A rapid method for cloning mutagenic DNA repair genes: isolation of umu-complementing genes from multidrug resistance plasmids R391, R446b, and R471a

Novel GLRA1 missense mutation (P250T) in dominant hyperekplexia defines an intracellular determinant of glycine receptor channel gating

Missense mutations as well as a null allele of the human glycine receptor alpha1 subunit gene GLRA1 result in the neurological disorder hyperekplexia [startle disease, stiff baby syndrome, Mendelian Inheritance in Man (MIM) #149400]. In a pedigree showing dominant transmission of hyperekplexia, we identified a novel point mutation C1128A of GLRA1. This mutation encodes an amino acid substitution (P250T) in the cytoplasmic loop linking transmembrane regions M1 and M2 of the mature alpha1 polypeptide. After recombinant expression, homomeric alpha1(P250T) subunit channels showed a strong reduction of maximum whole-cell chloride currents and an altered desensitization, consistent with a prolonged recovery from desensitization. Apparent glycine binding was less affected, yielding an approximately fivefold increase in Ki values. Topological analysis predicts that the substitution of proline 250 leads to the loss of an angular polypeptide structure, thereby destabilizing open channel conformations. Thus, the novel GLRA1 mutant allele P250T defines an intracellular determinant of glycine receptor channel gating.

Inhibition of homologous recombination by the plasmid MucA'B complex

By its functional interaction with a RecA polymer, the mutagenic UmuD'C complex possesses an antirecombination activity. We show here that MucA'B, a functional homolog of the UmuD'C complex, inhibits homologous recombination as well. In F- recipients expressing MucA'B from a Ptac promoter, Hfr x F- recombination decreased with increasing MucA'B concentrations down to 50-fold. In damage-induced pKM101-containing cells expressing MucA'B from the native promoter, recombination between a UV-damaged F lac plasmid and homologous chromosomal DNA decreased 10-fold. Overexpression of MucA'B together with UmuD'C resulted in a synergistic inhibition of recombination. RecA[UmuR] proteins, which are resistant to UmuD'C inhibition of recombination, are inhibited by MucA'B while promoting MucA'B-promoted mutagenesis efficiently. The data suggest that MucA'B and UmuD'C contact a RecA polymer at distinct sites. The MucA'B complex was more active than UmuD'C in promoting UV mutagenesis, yet it did not inhibit recombination more than UmuD'C does. The enhanced mutagenic potential of MucA'B may result from its inherent superior capacity to assist DNA polymerase in trans-lesion synthesis. In the course of this work, we found that the natural plasmid pKM101 expresses around 45,000 MucA and 13,000 MucB molecules per lexA(Def) cell devoid of LexA. These molecular Muc concentrations are far above those of the chromosomally encoded Umu counterparts. Plasmid pKM101 belongs to a family of broad-host-range conjugative plasmids. The elevated levels of the Muc proteins might be required for successful installation of pKM101-like plasmids into a variety of host cells.

Novel GLRA1 missense mutation (P250T) in dominant hyperekplexia defines an intracellular determinant of glycine receptor channel gating

Missense mutations as well as a null allele of the human glycine receptor alpha1 subunit gene GLRA1 result in the neurological disorder hyperekplexia [startle disease, stiff baby syndrome, Mendelian Inheritance in Man (MIM) #149400]. In a pedigree showing dominant transmission of hyperekplexia, we identified a novel point mutation C1128A of GLRA1. This mutation encodes an amino acid substitution (P250T) in the cytoplasmic loop linking transmembrane regions M1 and M2 of the mature alpha1 polypeptide. After recombinant expression, homomeric alpha1(P250T) subunit channels showed a strong reduction of maximum whole-cell chloride currents and an altered desensitization, consistent with a prolonged recovery from desensitization. Apparent glycine binding was less affected, yielding an approximately fivefold increase in Ki values. Topological analysis predicts that the substitution of proline 250 leads to the loss of an angular polypeptide structure, thereby destabilizing open channel conformations. Thus, the novel GLRA1 mutant allele P250T defines an intracellular determinant of glycine receptor channel gating.

