Cleavage of bacteriophage phi 80 CI repressor by RecA protein

Molecular Basis of Lysis-Lysogeny Decisions in Gram-Positive Phages

Temperate bacteriophages (phages) are viruses of bacteria. Upon infection of a susceptible host, a temperate phage can establish either a lytic cycle that kills the host or a lysogenic cycle as a stable prophage. The life cycle pursued by an infecting temperate phage can have a significant impact not only on the individual host bacterium at the cellular level but also on bacterial communities and evolution in the ecosystem. Thus, understanding the decision processes of temperate phages is crucial. This review delves into the molecular mechanisms behind lysis-lysogeny decision-making in Gram-positive phages. We discuss a variety of molecular mechanisms and the genetic organization of these well-understood systems. By elucidating the strategies used by phages to make lysis-lysogeny decisions, we can improve our understanding of phage-host interactions, which is crucial for a variety of studies including bacterial evolution, community and ecosystem diversification, and phage therapeutics. Expected final online publication date for the Annual Review of Microbiology, Volume 75 is October 2021. Please see http://www.annualreviews.org/page/journal/pubdates for revised estimates.

Studies on the gene regulation involved in the lytic-lysogenic switch in Staphylococcus aureus temperate bacteriophage Phi11

Antirepressor proteins of bacteriophages are chiefly involved in interfering with the function of the repressor protein and forcing the bacteriophage to adopt the lytic cycle. The genome of Staphylococcus aureus phage, Phi11 has already been sequenced; from the genome sequence, we amplified gp07 gene and analysed its involvement in the developmental pathway of Phi11. Our results indicate that Gp07 functions as a novel antirepressor and regulates the developmental pathway of Phi11 by enhancing the binding of the Cro repressor protein to its cognate operator. We also report our finding that the CI repressor protein of Phi11 binds to the putative operator of Gp07 and regulates its expression. We further report that S.aureus transcriptional repressor LexA and coprotease RecA play a crucial role in the lytic-lysogenic switching in Phi11. We also identified that the N-terminal domain (Bro-N) of Gp07 is actually responsible for enhancing the binding of Cro repressor to its cognate operator. Our results suggest that Phi11 prophage induction is different from other bacteriophages. This study furnishes a first-hand report regarding the regulation involved in the developmental pathway of Phi11.

Cloning and high-level expression of Thermus thermophilus RecA in E. coli: purification and novel use in HBV diagnostics

We studied the role of Thermus thermophilus Recombinase A (RecA) in enhancing the PCR signals of DNA viruses such as Hepatitis B virus (HBV). The RecA gene of a thermophilic eubacterial strain, T. thermophilus, was cloned and hyperexpressed in Escherichia coli. The recombinant RecA protein was purified using a single heat treatment step without the use of any chromatography steps, and the purified protein (>95%) was found to be active. The purified RecA could enhance the polymerase chain reaction (PCR) signals of HBV and improve the detection limit of the HBV diagnosis by real time PCR. The yield of recombinant RecA was ∼35mg/L, the highest yield reported for a recombinant RecA to date. RecA can be successfully employed to enhance detection sensitivity for the diagnosis of DNA viruses such as HBV, and this methodology could be particularly useful for clinical samples with HBV viral loads of less than 10IU/mL, which is interesting and novel.

Long 5' untranslated regions regulate the RNA stability of the deep-sea filamentous phage SW1

Virus production in the deep-sea environment has been found to be high, and viruses have been suggested to play significant roles in the overall functioning of this ecosystem. Nevertheless, little is known about these viruses, including the mechanisms that control their production, which makes them one of the least understood biological entities on Earth. Previously, we isolated the filamentous phage SW1, whose virus production and gene transcription were found to be active at low temperatures, from a deep-sea bacterium, Shewanella piezotolerans WP3. In this study, the operon structure of phage SW1 is presented, which shows two operons with exceptionally long 5′ and 3′ untranslated regions (UTRs). In addition, the 5′UTR was confirmed to significantly influence the RNA stability of the SW1 transcripts. Our study revealed novel regulation of the operon and led us to propose a unique regulatory mechanism for Inoviruses. This type of RNA-based regulation may represent a mechanism for significant viral production in the cold deep biosphere.

RecA protein plays a role in the chemotactic response and chemoreceptor clustering of Salmonella enterica

The RecA protein is the main bacterial recombinase and the activator of the SOS system. In Escherichia coli and Salmonella enterica sv. Typhimurium, RecA is also essential for swarming, a flagellar-driven surface translocation mechanism widespread among bacteria. In this work, the direct interaction between RecA and the CheW coupling protein was confirmed, and the motility and chemotactic phenotype of a S. Typhimurium ΔrecA mutant was characterized through microfluidics, optical trapping, and quantitative capillary assays. The results demonstrate the tight association of RecA with the chemotaxis pathway and also its involvement in polar chemoreceptor cluster formation. RecA is therefore necessary for standard flagellar rotation switching, implying its essential role not only in swarming motility but also in the normal chemotactic response of S. Typhimurium.

DNA repair and genome maintenance in Bacillus subtilis

From microbes to multicellular eukaryotic organisms, all cells contain pathways responsible for genome maintenance. DNA replication allows for the faithful duplication of the genome, whereas DNA repair pathways preserve DNA integrity in response to damage originating from endogenous and exogenous sources. The basic pathways important for DNA replication and repair are often conserved throughout biology. In bacteria, high-fidelity repair is balanced with low-fidelity repair and mutagenesis. Such a balance is important for maintaining viability while providing an opportunity for the advantageous selection of mutations when faced with a changing environment. Over the last decade, studies of DNA repair pathways in bacteria have demonstrated considerable differences between Gram-positive and Gram-negative organisms. Here we review and discuss the DNA repair, genome maintenance, and DNA damage checkpoint pathways of the Gram-positive bacterium Bacillus subtilis. We present their molecular mechanisms and compare the functions and regulation of several pathways with known information on other organisms. We also discuss DNA repair during different growth phases and the developmental program of sporulation. In summary, we present a review of the function, regulation, and molecular mechanisms of DNA repair and mutagenesis in Gram-positive bacteria, with a strong emphasis on B. subtilis.

