a lexA+ strain on a plasmid, SOS mutator activity and beta-galactosidase synthesis under LexA control were expressed in proportion to the plasmid copy number. We conclude that RecA718 is capable of becoming activated without DNA damage for cleavage of LexA and lambda repressor, but only if it is amplified above its base-line level in lexA+ strains. At amplified levels, RecA718 was also constitutively activated for its roles in SOS mutagenesis and stable DNA replication. The nucleotide sequence of recA718 reveals two base substitutions relative to the recA+ sequence. We propose that the first allows the protein to become activated constitutively, whereas the second partially suppresses this capability.

Cloning of the Vibrio cholerae recA gene and construction of a Vibrio cholerae recA mutant

A recombinant plasmid carrying the recA gene of Vibrio cholerae was isolated from a V. cholerae genomic library, using complementation in Escherichia coli. The plasmid complements a recA mutation in E. coli for both resistance to the DNA-damaging agent methyl methanesulfonate and recombinational activity in bacteriophage P1 transductions. After determining the approximate location of the recA gene on the cloned DNA fragment, we constructed a defined recA mutation by filling in an XbaI site located within the gene. The 4-base pair insertion resulted in a truncated RecA protein as determined by minicell analysis. The mutation was spontaneously recombined onto the chromosome of a derivative of V. cholerae strain P27459 by screening for methyl methanesulfonate-sensitive variants. Southern blot analysis confirmed the presence of the inactivated XbaI site in the chromosome of DNA isolated from one of these methyl methanesulfonate-sensitive colonies. The recA V. cholerae strain was considerably more sensitive to UV light than its parent, was impaired in homologous recombination, and was deficient in induction of a temperate vibriophage upon exposure to UV light. We conclude that the V. cholerae RecA protein has activities which are analogous to those described for the RecA protein of E. coli.

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 respiration. On the contrary, both recA+ and recA441 cultures either treated with bleomycin or incubated at 42 degrees 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.

Effect of a lexA41(Ts) mutation on DNA repair in recA(Def) derivatives of Escherichia coli K-12

Derivatives of Escherichia coli K-12 carrying a deletion of the recA gene survive exposure to UV (254 nm) better if they also contain the lexA41 mutation which codes for a labile LexA protein. This effect of the lexA41 mutation is not observed in comparable strains carrying a uvr A6 mutation. Using two independent methods to detect pyrimidine dimers we found that UV irradiated RecA deficient cells removed dimers from their DNA more rapidly if they contained the lexA41 mutation than if they contained the wild-type lexA gene. Our results are consistent with the idea that a relatively high level of UvrABC incision nuclease resulting from inefficient repression of the corresponding genes by the labile LexA41 protein facilitates excision of pyrimidine dimers from the DNA of UV irradiated cells.

Identification of the Escherichia coli recN gene product as a major SOS protein

The recA+ lexA+-dependent induction of four Escherichia coli SOS proteins was readily observed by two-dimensional gel analysis. In addition to the 38-kilodalton (kDa) RecA protein, which was induced in the greatest amounts and was readily identified, three other proteins of 115, 62, and 12 kDa were seen. The 115-kDa protein is the product of the uvrA gene, which is required for nucleotide excision repair and has previously been shown to be induced in the SOS response. The 62-kDa protein, which was induced to high intracellular levels, is the product of recN, a gene required for recBC-independent recombination. The recA and recN genes were partially derepressed in a recBC sbcB genetic background, a phenomenon which might account for the recombination proficiency of such strains. The 12-kDa protein has yet to be identified.

Purification and some of the functions of the products of bacteriophage T4 recombination genes, uvsX and uvsY

The nonessential T4 genes uvsX and uvsY are involved in DNA repair and general recombination. Using newly isolated amber mutants of these genes, we have identified the gene products (gp) by sodium dodecyl sulfate (SDS)/polyacrylamide gel electrophoresis. Their relative molecular masses are 39 000 and 16 000, respectively. In the normal wild-type infection process they are produced early but not late in infection. Their synthesis continues for a longer period when DNA synthesis is blocked. We have developed procedures to isolate these gene products at a purity of more than 95% for gpuvsX and at 70% for gpuvsY, as judged by SDS/polyacrylamide gel electrophoresis and staining with Coomassie brilliant blue dye. The purification procedures suggest that these products may be membrane proteins. Using both an agarose gel assay and electron microscopy, we find that the product of the gene uvsX catalyzes the assimilation of a linear single-stranded fd DNA fragment into superhelical double-stranded fd DNA (RFI). The reaction requires ATP and Mg2+ besides substrate DNAs and uvsX protein. The T4 uvsX protein therefore is similar to the Escherichia coli recA protein in molecular size and function, but differs in antigenic property.