Lon-mediated proteolysis of the Escherichia coli UmuD mutagenesis protein: in vitro degradation and identification of residues required for proteolysis

Most SOS mutagenesis in Escherichia coli is dependent on the UmuD and UmuC proteins. Perhaps as a consequence, the activity of these proteins is exquisitely regulated. The intracellular level of UmuD and UmuC is normally quite low but increases dramatically in lon- strains, suggesting that both proteins are substrates of the Lon protease. We report here that the highly purified UmuD protein is specifically degraded in vitro by Lon in an ATP-dependent manner. To identify the regions of UmuD necessary for Lon-mediated proteolysis, we performed 'alanine-stretch' mutagenesis on umuD and followed the stability of the mutant protein in vivo. Such an approach allowed us to localize the site(s) within UmuD responsible for Lon-mediated proteolysis. The primary signal is located between residues 15 and 18 (FPLF), with an auxiliary site between residues 26 and 29 (FPSP), of the amino terminus of UmuD. Transfer of the amino terminus of UmuD (residues 1-40) to an otherwise stable protein imparts Lon-mediated proteolysis, thereby indicating that the amino terminus of UmuD is sufficient for Lon recognition and the ensuing degradation of the protein.

Regulation of UmuD cleavage: role of the amino-terminal tail

An essential step in SOS mutagenesis is the RecA-mediated posttranslational processing of UmuD-like proteins to the shorter, but mutagenically active, UmuD'-like proteins. Interestingly, the UmuD-like proteins undergo posttranslational processing at different rates. For example, although the Escherichia coli UmuD (UmuDEc) and the Salmonella typhimurium UmuD (UmuDSt) proteins are 73% identical, UmuDSt is processed in vivo at a significantly faster rate than the UmuDEc protein. Here, we report experiments aimed at investigating the molecular basis of these phenotypic differences. The faster rate of UmuDSt cleavage probably does not result solely from a better interaction with RecA, since we observed that, in vitro, UmuDSt undergoes RecA-independent autocatalytic processing about four-times faster than UmuDEc. By constructing chimeric UmuD proteins, we determined that the amino-terminal tail of the UmuD proteins proximal to the Cys24-Gly25 cleavage site is mainly responsible for the difference in UmuDSt and UmuDEc cleavage rates. Site-directed mutagenesis of the UmuDEc protein suggests that most of the enhanced cleavage observed with the UmuDSt protein can be attributed to the presence of a Pro23 residue, juxtaposed to the cleavage site in UmuDSt. Furthermore, this proline residue appears to result in a UmuD protein that is a much better substrate for intermolecular cleavage. These findings clearly implicate the N-terminal tail of the UmuD-like proteins as playing an important and unexpected regulatory function in the maturation of the mutagenically active UmuD'-like mutagenesis proteins.

Novel Escherichia coli umuD' mutants: structure-function insights into SOS mutagenesis

Although it has been 10 years since the discovery that the Escherichia coli UmuD protein undergoes a RecA-mediated cleavage reaction to generate mutagenically active UmuD', the function of UmuD' has yet to be determined. In an attempt to elucidate the role of UmuD' in SOS mutagenesis, we have utilized a colorimetric papillation assay to screen for mutants of a hydroxylamine-treated, low-copy-number umuD' plasmid that are unable to promote SOS-dependent spontaneous mutagenesis. Using such an approach, we have identified 14 independent umuD' mutants. Analysis of these mutants revealed that two resulted from promoter changes which reduced the expression of wild-type UmuD', three were nonsense mutations that resulted in a truncated UmuD' protein, and the remaining nine were missense alterations. In addition to the hydroxylamine-generated mutants, we have subcloned the mutations found in three chromosomal umuD1, umuD44, and umuD77 alleles into umuD'. All 17 umuD' mutants resulted in lower levels of SOS-dependent spontaneous mutagenesis but varied in the extent to which they promoted methyl methanesulfonate-induced mutagenesis. We have attempted to correlate these phenotypes with the potential effect of each mutation on the recently described structure of UmuD'.