Genome of Enterobacteriophage Lula/phi80 and insights into its ability to spread in the laboratory environment

The novel temperate bacteriophage Lula, contaminating laboratory Escherichia coli strains, turned out to be the well-known lambdoid phage phi80. Our previous studies revealed that two characteristics of Lula/phi80 facilitate its spread in the laboratory environment: cryptic lysogen productivity and stealthy infectivity. To understand the genetics/genomics behind these traits, we sequenced and annotated the Lula/phi80 genome, encountering an E. coli-toxic gene revealed as a gap in the sequencing contig and analyzing a few genes in more detail. Lula/phi80's genome layout copies that of lambda, yet homology with other lambdoid phages is mostly limited to the capsid genes. Lula/phi80's DNA is resistant to cutting with several restriction enzymes, suggesting DNA modification, but deletion of the phage's damL gene, coding for DNA adenine methylase, did not make DNA cuttable. The damL mutation of Lula/phi80 also did not change the phage titer in lysogen cultures, whereas the host dam mutation did increase it almost 100-fold. Since the high phage titer in cultures of Lula/phi80 lysogens is apparently in response to endogenous DNA damage, we deleted the only Lula/phi80 SOS-controlled gene, dinL. We found that dinL mutant lysogens release fewer phage in response to endogenous DNA damage but are unchanged in their response to external DNA damage. The toxic gene of Lula/phi80, gamL, encodes an inhibitor of the host ATP-dependent exonucleases, RecBCD and SbcCD. Its own antidote, agt, apparently encoding a modifier protein, was found nearby. Interestingly, Lula/phi80 lysogens are recD and sbcCD phenocopies, so GamL and Agt are part of lysogenic conversion.

Coevolution of bacteria and their viruses

Coevolution between bacteria and bacteriophages can be characterized as an infinitive constant evolutionary battle (phage-host arm race), which starts during phage adsorption and penetration into host cell, continues during phage replication inside the cells, and remains preserved also during prophage lysogeny. Bacteriophage may exist inside the bacterial cells in four forms with different evolutionary strategies: as a replicating virus during the lytic cycle, in an unstable carrier state termed pseudolysogeny, as a prophage with complete genome during the lysogeny, or as a defective cryptic prophage. Some defensive mechanisms of bacteria and virus countermeasures are characterized, and some evolutionary questions concerning phage-host relationship are discussed.

Cleavage of bacteriophage lambda cI repressor involves the RecA C-terminal domain

The SOS response to DNA damage in Escherichia coli involves at least 43 genes, all under the control of the LexA repressor. Activation of these genes occurs when the LexA repressor cleaves itself, a reaction catalyzed by an active, extended RecA filament formed on DNA. It has been shown that the LexA repressor binds within the deep groove of this nucleoprotein filament, and presumably, cleavage occurs in this groove. Bacteriophages, such as lambda, have repressors (cI) that are structural homologs of LexA and also undergo self-cleavage when SOS is induced. It has been puzzling that some mutations in RecA that affect the cleavage of repressors are in the C-terminal domain (CTD) far from the groove where cleavage is thought to occur. In addition, it has been shown that the rate of cleavage of cI by RecA is dependent upon both the substrate on which RecA is polymerized and the ATP analog used. Electron microscopy and three-dimensional reconstructions show that the conformation and dynamics of RecA's CTD are also modulated by the polynucleotide substrate and ATP analog. Under conditions where the repressor cleavage rates are the highest, cI is coordinated within the groove by contacts with RecA's CTD. These observations provide a framework for understanding previous genetic and biochemical observations.

LexA Cleavage Is Required for CTX Prophage Induction

The physiologic conditions and molecular interactions that control phage production have been studied in few temperate phages. We investigated the mechanisms that regulate production of CTXphi, a temperate filamentous phage that infects Vibrio cholerae and encodes cholera toxin. In CTXphi lysogens, the activity of P(rstA), the only CTXphi promoter required for CTX prophage development, is repressed by RstR, the CTXvphi repressor. We found that the V. cholerae SOS response regulates CTXvphi production. The molecular mechanism by which this cellular response to DNA damage controls CTXphi production differs from that by which the E. coli SOS response controls induction of many prophages. UV-stimulated CTXphi production required RecA-dependent autocleavage of LexA, a repressor that controls expression of numerous host DNA repair genes. LexA and RstR both bind to and repress P(rstA). Thus, CTXphi production is controlled by a cellular repressor whose activity is regulated by the cell's response to DNA damage.

Complete genomic nucleotide sequence of the temperate bacteriophage Aa Phi 23 of Actinobacillus actinomycetemcomitans

The entire double-stranded DNA genome of the Actinobacillus actinomycetemcomitans bacteriophage Aa Phi 23 was sequenced. Linear DNA contained in the phage particles is circularly permuted and terminally redundant. Therefore, the physical map of the phage genome is circular. Its size is 43,033 bp with an overall molar G+C content of 42.5 mol%. Sixty-six potential open reading frames (ORFs) were identified, including an ORF resulting from a translational frameshift. A putative function could be assigned to 23 of them. Twenty-three other ORFs share homologies only with hypothetical proteins present in several bacteria or bacteriophages, and 20 ORFs seem to be specific for phage Aa Phi 23. The organization of the phage genome and several genetic functions share extensive similarities to that of the lambdoid phages. However, Aa Phi 23 encodes a DNA adenine methylase, and the DNA packaging strategy is more closely related to the P22 system. The attachment sites of Aa Phi 23 (attP) and several A. actinomycetemcomitans hosts (attB) are 49 bp long.

At the birth of molecular radiation biology

Rational thinking builds on feelings, too. This article starts with a tribute to Richard Setlow, an eminent scientist; it retraces as well some studies in molecular genetics that helped to understand basic questions of radiation biology. In the mid-1950s, the induction of a dormant virus (prophage) by irradiation of its host was an intriguing phenomenon. Soon, it was found that prophage induction results from the inactivation of the prophage repressor. Similarly, a score of induced cellular SOS functions were found to be induced when the LexA repressor is inactivated. Repressor inactivation involves the formation of a newly formed distinctive structure: a RecA-polymer wrapped around single-stranded DNA left by the arrest of replication at damaged sites. By touching this RecA nucleofilament, the LexA repressor is inactivated, triggering the sequential expression of SOS functions. The RecA nucleofilament acts as a chaperone, allowing recombinational repair to occur after nucleotide excision repair is over. The UmuD'C complex, synthesized slowly and parsimoniously, peaks at the end of recombinational repair, ready to be positioned at the tip of a RecA nucleofilament, placing the UmuD'C complex right at a lesion. At this location, UmuD'C prevents recombinational repair, and now acts as an error-prone paucimerase that fills the discontinuity opposite the damaged DNA. Finally, the elimination of lesions from the path of DNA polymerase, allows the resumption of DNA replication, and the SOS repair cycle switches to a normal cell cycle.