RecA protein--promoted lambda repressor cleavage: complementation between RecA441 and RecA430 proteins in vitro

Induction of prophage lambda occurs in recA441 mutant lysogens after a shift to 42 degrees C in the presence of adenine. If the synthesis of RecA441 protein is maintained at a low basal level by the presence of a second mutation in the recA441 gene, recA453, induction of prophage lambda is prevented. The ability to induce prophage lambda is restored by the introduction, on a transducing phage, of a second recA gene carrying the recA430 mutation; by itself, the RecA430 protein is devoid of activity against the lambda repressor (Rebollo et al. 1984). In order to explain how the RecA430 protein might complement the RecA441 protein to provide lambda repressor cleavage in a recA453-441 (recA430) diploid lysogen, we characterized the cleavage reaction catalysed by a mixture of these proteins in vitro. Our results suggest that, in the presence of dATP, the RecA441 and RecA430 proteins form mixed multimers on single-stranded DNA, in which the RecA441 protein molecules enhance the DNA binding affinity of RecA430 protein molecules, but RecA430 protein molecules support no cleavage of the lambda repressor. Although the effects of the RecA430 and single-strand binding (SSB) proteins are similar in vitro, we show that the SSB protein cannot substitute for the RecA430 protein in restoring lambda repressor cleavage in a recA453-441 lysogen. Comparison of the stimulatory effect of long single-stranded DNA with that of (dA)14 oligonucleotides on the RecA441 protein-directed cleavage of the lambda repressor in the presence of various nucleoside triphosphates (NTPs) indicates that the cooperative binding of the RecA441 protein to single-stranded DNA stabilizes the RecA protein-DNA complexes so that they remain intact long enough to support cleavage of the lambda repressor. We conclude that the low basal level of the RecA441 protein in a recA453-441 cell is sufficient to cleave the lambda repressor, under conditions where a normal basal level of RecA430 protein is also present allowing the formation of mixed multimers on single-stranded DNA regions normally present in the cell.

Role of RecA protein spiral filaments in genetic recombination

Physical and enzymatic studies on RecA protein from Escherichia coli provide the basis for a molecular model of general genetic recombination, a novel feature of which is the role attributed to spiral filaments of RecA protein.

Analysis of the antimutagenic effect of cinnamaldehyde on chemically induced mutagenesis in Escherichia coli

The antimutagenic effect of cinnamaldehyde on mutagenesis was investigated using ten kinds of chemical mutagen in Escherichia coli WP2s (uvr A-). In addition, the frequency of mutation induction by each mutagen in an SOS repair deficient (umuC-) strain was compared with that in a wild-type (umuC+) strain. Cinnamaldehyde greatly suppressed the umuC-dependent mutagenesis induced by 4-nitroquinoline 1-oxide (4-NQO), furylfuramide or captan. However, cinnamaldehyde was less effective against the umuC-independent mutagenesis by alkylating agents such as N-methyl-N'-nitro-N-nitrosoguanidine and ethylmethanesulfonate. On the other hand, no inhibitory effect of cinnamaldehyde was observed on prophage induction or tif-mediated filamentous growth. These results suggest that a cinnamaldehyde does not prevent the induction of the SOS functions. Despite the decrease in the number of revertants, a remarkable increase was observed in the survival of 4-NQO-treated WP2s cells after exposure to cinnamaldehyde. The reactivation of survival suggests the promotion of some DNA repair system by cinnamaldehyde. This enhancement of survival was also observed in uvr B, polA, recF or umuC mutants and less in lexA or recB, C mutants. However, it was not observed in recA mutants. Therefore, we assume that cinnamaldehyde may enhance an error-free recombinational repair system by acting on recA-enzyme activity.