Intermolecular cleavage by UmuD-like mutagenesis proteins

The activity of a number of proteins is regulated by self-processing reactions. Elegant examples are the cleavage of the prokaryotic LexA and lambdaCI transcriptional repressors and the UmuD-like mutagenesis proteins. Various studies support the hypothesis that LexA and lambdaCI cleavage reactions are predominantly intramolecular in nature. The recently described crystal structure of the Escherichia coli UmuD' protein (the posttranslational cleavage product of the UmuD protein) suggests, however, that the region of the protein corresponding to the cleavage site is at least 50 A away from the catalytic active site. We considered the possibility, therefore, that the UmuD-like proteins might undergo self-processing that, in contrast to LexA and lambdaCI, occurs via an intermolecular rather than intramolecular reaction. To test this hypothesis, we introduced into E. coli compatible plasmids with mutations at either the cleavage or the catalytic site of three UmuD-like proteins. Cleavage of these proteins only occurs in the presence of both plasmids, indicating that the reaction is indeed intermolecular in nature. Furthermore, this intermolecular reaction is completely dependent upon the multifunctional RecA protein and leads to the restoration of cellular mutagenesis in nonmutable E. coli strains. Intermolecular cleavage of a biotinylated UmuD active site mutant was also observed in vitro in the presence of the wild-type UmuD' protein, indicating that in addition to the intact UmuD protein, the normal cleavage product (UmuD') can also act as a classical enzyme.

Unusual insertion element polymorphisms in the promoter and terminator regions of the mucAB-like genes of R471a and R446b

We have previously identified umu-complementing genes on two incL/M plasmids, R471a and R446b (C. Ho et al., J. Bacteriol., 175 (1993) 5411-5419). Molecular analysis of these genes revealed that they are more structurally and functionally related to mucAB from the incN plasmid pKM101 than to other members of the previously identified Umu-like family. As a consequence, we have termed these new homologs mucAB(R471a) and mucAB(R446b) respectively. Interestingly, while the location of the mucAB-like genes is essentially the same in both R471a and R446b, the regions immediately flanking the mucAB-like genes are highly polymorphic. For example, 5' to mucAB(R471a) we found an insert that appears to be a novel retroelement encoding a putative reverse transcriptase (RT). This RT is related to the reverse transcriptases encoded by group II introns but is embedded in a retron-like context. Immediately 3' to the mucAB(R471a) locus is a putative insertion element of a sparsely-dispersed class not previously reported from enteric bacteria. Both the RT and insertion element are absent in R446b. These observations suggest that the mucAB-like genes from R471a and R446b are located within regions of the R-plasmids that perhaps were once (or still are) mobile genetic elements. Such observations might help explain the distribution of umu-like genes on R-plasmids and bacterial chromosomes.

Characterization of DinR, the Bacillus subtilis SOS repressor

In Bacillus subtilis, exposure to DNA damage and the development of natural competence lead to the induction of the SOS regulon. It has been hypothesized that the DinR protein is the cellular repressor of the B. subtilis SOS system due to its homology to the Escherichia coli LexA transcriptional repressor. Indeed, comparison of DinR and its homologs from gram-negative and -positive bacteria revealed conserved structural motifs within the carboxyl-terminal domain that are believed to be important for autocatalysis of the protein. In contrast, regions within the DNA binding domain were conserved only within gram-negative or -positive genera, which possibly explains the differences in the sequence specificities between gram-negative and gram-positive SOS boxes. The hypothesis that DinR is the repressor of the SOS regulon in B. subtilis has been tested through overexpression, purification, and characterization of the DinR protein. Like E. coli LexA, B. subtilis DinR undergoes an autocatalytic reaction at alkaline pH at a siscile Ala91-Gly92 bond. The cleavage reaction can also be mediated in vitro under more physiological conditions by the E. coli RecA protein. By using electrophoretic mobility shift assays, we demonstrated that DinR interacts with the previously characterized SOS box of the B. subtilis recA gene, but not with sequences containing single base pair mutations within the SOS box. Together, these observations strongly suggest that DinR is the repressor of the SOS regulon in B. subtilis.

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'.