Family values in the age of genomics: comparative analyses of temperate bacteriophage HK022

HK022 is a temperate coliphage related to phage lambda. Its chromosome has been completely sequenced, and several aspects of its life cycle have been intensively studied. In the overall arrangement, expression, and function of most of its genes, HK022 broadly resembles lambda and other members of the lambda family. Upon closer view, significant differences emerge. The differences reveal alternative strategies used by related phages to cope with similar problems and illuminate previously unknown regulatory and structural motifs. HK022 prophages protect lysogens from superinfection by producing a sequence-specific RNA binding protein that prematurely terminates nascent transcripts of infecting phage. It uses a novel RNA-based mechanism to antiterminate its own early transcription. The HK022 protein shell is strengthened by a complex pattern of covalent subunit interlinking to form a unitary structure that resembles chain-mail armour. Its integrase and repressor proteins are similar to those of lambda, but the differences provide insights into the evolution of biological specificity and the elements needed for construction of a stable genetic switch.

Recombinational repair of DNA damage in Escherichia coli and bacteriophage lambda

Although homologous recombination and DNA repair phenomena in bacteria were initially extensively studied without regard to any relationship between the two, it is now appreciated that DNA repair and homologous recombination are related through DNA replication. In Escherichia coli, two-strand DNA damage, generated mostly during replication on a template DNA containing one-strand damage, is repaired by recombination with a homologous intact duplex, usually the sister chromosome. The two major types of two-strand DNA lesions are channeled into two distinct pathways of recombinational repair: daughter-strand gaps are closed by the RecF pathway, while disintegrated replication forks are reestablished by the RecBCD pathway. The phage lambda recombination system is simpler in that its major reaction is to link two double-stranded DNA ends by using overlapping homologous sequences. The remarkable progress in understanding the mechanisms of recombinational repair in E. coli over the last decade is due to the in vitro characterization of the activities of individual recombination proteins. Putting our knowledge about recombinational repair in the broader context of DNA replication will guide future experimentation.

The UmuD' protein filament and its potential role in damage induced mutagenesis

BACKGROUND

Damage induced 'SOS mutagenesis' may occur transiently as part of the global SOS response to DNA damage in bacteria. A key participant in this process is the UmuD protein, which is produced in an inactive from but converted to the active form, UmuD', by a RecA-mediated self-cleavage reaction. UmuD', together with UmuC and activated RecA (RecA*), enables the DNA polymerase III holoenzyme to replicate across chemical and UV induced lesions. The efficiency of this reaction depends on several intricate protein-protein interactions.

RESULTS

Recent X-ray crystallographic analysis shows that in addition to forming molecular dimers, the N- and C-terminal tails of UmuD' extend from a globular beta structure to associate and produce crystallized filaments. We have investigated this phenomenon and find that these filaments appear to relate to biological activity. Higher order oligomers are found in solution with UmuD', but not with UmuD nor with a mutant of UmuD' lacking the extended N terminus. Deletion of the N terminus of UmuD' does not affect its ability to form molecular dimers but does severely compromise its ability to interact with a RecA-DNA filament and to participate in mutagenesis. Mutations in the C terminus of UmuD' result in both gain and loss of function for mutagenesis.

CONCLUSIONS

The activation of UmuD to UmuD' appears to cause a large conformational change in the protein which allows it to form oligomers in solution at physiologically relevant concentrations. Properties of these oligomers are consistent with the filament structures seen in crystals of UmuD'.

Interactions of Escherichia coli UmuD with activated RecA analyzed by cross-linking UmuD monocysteine derivatives

SOS mutagenesis in Escherichia coli requires the participation of a specialized system involving the activated form of UmuD (UmuD'), UmuC, RecA, and DNA polymerase III proteins. We have used a set of monocysteine derivatives of UmuD (M. H. Lee, T. Ohta, and G. C. Walker, J. Bacteriol. 176:4825-4837, 1994) and the cysteine-specific photoactive cross-linker p-azidoiodoacetanilide (AIA) to study not only the interactions of intact UmuD in the homodimer but also the interactions of UmuD with activated RecA. The reactivities of the individual UmuD monocysteine derivatives with AIA were similar to their reactivities with iodoacetate. The relative efficiencies of cross-linking of the AIA-modified monocysteine UmuD derivatives in the homodimer form are also consistent with our previous conclusions concerning the relative closeness of various UmuD residues to the dimer interface. With respect to the UmuD-RecA interface, the AIA-modified VC34 and SC81 monocysteine derivatives cross-linked most efficiently with RecA, indicating that positions 34 and 81 of UmuD are closer to the RecA interface than the other positions we tested. The AIA-modified SC57, SC67, and SC112 monocysteine derivatives cross-linked moderately efficiently with RecA. Neither C24, the wild-type UmuD that has a cysteine located at the Cys-24-Gly-25 cleavage site, nor SC60, the UmuD monocysteine derivative with a cysteine substitution at the position of the putative active-site residue, was able to cross-link with RecA, suggesting that RecA need not directly interact with residues involved in the cleavage reaction. SC19, located in the N-terminal fragment of UmuD that is cleaved, and LC44 also did not cross-link efficiently with RecA.

Inhibition of RecA-mediated cleavage in covalent dimers of UmuD

Disulfide-cross-linked UmuD2 derivatives were cleaved poorly upon incubation with activated RecA. Reducing the disulfide bonds prior to incubating the derivatives with RecA dramatically increased their extent of cleavage. These observations suggest that the UmuD monomer is a better substrate for the RecA-mediated cleavage reaction than the dimer.