Expression of human interferon genes using the recA promoter of Escherichia coli

Interferon beta 1 and three alpha-interferon genes were cloned on Eco RI fragments isolated from a human genomic library into the Eco RI site of a plasmid containing the recA promoter of E. coli. Expression of interferon activity from cells carrying these plasmids was nalidixic acid inducible. The alpha-interferon genes were expressed only when in the same transcriptional orientation as the recA promoter while the beta 1 interferon gene was expressed in either orientation. Interferon activity was also inducibly expressed from the recA promoter in cells containing a plasmid carrying a fusion of the recA gene with the beta 1 interferon gene. This interferon activity was thirty-fold less sensitive to neutralization by polyclonal antibodies than authentic interferon, implying that the change near the amino terminus affects either antibody recognition or specific activity or both.

Effect of suppressors of SOS-mediated filamentation on sfiA operon expression in Escherichia coli

In Escherichia coli, the cell division block observed during the SOS response requires the product of the sfiA gene, whose expression is regulated negatively by the LexA repressor and positively by the RecA protease. We have studied the effect on sfiA expression of sfiA, sfiB, infA, and infB mutations, which are known to affect SOS-associated filamentation. To measure sfiA expression in the different strains, we first constructed a lambda transducing phage carrying an sfiA::lac operon fusion. Mutations at the sfiA locus (dominant and recessive) and the sfiB locus (recessive) had no effect on sfiA expression. The mutations tif (at the recA locus) and tsl (at the lexA locus) are known to induce filamentation and a high level of sfiA expression at 42 degrees C. The infB1 mutation, which suppresses filamentation in a tif tsl strain at 42 degrees C, reduced sfiA expression at 42 degrees C in tif tsl infB1 and tsl infB1 strains but not in a tif infB1 strain. The infA3 mutation, which suppresses tif-mediated filamentation, reduced induction of sfiA expression in a tif infA3 strain at 42 degrees C or after UV irradiation. The isolation and characterization of sfiA constitutive strains revealed only lexA-linked mutations in a sfiA-background, suggesting that LexA is the only readily eliminated repressor of the sfiA gene. Nevertheless, the infA and infB mutations could define elements involved in the regulation of sfiA expression.

Cell survival, UV-reactivation and induction of prophage lambda in Escherichia coli K12 overproducing RecA protein

The effect of the cellular level of RecA protein on the ability of E. coli K12 bacteria to (i) survive UV-irradiation (ii) promote UV-reactivation of UV-damaged phage lambda (iii) induce prophage lambda was determined in bacterial mutants with discrete increasing levels of RecA protein. The various levels of RecA protein were obtained by combining lexA and recA alleles. Except for the double mutant lexA3 recAo98, whose repair ability was 25% less than that observed in wild type bacteria, bacterial survival was proportional to the level of RecA protein measured after 90 min of incubation. In lexA3 recAo98 bacteria, RecA protein, at a constitutive high basal level, failed to compensate totally for the lack of LexA repressor cleavage; UV-reactivation of UV-damaged phage lambda was not restored; yet, prophage lambda was induced with 35% efficiency. Efficient UV-induction of prophage lambda is linked to the induction of lexA-controlled host processes that repair the UV-damaged prophage.

Escherichia coli polypeptide controlled by the lon (capR) ATP hydrolysis-dependent protease and possibly involved in cell division

Mutation in the gene lon (capR) of Escherichia coli K-12 causes conditional inhibition of cell division. Two-dimensional gel electrophoresis was used to compare polypeptides from isogenic capR+ and capR strains. One polypeptide was present in the capR strain but absent in the wild-type strain, and it was proteolyzed when the pure capR+ protease was added to the capR extract. This polypeptide could only be detected in the capR strain when cell division was inhibited, and its synthesis was independent of the SOS response.

Transformation of Bacillus subtilis competent cells: identification of a protein involved in recombination

With the use of two-dimensional gel electrophoresis, the proteins present in a transformation-proficient B. subtilis strain were compared with those present in an isogenic, recombination-deficient strain carrying the recE4 mutation. One protein (molecular weight 45 kD, iso-electric point 5.4) was found to be virtually absent in the recE4 strain. This 45 kD protein is a prominent protein predominantly present in the competent fraction of a competent culture. The synthesis of the protein is substantially stimulated by irradiation with ultraviolet light or treatment with mitomycin C and, to a lesser extent, by treatment with nalidixic acid. Since the protein is also observed in a strain cured for SP beta and carrying non-inducible PBS X, it is unlikely that this protein is a gene product specified by one of these prophages usually present in B. subtilis strain 168. Based on these results we conclude that the 45 kD protein is involved in recombination in B. subtilis.