Identification of a DinB/UmuC homolog in the archeon Sulfolobus solfataricus

To date, eight closely related homologs of the Escherichia coli UmuC protein have been identified. All of these homologs appear to play critical roles in damage-inducible mutagenesis in enterobacteriaceae. Recently, a distantly related UmuC-homolog, DinB, has also been identified in E. coli. Using the polymerase chain reaction together with degenerate primers designed against conserved regions found in UmuC-like proteins, we have identified a new member of the UmuC-superfamily in the archeon Sulfolobus solfataricus. This new homolog shows high sequence similarity to DinB and a lower level of similarity to UmuC. As a consequence, we have called this new gene dbh (dinB homolog). Analysis of approximately 2.7 kb DNA encompassing the dbh region revealed several open reading frames (orfs). One, encoding a putative ribokinase, was located immediately upstream of dbh. This orf overlaps the dbh gene by 4 bp suggesting that both proteins might be coordinately expressed. Further upstream of the ribokinase-dbh locus was another orf encoding a potential ATPase homologous to two uncharacterized S. cerevisiae proteins (YD9346.02c and SC38KCXVI_20) and another E. coli DNA repair protein, RuvB. While this is the first report of a UmuC-like homolog in an archeon, we detected additional homologs using protein sequence comparisons in Gram-positive bacteria, cyanobacteria, and among potential human EST products, indicating that UmuC-related proteins comprise a ubiquitous superfamily of proteins probably involved in DNA repair and mutagenesis.

Induction of SOS-independent mutations by benzo[a]pyrene treatment in Escherichia coli cells deficient in MutY or MutM DNA glycosylases: possible role of oxidative lesions

The induction of SOS-independent mutations by exposure to benzo[a]pyrene (BaP) was screened in Escherichia coli strains lacking SOS mutagenesis proteins and deficient in MutY or MutM glycosylases, which prevent mutations by 8-hydroxyguanine (GO lesion). Mutagenicity assays, performed in the presence of S9 mix, indicated a great increase in the reversion of the trpE65 ochre mutation in both mutY and mutY mutM strains, whereas a lower increase was observed in a mutM strain. This mutability by BaP was observed in either uvr- or uvr+ strains. Moreover, it was increased when strains carried a deletion of the oxyR gene that abolished the OxyR response to oxidative stress, and reduced in the presence of the oxyR2 allele that rendered constitutive such response. It is suggested that SOS-independent mutations in cells treated with BaP arise from adenine/GO mispairs. The interaction of radical scavengers with BaP ultimate metabolites could cause oxidative stress capable of producing GO lesions. Strains lacking mutagenesis proteins and deficient in base excision repair systems, such as those dependent on MutY and MutM glycosylases, could be useful for screening the induction of SOS-independent mutations.

Specificity of spontaneous and t-butyl hydroperoxide-induced mutations in delta oxyR strains of Escherichia coli differing with respect to the SOS mutagenesis proficiency and to the MutY and MutM functions

Mutations induced by oxidative DNA damage appear to occur by two pathways, differing in their dependence on SOS mutagenesis. We have analysed the specificity of mutations produced by each pathway. Base substitutions generating extragenic suppressors were characterized in Trp+ revertants of Escherichia coli strains carrying the trpE65 ochre mutation, which were hypersensitive to oxidative mutagenesis due to a deletion of the oxyR gene. In strain IC3821, containing MucA/B proteins and therefore proficient for SOS mutagenesis, the more frequently scored base substitutions, either spontaneous or induced by t-butyl hydroperoxide (BuOOH), were T:A-A:T transversions, followed by G:C-A:T transitions, while the frequency of G:C-T:A transversions was lower. This SOS-dependent mutability could be promoted by abasic sites. In strains IC3894 (mutY) and IC3981 (mutY mutM), lacking mutagenesis proteins, SOS-independent revertants arose almost exclusively via G:C-T:A transversions probably derived from oxidatively damaged 8-oxoguanine/adenine mispairs. Formation of these mispairs in IC3894 and IC3981 would be enhanced by BuOOH treatment since it caused a significant increase in the revertant number. Strains IC3894 and IC3981 could have a complementary role to that of IC3821 to analyse the mutagenicity and the mutational specificity of oxidants.