Involvement of umuDCST genes in nitropyrene-induced -CG frameshift mutagenesis at the repetitive CG sequence in the hisD3052 allele of Salmonella typhimurium

Expression of the umuDC operon is required for UV and most chemical mutagenesis in Escherichia coli. The closely related species Salmonella typhimurium has two sets of umuDC-like operons, umuDCST on the chromosome and samAB on a 60-MDa cryptic plasmid. The roles of the umuDC-like operons in chemically induced frameshift mutagenesis of the hisD3052 allele of S. typhimurium were investigated. Introduction of a pBR322-derived plasmid carrying umuDCST increased the rate of reversion of hisD3052, following treatment with 1-nitropyrene (1-NP) or 1,8-dinitropyrene (1,8-DNP) tenfold and fivefold, respectively, whereas it did not substantially increase the rate of reversion induced by other frameshift mutagens, i.e. 2-nitrofluorene (2-NF) and 2-amino-3-methyldipyrido[1,2-a:3',2'-d]imidazole (Glu-P-1). Introduction of a pBR322-derived plasmid carrying samAB did not increase the incidence of reversion of hisD3052 observed with any of the mutagens examined. Deletion of umuDCST substantially lowered the reversion rate induced by 1-NP or 1,8-DNP, but it did not affect reversion induced by 2-NF, Glu-P-1 or N-hydroxyacetylaminofluorene (N-OH-AAF). Deletion of samAB had little impact on reversion incidence induced by any of the five frameshift mutagens. DNA amplification using the polymerase chain reaction technique followed by restriction enzyme analysis using BssHII, suggested that the mutations induced by the five frameshift mutagens were all CG deletions at the CGCGCGCG sequence in hisD3052. These results suggest that umuDCST, but not samAB, is involved in the -2 frameshift mutagenesis induced by 1-NP and 1,8-DNP at the repetitive CG sequence, whereas neither operon participates in induction of the same type of mutations by 2-NF, Glu-P-1 or N-OH-AAF.

Analysis of recA mutants with altered SOS functions

The Escherichia coli RecA protein has at least three roles in SOS mutagenesis: (1) derepression of the SOS regulon by mediating LexA cleavage; (2) activation of the UmuD mutagenesis protein by mediating its cleavage; and (3) targeting the Umu-like mutagenesis proteins to DNA. Using a combined approach of molecular and physiological assays, it is now possible to determine which of the three defined steps has been altered in any recA mutant. In this study, we have focused on the ability of six particular recA mutants (recA85, recA430, recA432, recA433, recA435 and recA730) to perform these functions. Phenotypically, recA85 and recA730 were similar in that in lexA+ and lexA(Def) backgrounds, they exhibited constitutive coprotease activity towards the UmuD mutagenesis protein. Somewhat surprisingly, in a lexA(Ind-) background, UmuD cleavage was damage inducible, suggesting that the repressed level of the RecA* protein cannot spontaneously achieve a fully activated state. Although isolated in separate laboratories, the nucleotide sequence of the recA85 and recA730 mutants revealed that they were identical, with both alleles possessing a Glu38-->Lys change in the mutant protein. The recA430, recA433 and recA435 mutants were found to be defective for both lambda mutagenesis and UmuD cleavage. lambda mutagenesis was fully restored, however, to the recA433 and recA435 strains by a low copy plasmid expressing the mutagenically active UmuD' protein. In contrast, lambda mutagenesis was only partially restored to a recA430 strain by a high copy UmuD' plasmid, suggesting that RecA430 may also be additionally defective in targeting the Umu proteins to DNA. Sequence analysis of the recA433 and recA435 alleles revealed identical substitutions resulting in Arg243-->His. The recA432 mutation had a complex phenotype in that its coprotease activity towards UmuD depended upon the lexA background: inducible in lexA+ strains, inefficient in lexA(Ind-) cells and constitutive in a lexA(Def) background. The recA432 mutant was found to carry a Pro119-->Ser substitution, a residue believed to be at the RecA subunit interface; thus this complex phenotype may result from alterations in the assembly of RecA multimers.

Nucleotide sequence, organization and expression of rdgA and rdgB genes that regulate pectin lyase production in the plant pathogenic bacterium Erwinia carotovora subsp. carotovora in response to DNA-damaging agents

In most soft-rotting Erwinia spp., including E. carotovora subsp. carotovora strain 71 (Ecc71), production of the plant cell wall degrading enzyme pectin lyase (Pnl) is activated by DNA-damaging agents such as mitomycin C (MC). Induction of Pnl production in Ecc71 requires a functional recA gene and the rdg locus. DNA sequencing and RNA analyses revealed that the rdg locus contains two regulatory genes, rdgA and rdgB, in separate transcriptional units. There is high homology between RdgA and repressors of lambdoid phages, specially phi 80. RdgB, however, has significant homology with transcriptional activators of Mu phage. Both RdgA and RdgB are also predicted to possess helix-turn-helix motifs. By replacing the rdgB promoter with the IPTG-inducible tac promoter, we have determined that rdgB by itself can activate Pnl production in Escherichia coli. However, deletion analysis of rdg+ DNA indicated that, when driven by their native promoters, functions of both rdgA and rdgB are required for the induction of pnlA expression by MC treatment. While rdgB transcription occurs only after MC treatment, a substantial level of rdgA mRNA is detected in the absence of MC treatment. Moreover, upon induction with MC, a new rdgA mRNA species, initiated from a different start site, is produced at a high level. Thus, the two closely linked rdgA and rdgB genes, required for the regulation of Pnl production, are expressed differently in Ecc71.

Biochemistry of homologous recombination in Escherichia coli

Homologous recombination is a fundamental biological process. Biochemical understanding of this process is most advanced for Escherichia coli. At least 25 gene products are involved in promoting genetic exchange. At present, this includes the RecA, RecBCD (exonuclease V), RecE (exonuclease VIII), RecF, RecG, RecJ, RecN, RecOR, RecQ, RecT, RuvAB, RuvC, SbcCD, and SSB proteins, as well as DNA polymerase I, DNA gyrase, DNA topoisomerase I, DNA ligase, and DNA helicases. The activities displayed by these enzymes include homologous DNA pairing and strand exchange, helicase, branch migration, Holliday junction binding and cleavage, nuclease, ATPase, topoisomerase, DNA binding, ATP binding, polymerase, and ligase, and, collectively, they define biochemical events that are essential for efficient recombination. In addition to these needed proteins, a cis-acting recombination hot spot known as Chi (chi: 5'-GCTGGTGG-3') plays a crucial regulatory function. The biochemical steps that comprise homologous recombination can be formally divided into four parts: (i) processing of DNA molecules into suitable recombination substrates, (ii) homologous pairing of the DNA partners and the exchange of DNA strands, (iii) extension of the nascent DNA heteroduplex; and (iv) resolution of the resulting crossover structure. This review focuses on the biochemical mechanisms underlying these steps, with particular emphases on the activities of the proteins involved and on the integration of these activities into likely biochemical pathways for recombination.