Escherichia coli single-strand binding protein organizes single-stranded DNA in nucleosome-like units

Electron microscopy shows that complexes of the single-strand DNA binding protein (SSB) of Escherichia coli and phage fd DNA appear as beaded fiber loops containing an average of 38 beads, 1 per 170 bases of DNA. Extensive digestion of native unfixed SSB-fd DNA complexes with micrococcal nuclease reveals a protected DNA fragment of 145 bases, while shorter digestion periods result in a sequence of fragments in multiples of 160 +/- 25 bases. Digestion of these complexes with DNase I produces a repeating pattern of bands, multiples of approximately 15 bases with strong bands at 60, 105, 118, 130, 145, 150, and 210 bases. Isopycnic banding in CsCl solution yields densities of 1.272 and 1.700 g/ml, respectively, for SSB alone and for fd DNA and, after fixation, of 1.388 g/ml for fd DNA-SSB beaded fibers and 1.373 g/ml for the individual protein-DNA beads. Based on these data and the molecular weights of SSB and fd DNA, we suggest that the nucleoprotein chain consists of eight molecules of SSB bound to 145 bases of DNA, with these units linked by roughly 30 bases of protein-free DNA. The excellent concord between results obtained by enzyme digestion of unfixed native samples and, after fixation, by electron microscopy and density banding supports the conclusion that SSB organizes single-stranded DNA in a manner similar to the organization of duplex DNA by histones.

Isolation and characterization of an operator-constitutive mutation in the recA gene of E. coli K-12

The recA gene of E. coli is regulated by a specific repressor, the lexA protein, which binds to an operator in the recA regulatory region. We describe in this paper the isolation and characterization of a mutant thought to carry an operator-constitutive mutation in the recA gene. This mutation has the following properties: 1) It partially suppresses the UV sensitivity of lexA- strains. 2) It maps near the recA gene. 3) It allows constitutive high-level synthesis of recA protein in both lexA- and lexA+ backgrounds. 4) It allows constitutive synthesis of the recA messenger RNA. 5) It is cis-acting. The mutation does not restore induced cellular mutagenesis in a lexA- background. The expression of induced repair and mutagenesis of UV irradiated phage lambda or the regulation of the lexA gene is not affected by the presence of the mutation in either a lexA+ or lexA- strain. These observations confirm other findings that high levels of recA protein synthesis per se is not sufficient for the expression of UV inducible functions and that the lexA protein represses other genes besides the recA gene.

recA protein from Escherichia coli. a very rapid and simple purification procedure: binding of adenosine 5'-triphosphate and adenosine 5'-diphosphate by the homogeneous protein

The recA protein from Escherichia coli may be rapidly purified to homogeneity by a simple procedure involving only selective precipitation and one gel filtration step. The binding of ATP to the homogeneous protein has been measured by nonequilibrium dialysis. At pH 8.1 and 25 degrees C, the stoichiometry of the recA X ATP complex is 1:1 and the dissociation constant 24 microM. The binding of ADP to the enzyme and its complexes with single-stranded (ss) DNA and double-stranded (ds) DNA has been measured by equilibrium dialysis. In the absence of DNA, the binding is similar to that observed for ATP. The addition of ssDNA weakens the binding 3-fold. The addition of dsDNA causes a significant drop in the stoichiometry, suggesting an asymmetric distribution of active sites in the complex.

UV light induction of proteins in Bacteroides fragilis under anaerobic conditions

Far-UV irradiation of Bacteroides fragilis cells under anaerobic conditions resulted in the induction of a new 95,000-molecular-weight protein and the increased synthesis of two proteins with molecular weights of 90,000 and 70,000. The latter two proteins were synthesized in small amounts in unirradiated cells. The induction of a 37,000- to 40,000-molecular-weight protein was not observed in irradiated B. fragilis cells. Caffeine, which affected the survival of irradiated B. fragilis cells and reduced host cell-mediated UV reactivation, specifically inhibited the induction of the 95,000-, 90,000-, and 70,000-molecular-weight proteins. Sodium arsenite did not affect the induction of the three inducible proteins or the survival of irradiated B. fragilis cells.