Analysis of the mutagenic properties of the UmuDC, MucAB and RumAB proteins, using a site-specific abasic lesion

The mucAB and rumAB loci have been shown to promote mutagenesis to a greater extent than the structurally and functionally homologous Escherichia coli umuDC operon. We have analyzed the basis of this enhanced mutagenesis by comparing the influence of these operons, relative to umuDC, on the mutagenic properties of each of two abasic sites, specifically located in a single-stranded vector. Experiments with these vectors are useful analytical tools because they provide independent estimates of the efficiency of translesion synthesis and of the relative frequencies of each type of nucleotide insertion or other kind of mutagenic event. The umuDC, mucAB, and rumAB genes were expressed from their natural LexA-regulated promoter on low-copy-number plasmids in isogenic strains carrying a umuDC deletion. In addition, plasmids expressing the UmuD'C, MucA'B, or RumA'B proteins were also used. Compared to umuDC, the chief effect of mucAB was to increase the efficiency of translesion synthesis past the abasic site. The enhanced capacity of mucAB for translesion synthesis depended about equally on an inherently greater capacity to promote this process and on a greater susceptibility of the MucA protein to proteolytic processing. The RumA protein also appeared to be more susceptible to proteolytic processing, but the inherent capacity of the Rum products for translesion synthesis was no greater than that of UmuDC. dAMP was inserted opposite one of the two abasic sites studied at a somewhat greater frequency in strains expressing rum (82%) compared to those expressing umu (72%), which might result in higher mutation frequencies in rumAB than in umuDC strains.

In vivo stability of the Umu mutagenesis proteins: a major role for RecA

The Escherichia coli Umu proteins play critical roles in damage-inducible SOS mutagenesis. To avoid any gratuitous mutagenesis, the activity of the Umu proteins is normally kept to a minimum by tight transcriptional and posttranslational regulation. We have, however, previously observed that compared with an isogenic recA+ strain, the steady-state levels of the Umu proteins are elevated in a recA730 background (R. Woodgate and D. G. Ennis, Mol. Gen. Genet. 229:10-16, 1991). We have investigated this phenomenon further and find that another coprotease-constitutive (recA*) mutant, a recA432 strain, exhibits a similar phenotype. Analysis revealed that the increased steady-state levels of the Umu proteins in the recA* strains do indeed reflect an in vivo stabilization of the proteins. We have investigated the basis for the phenomenon and find that the mutant RecA* protein stabilizes the Umu proteins by not only converting the labile UmuD protein to the much more stable (and mutagenically active) UmuD' protein but by directly stabilizing UmuD' itself. In contrast, UmuC does not appear to be directly stabilized by RecA* but is instead dramatically stabilized in the presence of UmuD'. On the basis of these observations, we suggest that formation of a UmuD'C-RecA*-DNA quaternary complex protects the UmuD'C proteins from proteolytic degradation and as a consequence helps to promote the switch from error-free to error-prone mechanisms of DNA repair.

Analysis of chimeric UmuC proteins: identification of regions in Salmonella typhimurium UmuC important for mutagenic activity

Unlike Escherichia coli, the closely related bacterium Salmonella typhimurium is relatively unresponsive to the mutagenic effects of DNA-damaging agents. Previous experiments have suggested that these phenotypic differences might result from reduced activity of the S. typhimurium UmuC protein. To investigate this possibility, we have taken advantage of the high degree of homology between the UmuC proteins of E. coli and S. typhimurium and have constructed a series of plasmid-encoded chimeric proteins. The possibility that the phenotypic differences might be due to differential expression of the respective UmuC proteins was eliminated by constructing chimeric proteins that retained the first 25 N-terminal amino acids of either of the UmuC proteins (and presumably the same translational signals), but substituting the remaining 397 C-terminal amino acids with the corresponding segments from the reciprocal operon. Constructs expressing mostly E. coli UmuC were moderately proficient for mutagenesis whereas those expressing mostly S. typhimurium UmuC exhibited much lower frequencies of mutation, indicating that the activity of the UmuC protein of S. typhimurium is indeed curtailed. The regions responsible for this phenotype were more precisely localized by introducing smaller segments of the S. typhimurium UmuC protein into the UmuC protein of E. coli. While some regions could be interchanged with few or no phenotypic effects, substitution of residues 212-395 and 396-422 of E. coli UmuC with those from S. typhimurium resulted in reduced mutability, while substitution of residues 26-59 caused a dramatic loss of activity. We suggest, therefore, that the primary cause for the poor mutability of S. typhimurium can be attributed to mutations located within residues 26-59 of the S. typhimurium UmuC protein.