A monocysteine approach for probing the structure and interactions of the UmuD protein

UmuD participates in a variety of protein-protein interactions that appear to be essential for its role in UV mutagenesis. To learn about these interactions, we have initiated an approach based on the construction of a series of monocysteine derivatives of UmuD and have carried out experiments exploring the chemistry of the unique thiol group in each derivative. In vivo and in vitro characterizations indicate that these proteins have an essentially native structure. In proposing a model for the interactions of UmuD in the homodimer, we have made the following assumptions: (i) the conformations of the mutant proteins are similar to that of the wild type, and (ii) the differences in reactivity of the mutant proteins are predominantly due to the positional effects of the single cysteine substitutions. The model proposes the following. The region including the Cys-24-Gly-25 cleavage site, Val-34, and Leu-44 are closer to the interface than the other positions tested as suggested by the relative ease of dimer cross-linking of the monocysteine derivatives at these positions by oxidation with iodine (I2) and by reaction with bis-maleimidohexane. The mutant with a Ser-to-Cys change at position 60 (SC60) is similar in iodoacetate reactivity to the preceding derivatives but cross-links less efficiently by I2 oxidation. This suggests that Ser-60, the site of the putative nucleophile in the cleavage reaction, is located further from the dimer interface or in a cleft region. Both Ser-19, located in the N-terminal fragment of UmuD that is removed by RecA-mediated cleavage, and Ser-67 are probably not as close to the dimer interface, since they are cross-linked more easily with bis-maleimidohexane than with I2. The SC67 mutant phenotype also suggests that this position is less important in RecA-mediated cleavage but more important in a subsequent role for UmuD in mutagenesis. Ala-89, Gln-100, and Asp-126 are probably not particularly solvent accessible and may play important roles in protein architecture.

LexA and lambda Cl repressors as enzymes: specific cleavage in an intermolecular reaction

During the SOS response, LexA repressor is inactivated by specific cleavage. Although cleavage requires RecA protein in vivo, RecA acts indirectly as a coprotease by stimulating an inherent self-cleavage activity of LexA. In lambda lysogens, cleavage of lambda Cl repressor in a similar but far slower reaction results in prophage induction. We describe an intermolecular cleavage reaction in which the C-terminal fragment of LexA acted as an enzyme to cleave other molecules of LexA. The C-terminal fragment of lambda repressor cleaved the LexA substrates about as efficiently as did the LexA enzyme, suggesting that the slow rate of Cl self-cleavage results from a weak interaction between its cleavage site and the active site.

Regulation of pyocin genes in Pseudomonas aeruginosa by positive (prtN) and negative (prtR) regulatory genes

Most strains of Pseudomonas aeruginosa produce various types of bacteriocins (pyocins), namely, R-, F-, and S-type pyocins. The production of all types of pyocins was shown to be regulated by positive (prtN) and negative (prtR) regulatory genes. The prtN gene activates the expression of various pyocin genes, probably by the interaction of its product with the DNA sequences conserved in the 5' noncoding regions of the pyocin genes. The prtR gene represses the expression of the prtN gene, and its product, predicted from the nucleotide sequence, has a structure characteristic of phage repressors and seems to be inactivated by the RecA protein activated by DNA damage. A model for the regulation of the pyocin genes is proposed.

In vitro analysis of mutant LexA proteins with an increased rate of specific cleavage

Specific cleavage of LexA repressor plays a crucial role in the SOS response of Escherichia coli. In vivo, cleavage requires an activated form of RecA protein. However, previous work has shown that the mechanism of cleavage is unusual, in that the chemistry of cleavage is probably carried out by residues in the repressor, and not those in RecA; RecA appears to facilitate this reaction, acting as a coprotease. We recently described a new type of lexA mutation, a class termed lexA (IndS) and here called IndS, that confers an increased rate of in vivo cleavage. Here, we have characterized the in vitro cleavage of these IndS mutant proteins, and of several double mutant proteins containing an IndS mutation and one of several mutations, termed Ind-, that decrease the rate of cleavage. We found, first, that the autodigestion reaction for the IndS mutant proteins had a higher maximum rate and a lower apparent pKa than wild-type LexA. Second, the IndS mutations had little or no effect on the rate of RecA-mediated cleavage, measured at low protein concentrations, implying that the value of Kcat/Km was unaffected. Third, the rate of autodigestion for the double-mutant proteins, relative to wild-type, was about that rate predicted from the product of the effects of the two single mutations. Finally, by contrast, these proteins displayed the same rate of RecA-mediated cleavage as did the single Ind- mutant protein. We interpret these data to mean that the IndS mutations mimic to some extent the effect of RecA on cleavage, perhaps by favoring a conformational change in LexA. We present and analyze a model that embodies these conclusions.

Roles of Salmonella typhimurium umuDC and samAB in UV mutagenesis and UV sensitivity

Expression of the umuDC operon is required for UV mutagenesis and most chemical mutagenesis in Escherichia coli. The closely related species Salmonella typhimurium has two sets of umuDC-like operons; the samAB operon is located in a 60-MDa cryptic plasmid, while the S. typhimurium umuDC (umuDCST) operon resides in a chromosome. The roles of these two umuDC-like operons in UV mutagenesis and UV sensitivity of S. typhimurium were investigated. A pBR322-derived plasmid carrying the samAB operon more efficiently restored UV mutability to a umuD44 strain and a umuC122::Tn5 strain of E. coli than a plasmid carrying the umuDCST operon did. When the umuDCST operon was specifically deleted from the chromosome of S. typhimurium TA2659, the resulting strain was not UV mutable and was more sensitive to the killing effect of UV irradiation than the parent strain was. Curing of the 60-MDa cryptic plasmid carrying the samAB operon did not influence the UV mutability of strain TA2659 but did increase its resistance to UV killing. A pSC101-derived plasmid carrying the samAB operon did not restore UV mutability to a umuD44 strain of E. coli, whereas pBR322- or pBluescript-derived plasmids carrying the samAB operon efficiently did restore UV mutability. We concluded that the umuDCST operon plays a major role in UV mutagenesis in S. typhimurium and that the ability of the samAB operon to promote UV mutagenesis is strongly affected by gene dosage. Possible reasons for the poor ability of samAB to promote UV mutagenesis when it is present on low-copy-number plasmids are discussed.