Cleavage of lambda repressor and synthesis of RecA protein induced by transferred UV-damaged F sex factor

Transfer of a UV-damaged F sex factor to a recipient lambda lysogen induces prophage lambda development. Under these conditions RecA protein synthesis was induced and lambda repressor cleaved, as observed upon direct induction, that is, when the recipient lambda lysogen was directly exposed to UV-light. The efficiency of induction of RecA protein synthesis in recipient bacteria which had received an irradiated F-lac factor was about 80% of that measured upon direct induction. We observed the simultaneous disappearance of lambda repressor and a slight production of cleavage fragments; quantitation by densitometric scanning of the autoradiogram after correction for the efficiency of transfer indicated that 55% of lambda repressor was cleaved. Transfer of UV-damaged Hfr DNA failed to induce RecA protein synthesis. A lambda phage vector carrying oriF, the cloned origin of F plasmid replication, after exposure to UV-light and infection of a recipient lysogen, induced RecA protein synthesis and a moderate but significant cleavage of lambda repressor. Indirect induction by UV-damaged F sex factor or phage lambda oriF resulted in biochemical cellular reactions similar to those observed upon direct induction. LexA repressor that negatively controls RecA protein synthesis appeared more susceptible to cleavage than did lambda repressor.

Plasmid pKM101-mediated mutagenesis in Escherichia coli is inducible

A tif-1 umuC36 double mutant of Escherichia coli was constructed. It has been found that the umuC36 mutation prevents both increased spontaneous mutagenesis and enhanced reactivation of UV-irradiated lambda, phenomena normally observed in the tif-1 strain grown at 42 degrees C. When the plasmid pKM101 was introduced into tif-1 umuC36, an elevated spontaneous reversion rate of the his-4 mutation observed at 30 degrees C was further increased 6-fold at 42 degrees C. This was accompanied by a 10-fold increase in the ability of tif-1 umuC36 containing pKM101 and grown before infection at 42 degrees C to reactivate UV-irradiated lambda.

Regulation of the Escherichia coli K-12 uvrB operon

The UV light inducibility of the uvrB operon of Escherichia coli K-12 was previously demonstrated by exploiting a strain in which the gene for the enzyme beta-galactosidase was inserted into the uvrB operon. This insert is now shown to be located within the structural gene for the uvrB enzyme, leaving the regulatory sequences of the operon intact. Analyses to quantitate the induction of this system show that derepression of the operon is first detectable 5 min after UV exposure, with the rate of synthesis increasing to four to six times the uninduced rate during the subsequent 30 min. Induction is unaffected by mutations in other components of nucleotide excision repair. The control of uvrB was found to result from direct repression by the lexA gene product, with the recA gene product playing an indirect role. Nucleotide excision repair thus seems to be part of the SOS response.

Interspecies recA protein substitution in Escherichia coli and Proteus mirabilis

With the help of recombinant plasmids carrying the recA gene of Escherichia coli or of Proteus mirabilis the ability of the recA gene products to substitute functionally for each other was studied. The recA protein of each can function in recombination, repair, induction of mutations and prophages and in regulation of its own synthesis within the foreign host nearly equally well as in the natural host. It is, therefore, suggested that recA-dependent processes act similarly in E. coli and P. mirabilis.

Quantitative evaluation of recA gene expression in Escherichia coli

A recA::lac operon fusion was constructed using the phage Mu d(Ap, lac) in Escherichia coli to obtain precise measurements of the level of recA gene expression in various genetic backgrounds. The RecA protein normally represents 0.02% of total protein. This value is known to increase dramatically after treatments interrupting DNA synthesis; kinetic experiments showed that the rate of recA expression increases 17-fold within 10 min after UV irradiation or thymine starvation. In mutants affected in SOS regulation or repair the following observations were made: (i) the tif-1 mutation in the recA gene does not alter the basal level of recA expression, suggesting that it improves the protease activity of RecA; (ii) the lexA3 mutation does not create a "super-repressor" of recA; (iii) the tsl-1 mutation in the lexA gene makes the LexA protein a poor repressor of recA at 30 degrees C (2.5-fold derepression) and a poor substrate for RecA protease (3-fold stimulation of recA expression by UV); (iv) the spr-55 amber mutation in the lexA gene causes a 30-fold increase in recA expression, higher than all inducing treatments, and this level cannot be further increased by nalidixic acid; (v) the zab-53 mutation at the recA locus, known to abolish tsl-mediated induction of recA expression, is trans-recessive and thus probably affects a regulatory site on the DNA; (vi) uvrA, B and C, recB and recF mutations do not increase the basal level of recA expression, suggesting that there are not sufficient spontaneous lesions to cause induction even when any one of these three repair pathways is inoperative.

