The structure and function of the regulatory elements of the Escherichia coli uvrB gene

Amplified UvrA protein can ameliorate the ultraviolet sensitivity of an Escherichia coli recA mutant

When a recA strain of Escherichia coli was transformed with the multicopy plasmid pSF11 carrying the uvrA gene of E. coli, its extreme ultraviolet (UV) sensitivity was decreased. The sensitivity of the lexA1 (Ind(-)) strain to UV was also decreased by pSF11. The recA cells expressing Neurospora crassa UV damage endonuclease (UVDE), encoding UV-endonuclease, show UV resistance. On the other hand, only partial amelioration of UV sensitivity of the recA strain was observed in the presence of the plasmid pNP10 carrying the uvrB gene. Host cell reactivation of UV-irradiated lambda phage in recA cells with pSF11 was as efficient as that in wild-type cells. Using an antibody to detect cyclobutane pyrimidine dimers, we found that UV-irradiated recA cells removed dimers from their DNA more rapidly if they carried pSF11 than if they carried a vacant control plasmid. Using anti-UvrA antibody, we observed that the expression level of UvrA protein was about 20-fold higher in the recA strain with pSF11 than in the recA strain without pSF11. Our results were consistent with the idea that constitutive level of UvrA protein in the recA cells results in constitutive levels of active UvrABC nuclease which is not enough to operate full nucleotide excision repair (NER), thus leading to extreme UV sensitivity.

Role of the Escherichia coli nucleotide excision repair proteins in DNA replication

DNA polymerase I (PolI) functions both in nucleotide excision repair (NER) and in the processing of Okazaki fragments that are generated on the lagging strand during DNA replication. Escherichia coli cells completely lacking the PolI enzyme are viable as long as they are grown on minimal medium. Here we show that viability is fully dependent on the presence of functional UvrA, UvrB, and UvrD (helicase II) proteins but does not require UvrC. In contrast, delta polA cells grow even better when the uvrC gene has been deleted. Apparently UvrA, UvrB, and UvrD are needed in a replication backup system that replaces the PolI function, and UvrC interferes with this alternative replication pathway. With specific mutants of UvrC we could show that the inhibitory effect of this protein is related to its catalytic activity that on damaged DNA is responsible for the 3' incision reaction. Specific mutants of UvrA and UvrB were also studied for their capacity to support the PolI-independent replication. Deletion of the UvrC-binding domain of UvrB resulted in a phenotype similar to that caused by deletion of the uvrC gene, showing that the inhibitory incision activity of UvrC is mediated via binding to UvrB. A mutation in the N-terminal zinc finger domain of UvrA does not affect NER in vivo or in vitro. The same mutation, however, does give inviability in combination with the delta polA mutation. Apparently the N-terminal zinc-binding domain of UvrA has specifically evolved for a function outside DNA repair. A model for the function of the UvrA, UvrB, and UvrD proteins in the alternative replication pathway is discussed.

UvrA and UvrB suppress illegitimate recombination: synergistic action with RecQ helicase

Illegitimate recombination is a major cause of genetic instability in prokaryotes as well as in eukaryotes. This recombination usually occurs at a low frequency, but it is greatly enhanced by UV irradiation or other environmental stresses. DNA damages produced by these environmental stresses are thought to induce DNA double-strand breaks, leading to illegitimate recombination. In this paper we show that UV-induced illegitimate recombination is enhanced by mutations of nucleotide excision repair genes, uvrA or uvrB, and partially by uvrC mutation, but not by uvrD mutation. Unexpectedly, the recombination was enhanced by the uvrA uvrB double mutation even without UV irradiation, but the uvrB uvrC double mutation has not shown this effect, suggesting that illegitimate recombination is mostly suppressed by UvrA and UvrB. Moreover, illegitimate recombination was synergistically enhanced by the recQ uvrA double mutation. In addition, overproduction of the UvrA protein suppressed the hyperrecombination phenotype of the recQ or uvrB mutant, but it did not affect the UV-sensitive phenotype of the uvrB mutant. We concluded that the UvrAB complex suppresses illegitimate recombination in a pathway shared with RecQ helicase. In addition, UvrA protein alone can suppress illegitimate recombination in the pathway, in which RecQ helicase and UvrAB complex work. Possible functions of the proteins involved in these pathways are also discussed.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