C-terminal truncated Escherichia coli RecA protein RecA5327 has enhanced binding affinities to single- and double-stranded DNAs

RecA5327 is a truncated RecA protein that is lacking 25 amino acid residues from the C-terminal end. The expression of RecA5327 protein in the cell resulted in the constitutive induction of SOS functions without damage to the DNA. Purified RecA5327 protein effectively promoted the LexA repressor cleavage reaction and ATP hydrolysis at a lower concentration of single-stranded DNA than that required for wild-type RecA protein. A DNA binding study showed that RecA5327 has about ten times higher affinity for single-stranded DNA than does the wild-type RecA protein. Moreover RecA5327 protein binds stably to double-stranded (ds) DNA in conditions where the wild-type RecA protein could not bind. The binding of RecA5327 protein to dsDNA was associated with the unwinding of dsDNA, suggesting that RecA5327 binds to dsDNA in the same manner as does the wild-type protein. The fact that RecA5327 does not bind stoichiometrically but forms short filaments on dsDNA suggests that it nucleates to dsDNA much more frequently than does the wild-type protein. The role of the 25 C-terminal residues, in the regulation of RecA binding to DNA, is discussed.

Mechanism of specific LexA cleavage: autodigestion and the role of RecA coprotease

Specific LexA cleavage can occur under two different conditions: RecA-mediated cleavage requires an activated form of RecA, while an intramolecular self-cleavage termed autodigestion proceeds spontaneously at high pH and does not involve RecA. The two cleavage reactions are closely related. We postulate that RecA stimulates autodigestion rather than acting as a typical protease, and it is proposed to term this activity 'RecA coprotease' to emphasize this indirect role. The mechanism of autodigestion is similar to that of a serine protease, and RecA appears to act by reducing the pKa of a critical lysine residue LexA. A new class of mutants, termed lexA (IndS), is described; these mutations increase the rate of LexA cleavage.

Introduction of a UV-damaged replicon into a recipient cell is not a sufficient condition to produce an SOS-inducing signal

Three models have been proposed for the nature of the SOS-inducing signal in E. coli. One model postulates that degradation products of damaged DNA generate an SOS-inducing signal; another model surmises that the very lesions produced by UV damage constitute the SOS-inducing signal in vivo; a third model proposes that DNA damage is processed upon DNA replication to form single-stranded DNA (the SOS signal) that activates RecA protein. We tested the models by measuring SOS induction produced by introducing into recipient cells the UV-damaged DNA of 2 constructed phagemids. We used phagemids since they transferred DNA to the recipients with 100% efficiency. The origin of replication of the phagemids was either oriC from the E. coli chromosome, or oriF from F plasmid. Replication of the oriC phagemid was dependent on methylation. A UV-damaged oriC phagemid failed to induce SOS functions in a recipient cell whereas an oriF phagemid did induce them. Our results disprove the first and the second model proposed for the nature of the SOS-inducing signal. The failure of a UV-damaged oriC replicon to induce SOS can be explained by the third model if one assumes that replication of a UV-damaged oriC plasmid does not generate single-stranded DNA as does the E. coli chromosome after UV damage.

Cloning and characterization of DNA damage-inducible promoter regions from Bacillus subtilis

DNA damage-inducible (din) genes in Bacillus subtilis are coordinately regulated and together compose a global regulatory network that has been termed the SOS-like or SOB regulon. To elucidate the mechanisms of SOB regulation, operator/promoter regions from three din loci (dinA, dinB, and dinC) of B. subtilis were cloned. Operon fusions constructed with these cloned din promoter regions rendered reporter genes damage inducible in B. subtilis. Induction of all three din promoters was dependent upon a functional RecA protein. Analysis of these fusions has localized sequences required for damage-inducible expression of the dinA, dinB, and dinC promoters to within 120-, 462-, and 139-bp regions, respectively. Comparison of the nucleotide sequences of these three din promoters with the recA promoter, as well as with the promoters of other loci associated with DNA repair in B. subtilis, has identified the consensus sequence GAAC-N4-GTTC as a putative SOB operator site.

Biochemical and biological function of Escherichia coli RecA protein: behavior of mutant RecA proteins

The recA protein of E coli participates in several diverse biological processes and promotes a variety of complex in vitro reactions. A careful comparison of the phenotypic behavior of E coli recA mutations to the biochemical properties of the corresponding mutant proteins reveals a close parallel both between recombination phenotype and DNA strand exchange and renaturation activities, and between inducible phenomena and repressor cleavage activity. The biochemical alterations manifest by the mutant recA proteins are reflected in the strength of their interaction with ssDNA. The defective mutant recA proteins fail to properly assume the high-affinity DNA-binding state that is characteristic of the wild-type protein and, consequently, form less stable complexes with DNA. The mutant proteins displaying an 'enhanced' activity bind ssDNA with approximately the same affinity as the wild-type protein but, due to altered protein-protein interactions, they associate more rapidly with ssDNA. These changes proportionately affect the ability of recA protein to compete with SSB protein, to interact with dsDNA, and, perhaps, to bind repressor proteins. In turn, the DNA strand exchange, DNA renaturation, and repressor cleavage activities mirror these modifications.

Salmonella typhimurium has two homologous but different umuDC operons: cloning of a new umuDC-like operon (samAB) present in a 60-megadalton cryptic plasmid of S. typhimurium

Expression of the umuDC operon is required for UV and most chemical mutagenesis in Escherichia coli. The DNA which can restore UV mutability to a umuD44 strain and to a umuC122::Tn5 strain of E. coli has been cloned from Salmonella typhimurium TA1538. DNA sequence analysis indicated that the cloned DNA potentially encoded proteins with calculated molecular weights of 15,523 and 47,726 and was an analog of the E. coli umuDC operon. We have termed this cloned DNA the samAB (for Salmonella mutagenesis) operon and tentatively referred to the umuDC operon of S. typhimurium LT2 (C. M. Smith, W. H. Koch, S. B. Franklin, P. L. Foster, T. A. Cebula, and E. Eisenstadt, J. Bacteriol. 172:4964-4978, 1990; S. M. Thomas, H. M. Crowne, S. C. Pidsley, and S. G. Sedgwick, J. Bacteriol. 172:4979-4987, 1990) as the umuDCST operon. The samAB operon is 40% diverged from the umuDCST operon at the nucleotide level. Among five umuDC-like operons so far sequenced, i.e., the samAB, umuDCST, mucAB, impAB, and E. coli umuDC operons, the samAB operon shows the highest similarity to the impAB operon of TP110 plasmid while the umuDCST operon shows the highest similarity to the E. coli umuDC operon. Southern hybridization experiments indicated that (i) S. typhimurium LT2 and TA1538 had both the samAB and the umuDCST operons and (ii) the samAB operon was located in a 60-MDa cryptic plasmid. The umuDCST operon is present in the chromosome. The presence of the two homologous but different umuDC operons may be involved in the poor mutability of S. typhimurium by UV and chemical mutagens.