Construction and characterization of two lexA mutants of Salmonella typhimurium with different UV sensitivities and UV mutabilities

Salmonella typhimurium has a SOS regulon which resembles that of Escherichia coli. recA mutants of S. typhimurium have already been isolated, but no mutations in lexA have been described yet. In this work, two different lexA mutants of S. typhimurium LT2 have been constructed on a sulA background to prevent cell death and further characterized. The lexA552 and lexA11 alleles contain an insertion of the kanamycin resistance fragment into the carboxy- and amino-terminal regions of the lexA gene, respectively. SOS induction assays indicated that both lexA mutants exhibited a LexA(Def) phenotype, although SOS genes were apparently more derepressed in the lexA11 mutant than in the lexA552 mutant. Like lexA(Def) of E. coli, both lexA mutations only moderately increased the UV survival of S. typhimurium, and the lexA552 strain was as mutable as the lexA+ strain by UV in the presence of plasmids encoding MucAB or E. coli UmuDC (UmuDCEc). In contrast, a lexA11 strain carrying any of these plasmids was nonmutable by UV. This unexpected behavior was abolished when the lexA11 mutation was complemented in trans by the lexA gene of S. typhimurium. The results of UV mutagenesis correlated well with those of survival to UV irradiation, indicating that MucAB and UmuDCEc proteins participate in the error-prone repair of UV damage in lexA552 but not in lexA11. These intriguing differences between the mutagenic responses of lexA552 and lexA11 mutants to UV irradiation are discussed, taking into account the different degrees to which the SOS response is derepressed in these mutants.

Substitution of mucAB or rumAB for umuDC alters the relative frequencies of the two classes of mutations induced by a site-specific T-T cyclobutane dimer and the efficiency of translesion DNA synthesis

We have examined the effect of replacing umuDC with mucAB or rumAB on the mutagenic properties of a T-T cyclobutane dimer in an attempt to determine the molecular basis for the differences in UV-induced mutagenesis that are associated with these structurally and functionally related genes. A single-stranded vector carrying a site-specific T-T cis-syn cyclobutane dimer was transfected into a set of isogenic Escherichia coli delta umuDC strains harboring low-copy-number plasmids expressing UmuDC, MucAB, RumAB, or their genetically engineered and mutagenically active counterparts UmuD'C, MucA'B, and RumA'B, respectively. Although the overall mutation frequency was similar for all strains, the relative frequencies of the two classes of mutation induced by the T-T dimer varied according to the mutagenesis operon expressed. In umuDC strains, 3' T-->A mutations outnumbered 3' T-->C mutations, but the reverse was true for the mucAB and rumAB strains. We also found that the T-T dimer was bypassed with differing efficiencies in unirradiated cells expressing wild-type UmuDC, MucAB, and RumAB proteins. These differences can probably be attributed to the relative efficiency of the normal cellular posttranslational activation of UmuD, MucA, and RumA, respectively, since recombinant constructs expressing the mutagenically active UmuD'C, MucA'B, and RumA'B proteins all promoted similarly high levels of bypass in UV-irradiated cells. These results suggest that the UmuD'/UmuC complex and its homologs may differ in their relative abilities to promote elongation from T - T and T - G mismatched termini. Alternatively, they may differentially influence the efficiency with which these mismatches are edited or influence nucleotide insertion by the catalytic subunit of the DNA polymerase III.

The ultraviolet-sensitizing function of plasmid R391 interferes with a late step of postreplication repair in Escherichia coli

The conjugative plasmid R391 increases the UV radiation sensitivity of wild-type, uvrA, and lexA cells of Escherichia coli, but not recA strains. To investigate the UV-sensitizing function of R391, we examined the effect of R391 on the repair of DNA daughter-strand gaps and on the UV radiation sensitivities of various repair and/or recombination-deficient mutants. The presence of R391 did not significantly inhibit the repair of DNA daughter-strand gaps in uvrB cells. The presence of R391 increased the UV radiation sensitivity of uvrA, uvrA recF, uvrB, uvrB recF, uvrB recB, and uvrB ssb-113 cells to UV irradiation, but did not significantly increase the UV radiation sensitivity of uvrA ruvA and uvrA ruvC strains. Based on these results, we propose that the UV-sensitizing activity of R391 acts by inhibiting or interfering with the ruvABC-mediated postsynapsis step of recombinational repair.