Role of DNA replication in the induction and turn-off of the SOS response in Escherichia coli

We have studied the role of DNA replication in turn-on and turn-off of the SOS response in Escherichia coli using a recA::lac fusion to measure levels of recA expression. An active replication fork does not seem to be necessary for mitomycin C induced recA expression: a dnaA43 initiation defective mutant, which does not induce the SOS response at non-permissive temperature, remains mitomycin C inducible after the period of residual DNA synthesis. This induction seems to be dnaC dependent since in a dnaC325 mutant recA expression not only is not induced at 42 degrees C but becomes mitomycin C non-inducible after the period of residual synthesis. Unscheduled halts in DNA replication, generally considered the primary inducing event, are not sufficient to induce the SOS response: no increase in recA expression was observed in dnaG(Ts) mutants cultivated at non-permissive temperature. The replication fork is nonetheless involved in induction, as seen by the increased spontaneous level of recA expression in these strains at permissive temperature. Turn-off of SOS functions can be extremely rapid: induction of recA expression by thymine starvation is reversed within 10 min after restoration of normal DNA replication. We conclude that the factors involved in induction--activated RecA (protease) and the activating molecular (effector)--do not persist in the presence of normal DNA replication.

Induction of E. coli recA protein via recBC and alternate pathways: quantitation by enzyme-linked immunosorbent assay (ELISA)

An enzyme-linked immunosorbent assay (ELISA) has been adapted to measure E. coli recA protein in the 1 to 10 ng range in whole-cell sonicates, membrane extracts, and osmotic shock fluid from 2 x 10(8) cells. The specific activity of recA protein is maintained at a relatively constant "basal' level (800 to 1,200 molecules per cell for wild-type E. coli in L-broth, salt-depleted broth and minimal media) during early-log and mid-log phase growth, but it increases by two- to ten-fold as the culture approaches saturation density. Nalidixate-induced levels are 20- to 50-fold higher, and 100-fold higher in a constitutive tif- spr- mutant. Induction of recA protein synthesis by nalidixic acid, which normally requires functional recBC enzyme, also occurs in recB- and recC- cells by pathways activated by mutation in the sbcA and sbcB indirect suppressors. In recB- sbcA- mutants, exonuclease VIII, the recE gene product, is required for induction of recA protein. Abolition of exonuclease I activity by mutation in sbcB allows induction of recA protein by nalidixate in recB- and recC- cells. Mutation in recF does not affect induction by nalidixate in RecBC+ cells, but it enables induction to occur in RecBC- cells, suggesting that recF gene product is involved in regulation of recA protein.

Characterization of long patch excision repair of DNA in ultraviolet-irradiated Escherichia coli: an inducible function under rec-lex control

Excision repair in ultraviolet-irradiated wild-type Escherichia coli produces a bimodal distribution of repair patch sizes in the DNA. Approximately 99% of the repair events result in short patches of 20-30 nucleotides produced by a constitutive repair system. The remaining 1% result in patches which are at least 1,500 nucleotides in length. This long patch repair is shown to be a damage-inducible process under control of the rec-lex regulatory circuit. The kinetics of the two processes differ; short patch synthesis begins immediately after irradiation and is virtually completed prior to synthesis of the majority of the long patches. Long patch repair synthesis is a linear function of UV dose up to a plateau at 60 J/m2, and hence each long patch event is the consequence of a single UV-induced lesion. Long patch repair does not appear to be necessarily error-prone, since no alteration in repair synthesis occurs as a result of a mutation umuC- which renders cells nonmutable by UV. Evidence is presented suggesting that DNA polymerase I is responsible for both long and short patch synthesis in wild type cells under inducing conditions. In the absence of polymerase I the constitutive patch size averages 80-90 nucleotides, and this distribution is unchanged by induction.