Dominant negative umuD mutations decreasing RecA-mediated cleavage suggest roles for intact UmuD in modulation of SOS mutagenesis

The products of the SOS-regulated umuDC operon are required for most UV and chemical mutagenesis in Escherichia coli. The UmuD protein shares homology with a family of proteins that includes LexA and several bacteriophage repressors. UmuD is posttranslationally activated for its role in mutagenesis by a RecA-mediated proteolytic cleavage that yields UmuD'. A set of missense mutants of umuD was isolated and shown to encode mutant UmuD proteins that are deficient in RecA-mediated cleavage in vivo. Most of these mutations are dominant to umuD+ with respect to UV mutagenesis yet do not interfere with SOS induction. Although both UmuD and UmuD' form homodimers, we provide evidence that they preferentially form heterodimers. The relationship of UmuD to LexA, lambda repressor, and other members of the family of proteins is discussed and possible roles of intact UmuD in modulating SOS mutagenesis are discussed.

Biochemical properties of the Escherichia coli recA430 protein. Analysis of a mutation that affects the interaction of the ATP-recA protein complex with single-stranded DNA

The biochemical properties of the recA430 protein have been examined and compared to those of wild-type recA protein. We find that, while the recA430 protein possesses ssDNA-dependent rATP activity, this activity is inhibited by the Escherichia coli single-stranded DNA binding protein (SSB protein) under many conditions that enhance wild-type recA protein rATPase hydrolysis. Stimulation of rATPase activity by SSB protein is observed only at high concentrations of both rATP (greater than 1 mM) and recA430 protein (greater than 5 microM). In contrast, stimulation of ssDNA-dependent dATPase activity by SSB protein is less sensitive to protein and nucleotide concentration. Consistent with the nucleotide hydrolysis data, recA430 protein can carry out DNA strand exchange in the presence of either rATP or dATP. However, in the presence of rATP, both the rate and the extent of DNA strand exchange by recA430 protein are greatly reduced compared to wild-type recA protein and are sensitive to recA430 protein concentration. This reduction is presumably due to the inability of recA430 protein to compete with SSB protein for ssDNA binding sites under these conditions. The cleavage of lexA repressor protein by recA430 protein is also sensitive to the nucleotide cofactor present and is completely inhibited by SSB protein when rATP is the cofactor but not when dATP is used. Finally, the steady-state affinity and the rate of association of the recA430 protein-ssDNA complex are reduced, suggesting that the mutation affects the interaction of the ATP-bound form of recA protein with ssDNA. This alteration is the likely molecular defect responsible for inhibition of recA430 protein rATP-dependent function by SSB protein. The biochemical properties observed in the presence of dATP and SSB protein, i.e. the reduced levels of both DNA strand exchange activity and cleavage of lexA repressor protein, are consistent with the phenotypic behavior of recA430 mutations.

Genetic analyses of cellular functions required for UV mutagenesis in Escherichia coli

In Escherichia coli, most UV and chemical mutagenesis is not a passive process and requires the participation of the umuD and umuC gene products. However, the molecular mechanism of UV mutagenesis is not yet understood and the roles of the UmuD and UmuC proteins have not been elucidated. The umuDC operon is induced by UV irradiation and regulated as part of the SOS response. Genetic evidence now indicates that RecA-mediated cleavage activates UmuD for its role in mutagenesis. The COOH-terminal fragment of UmuD is both necessary and sufficient for this role. The RecA protein appears to have a third role in UV mutagenesis besides mediating the cleavage of LexA and UmuD at the time of SOS induction. In addition, we have obtained evidence which indicates that the GroEL and GroES proteins also play a role in UV mutagenesis. Similarities of the amino acid sequence of UmuD to the sequence of gene 45 protein of bacteriophage T4 and of the sequence of UmuC to those of the gene 44 and gene 62 proteins suggest possible roles for UmuD and UmuC in mutagenesis that are supported by preliminary evidence.

Autodigestion and RecA-dependent cleavage of Ind- mutant LexA proteins

The LexA repressor of Escherichia coli undergoes a specific cleavage reaction in vivo, an event that leads to derepression of the SOS regulon and requires an activated form of RecA protein. In vitro, cleavage requires RecA at neutral pH; at alkaline pH, a spontaneous cleavage reaction termed autodigestion takes place. Both autodigestion and RecA-mediated cleavage cut the same bond, and are observed for the same set of substrates, suggesting that RecA acts indirectly to stimulate LexA self-cleavage at neutral pH, perhaps binding to LexA and acting as an allosteric effector. We previously isolated a set of lexA(Ind-) mutants that are deficient in in vivo RecA-mediated cleavage but retain significant repressor function. Here, we describe the in vitro cleavage of purified mutant proteins. All of those tested were deficient in both cleavage reactions. Although most of them were equally deficient in both reactions, some were more deficient in one reaction than the other. Several mutant proteins appeared to have defects in binding to RecA. Autodigestion of all but one of the poorly cleavable mutant proteins reached a maximum rate at pH around 10, as does wild-type LexA. The exception was KR156, which changed Lys156, a residue previously implicated in the mechanism of cleavage, to Arg, another basic residue: for this protein, the rate of autodigestion increased with pH at values above 11. RecA-mediated cleavage of KR156 was 1% the wild-type rate at pH 7, but increased with increasing pH to a plateau at pH 9.5, where the rate was 40% the wild-type rate. In contrast, an essentially constant rate was observed for wild-type LexA over the pH range 6 to 11. We suggest, first, that deprotonation of Arg156 and, by inference, Lys156 in the wild-type protein, is required for both autodigestion and RecA-mediated cleavage: and second, that RecA acts to reduce the pKa of Lys156, allowing efficient cleavage of wild-type repressor under physiological conditions.