Transfer of the IncJ plasmid R391 to recombination deficient Escherichia coli K12: evidence that R391 behaves as a conjugal transposon

A study of the IncJ plasmid R391 confirmed a low frequency of transfer between recombination proficient (recA+) Escherichia coli (10(-5) donor -1). Reanalysis of its transfer to recombination deficient (recA) E. coli revealed an equivalent transfer frequency to and from all mutants tested. Extrachromosomal DNA could not be detected in either recA+ or recA transconjugants, while R391 proved refractory to curing in both backgrounds implying a high degree of stability. The integration of R391 into a specific region of the chromosome was demonstrated by its transfer as part of the exogenote mobilised from the transfer origins of Hfr strains BW6165 and JC158. Transfer of R391 coupled to recA independent chromosomal integration has significant implications as to the nature and classification of the element. We propose that R391 behaves like a conjugal transposon.

Detection of oxidative mutagens in strains of Escherichia coli deficient in the OxyR or MutY functions: dependence on SOS mutagenesis

The Escherichia coli strain IC3821, a delta oxyR derivative of WP2 uvrA trpE65, was more sensitive to mutagenicity promoted by t-butyl hydroperoxide and cumene hydroperoxide than the isogenic oxyR+ control. Mutagenicity of menadione, a redox cycling quinone, was clearly detected in the delta oxyR strain, whereas only a slight mutagenic response was observed in the oxyR+ strain. Plumbagin, another quinone structurally similar to menadione, was not mutagenic to any of the strains. These mutagenic responses appeared to involve the SOS processing of oxidative DNA lesions and were mediated by MucA/B proteins more efficiently than by UmuD/C. In cells lacking mutagenesis proteins, induction of SOS-independent mutations by the two alkyl hydroperoxides required a deficiency in the MutY DNA glycosylase and was increased by the presence of the delta oxyR mutation. In contrast, the two quinones assayed were unable to induce SOS-independent mutations in the MutY-deficient strains.

Characterization of the umu-complementing operon from R391

In addition to conferring resistances to antibiotics and heavy metals, certain R factors carry genes involved in mutagenic DNA repair. These plasmid-encoded genes are structurally and functionally related to the chromosomally encoded umuDC genes of Escherichia coli and Salmonella typhimurium. Three such plasmid operons, mucAB, impCAB, and samAB, have been characterized at the molecular level. Recently, we have identified three additional umu-complementing operons from IncJ plasmid R391 and IncL/M plasmids R446b and R471a. We report here the molecular characterization of the R391 umu-complementing operon. The nucleotide sequence of the minimal R plasmid umu-complementing (rum) region revealed an operon of two genes, rumA(R391) and rumB(R391), with an upstream regulatory signal strongly resembling LexA-binding sites. Phylogenetic analysis revealed that the RumAB(R391) proteins are approximately equally diverged in sequence from the chromosomal UmuDC proteins and the other plasmid-encoded Umu-like proteins and represent a new subfamily. Genetic characterization of the rumAB(R391) operon revealed that in recA+ and recA1730 backgrounds, the rumAB(R391) operon was phenotypically indistinguishable from mucAB. In contrast, however, the rumAB(R391) operon gave levels of mutagenesis that were intermediate between those given by mucAB and umuDC in a recA430 strain. The latter phenotype was shown to correlate with the reduced posttranslational processing of the RumA(R391) protein to its mutagenically active form, RumA'(R391). Thus, the rumAB(R391) operon appears to possess characteristics that are reminiscent of both chromosome and plasmid-encoded umu-like operons.

Increased mutability by oxidative stress in OxyR-deficient Escherichia coli and Salmonella typhimurium cells: clonal occurrence of the mutants during growth on nonselective media

Escherichia coli and Salmonella typhimurium strains deficient in the OxyR-regulated adaptive response to oxidative stress were used to study the mode in which spontaneous SOS-dependent mutations are generated in a distressed bacterial population. When assayed on supplemented selective medium, the E. coli strain IC3821 (trpE65), carrying the delta oxyR30 mutation and containing the plasmid pRW144 (mucA/B), showed a frequency of spontaneous Trp+ revertants similar to that of the oxyR+ control. Instead, the IC3821 strain exhibited an enhancement in the clonal occurrence of spontaneous revertants arising at random during growth on a nonselective medium. A similar enhancement was observed for the S. typhimurium strain TA4125 (hisG428 delta oxyR2). The mutator effect observed in oxyR- cells would be induced by an increased background of reactive oxygen species; it provides a model for studying the mutability of a cell population constantly exposed to mutation-inducing agents. In the IC3821 strain, revertants were induced by t-butyl hydroperoxide with higher efficiency than in oxyR+. We suggest that strain IC3821 could be useful for the detection of SOS-dependent mutagenesis induced by chemical oxidants.

Salmonella typhimurium LT7 and LT2 strains carrying the imp operon on colIa

The imp operon is carried on a transmissible plasmid, ColIa, in original isolates of Salmonella typhimurium LT7. LT2 strain recipients of F' factors from LT7 strains harboring ColIa can acquire ColIa and imp under nonselective conditions. Thus, S. typhimurium LT2 strains that have received plasmids by conjugal transfer from LT7 strains might be inadvertently harboring ColI factors.

MucAB but not UmuDC proteins enhance -2 frameshift mutagenesis induced by N-2-acetylaminofluorene at alternating GC sequences

N-2-acetylaminofluorene has been shown efficiently to induce both -1 and -2 frameshift mutations in Escherichia coli as well as in mammalian cells. In E. coli, the genetic characteristics of -1 and -2 frameshift mutations were found to be distinct. The -1 frameshift mutation pathway occurs at monotonous runs of G residues (i.e. GGG-->GG). This pathway exhibits the same genetic requirements as UV light-induced base substitution mutagenesis. Indeed, optimal mutagenesis requires the expression of both UmuDC and the activated form of RecA. The -2 frameshift mutation pathway operates at short alternating GpC sequences, such as the NarI sequence (i.e. GGCGCC-->GGCC). In contrast to the -1 frameshift mutation pathway, optimal induction does not require the UmuDC and RecA proteins. This pathway involves a LexA-repressed function tentatively called Npf (for NarI processing factor). In this paper, we show that MucAB efficiently stimulates the -2 frameshift mutation pathway. However, unlike the Npf pathway, MucAB-mediated stimulation requires expression of the RecA protein.

Isolation and characterization of novel plasmid-encoded umuC mutants

Most inducible mutagenesis in Escherichia coli is dependent upon the activity of the UmuDC proteins. The role of UmuC in this process is poorly understood, possibly because of the limited number of genetically characterized umuC mutants. To better understand the function of the UmuC protein in mutagenic DNA repair, we have isolated several novel plasmid-encoded umuC mutants. A multicopy plasmid that expressed UmuC at physiological levels was constructed and randomly mutagenized in vitro by exposure to hydroxylamine. Mutated plasmids were introduced into the umu tester strain RW126, and 16 plasmids that were unable to promote umuC-dependent spontaneous mutator activity were identified by a colorimetric papillation assay. Interestingly, these plasmid mutants fell into two classes: (i) 5 were expression mutants that produced either too little or too much wild-type UmuC protein, and (ii) 11 were plasmids with structural changes in the UmuC protein. Although hydroxylamine mutagenesis was random, most of the structural mutants identified in the screen were localized to two regions of the UmuC protein; four mutations were found in a stretch of 30 amino acids (residues 133 to 162) in the middle of the protein, while four other mutations (three of which resulted in a truncated UmuC protein) were localized in the last 50 carboxyl-terminal amino acid residues. These new plasmid umuC mutants, together with the previously identified chromosomal umuC25, umuC36, and umuC104 mutations that we have also cloned, should prove extremely useful in dissecting the genetic and biochemical activities of UmuC in mutagenic DNA repair.