New recA mutations that dissociate the various RecA protein activities in Escherichia coli provide evidence for an additional role for RecA protein in UV mutagenesis

To isolate strains with new recA mutations that differentially affect RecA protein functions, we mutagenized in vitro the recA gene carried by plasmid mini-F and then introduced the mini-F-recA plasmid into a delta recA host that was lysogenic for prophage phi 80 and carried a lac duplication. By scoring prophage induction and recombination of the lac duplication, we isolated new recA mutations. A strain carrying mutation recA1734 (Arg-243 changed to Leu) was found to be deficient in phi 80 induction but proficient in recombination. The mutation rendered the host not mutable by UV, even in a lexA(Def) background. Yet, the recA1734 host became mutable upon introduction of a plasmid encoding UmuD*, the active carboxyl-terminal fragment of UmuD. Although the recA1734 mutation permits cleavage of lambda and LexA repressors, it renders the host deficient in the cleavage of phi 80 repressor and UmuD protein. Another strain carrying mutation recA1730 (Ser-117 changed to Phe) was found to be proficient in phi 80 induction but deficient in recombination. The recombination defect conferred by the mutation was partly alleviated in a cell devoid of LexA repressor, suggesting that, when amplified, RecA1730 protein is active in recombination. Since LexA protein was poorly cleaved in the recA1730 strain while phage lambda was induced, we conclude that RecA1730 protein cannot specifically mediate LexA protein cleavage. Our results show that the recA1734 and recA1730 mutations differentially affect cleavage of various substrates. The recA1730 mutation prevented UV mutagenesis, even upon introduction into the host of a plasmid encoding UmuD* and was dominant over recA+. With respect to other RecA functions, recA1730 was recessive to recA+. This demonstrates that RecA protein has an additional role in mutagenesis beside mediating the cleavage of LexA and UmuD proteins.

Two forms of RecA-single-stranded DNA-adenosine 5'-O-(3-thiotriphosphate) complexes with different activities for cleavage of phage phi 80 cI repressor

The kinetics of cleavage of the phage phi 80 cI repressor by Escherichia coli RecA protein were studied. The rate of cleavage in the presence of single-stranded DNA (ssDNA) and either adenosine 5'-O-(3-thiotriphosphate) (ATP gamma S), ATP or dATP is very low in the first hour at 37 degrees C and then increases sharply as incubation continues. The initial rate of cleavage of the repressor is greatly increased by incubating the RecA protein with ssDNA prior to addition of ATP gamma S and the repressor. However, when ATP gamma S is present during preincubation of RecA protein with ssDNA, the stimulatory effect of preincubation is greatly reduced. This difference in the effect of preincubation in two different conditions can be explained by formation of RecA-ssDNA-ATP gamma S complexes with different activities for cleavage of the repressor. The active complex is formed by binding of ATP gamma S to a complex of RecA protein and ssDNA. However, when the RecA protein binds to ATP gamma S prior to its binding to ssDNA, the resulting complex has no or only very weak cleavage activity toward the repressor.

Stimulation of RecA-mediated cleavage of phage phi 80 cI repressor by deoxydinucleotides

The presence of either deoxyguanylyl-(3'----5')-deoxyguanosine (d(G-G] or deoxyadenylyl-(3'----5')-deoxyguanosine (d(A-G] greatly stimulates cleavage of the phage phi 80 cI repressor mediated by the Escherichia coli RecA protein in vitro. No other deoxydinucleoside monophosphate or riboguanylyl-(3'----5')-guanosine (r(G-G] affects the cleavage reaction. Neither the cleavage site of the phi 80 cI repressor nor the requirement for single-stranded DNA and ATP for cleavage is altered by d(G-G). Photoaffinity labeling experiments with 32P-labeled 5'-phosphoryl deoxyguanylyl deoxyguanosine (pd(G-G], which also stimulates cleavage, show that pd(G-G) bound to the repressor under the conditions in which the repressor is cleaved by RecA protein. The binding increases the affinity of the repressor for RecA protein and thus greatly stimulates repressor cleavage. The cleavage reactions of LexA and lambda cI repressors by RecA protein are not affected by d(G-G).

Organization of the early region of bacteriophage phi 80. Genes and proteins

An EcoRI segment containing the early region of bacteriophage phi 80 DNA that controls immunity and lytic growth was identified as a segment whose presence on a plasmid prevented growth of infecting phi 80cI phage. The nucleotide sequence of the segment (EcoRI-F) and adjacent regions was determined. Based on the positions of amber mutations and the sizes of some gene products, the reading frames for five genes were identified. From the relative locations of these genes in the genome, the properties of some isolated gene products, and the analysis of the structures of predicted proteins, the following phi 80 to lambda analogies are deduced: genes cI and cII to their lambda namesakes; gene 30 to cro; gene 15 to O; and gene 14 to P. An amber mutation by which gene 16 was defined is a nonsense mutation in the frame for gene 15 protein, excluding the presence of gene 16. An amber mutation in gene 14 or 15 inhibits phage DNA synthesis, as is the case with their lambda analogues, gene O or P. Some characteristics of proteins from the early region predicted from their primary structures and their possible functions are discussed.

Transcriptional regulation of early functions of bacteriophage phi 80

To study the expression of early functions of phi 80 phage, various segments from the early region were transcribed with RNA polymerase. Two major transcripts (from promoters PL and PR) whose synthesis was inhibited by the CI protein were identified. Synthesis of the third major transcript (from promoter PRM) was induced by the CI protein. These studies define two operator-promoter regions, OLPL and ORPRPRM. This mode of transcription from the early region is similar to that of phage lambda. However, there are the following major differences. One is the presence of a p-independent terminator of transcription from promoter PL located immediately after gene N and the absence of a p-dependent terminator that corresponds to tR1 of lambda. The other is the uniqueness of the structure and function of the operators. Both OL and OR operator regions consist of three sites, each containing a highly homologous 19 base-pair sequence. In each site, consensus octanucleotide sequences (half-sites) exhibit dyad symmetry, except in one of the sites where the sequences are arranged tandemly. In addition, each operator region also contains a single half-site. The modes of binding of the CI protein and gene 30 protein to these operator sites are quite different from those of the lambda proteins to the lambda operators. For example, binding of the phi 80 CI protein to the OR1 site is less tight than its binding to the OR2 or OR3 site. The gene 30 protein binds to the OR1 site as tightly as to the OR3 site.