The ClpP component of Clp protease is the sigma 32-dependent heat shock protein F21.5

The genes that encode the subunits of the Clp protease of Escherichia coli, clpA and clpP, appear to be regulated differently from each other. The clpA gene does not seem to be under heat shock control (Y. S. Katayama, S. Gottesman, J. Pumphrey, S. Rudikoff, W. P. Clark, and M. R. Maurizi, J. Biol. Chem. 263:15226-15236, 1988). In contrast, the level of ClpP protein was increased in rpoH+ cells but not in null rpoH cells after an upshift in temperature from 17 to 43 degrees C. The level of ClpP protein in a null dnaK strain was also elevated relative to the level of ClpP protein in an otherwise isogenic dnaK+ strain. In two-dimensional gels, the ClpP protein was located in the position of the previously unidentified heat shock protein F21.5. No protein spot corresponding to F21.5 was present in two-dimensional gels of a null clpP strain. The clpP gene, therefore, appears to be a heat shock gene, expressed in a sigma 32-dependent manner and negatively regulated by DnaK; the product of clpP is the previously unidentified heat shock protein F21.5.

Nucleotide excision repair in Escherichia coli

One of the best-studied DNA repair pathways is nucleotide excision repair, a process consisting of DNA damage recognition, incision, excision, repair resynthesis, and DNA ligation. Escherichia coli has served as a model organism for the study of this process. Recently, many of the proteins that mediate E. coli nucleotide excision have been purified to homogeneity; this had led to a molecular description of this repair pathway. One of the key repair enzymes of this pathway is the UvrABC nuclease complex. The individual subunits of this enzyme cooperate in a complex series of partial reactions to bind to and incise the DNA near a damaged nucleotide. The UvrABC complex displays a remarkable substrate diversity. Defining the structural features of DNA lesions that provide the specificity for damage recognition by the UvrABC complex is of great importance, since it represents a unique form of protein-DNA interaction. Using a number of in vitro assays, researchers have been able to elucidate the action mechanism of the UvrABC nuclease complex. Current research is devoted to understanding how these complex events are mediated within the living cell.

Interaction of the LexA repressor and the uvrC regulatory region

We have studied the in vitro interaction of the LexA repressor protein and the uvrC regulatory region. We find that there is specific binding to two regions, the region we have defined as lexA1 and the lexA2-lexA3 region. Our findings support the possibility of an inducible regulation for this complex operon.

The molecular genetics of the incision step in the DNA excision repair process

This review describes the evolution of research into the genetic basis of how different organisms use the process of excision repair to recognize and remove lesions from their cellular DNA. One particular aspect of excision repair, DNA incision, and how it is controlled at the genetic level in bacteriophage, bacteria, S. cerevisae, D. melanogaster, rodent cells and humans is examined. In phage T4, DNA is incised by a DNA glycosylase-AP endonuclease that is coded for by the denV gene. In E. coli, the products of three genes, uvrA, uvrB and uvrC, are required to form the UVRABC excinuclease that cleaves DNA and releases a fragment 12-13 nucleotides long containing the site of damage. In S. cerevisiae, genes complementing five mutants of the RAD3 epistasis group, rad1, rad2, rad3, rad4 and rad10 have been cloned and analyzed. Rodent cells sensitive to a variety of mutagenic agents and deficient in excision repair are being used in molecular studies to identify and clone human repair genes (e.g. ERCC1) capable of complementing mammalian repair defects. Most studies of the human system, however, have been done with cells isolated from patients suffering from the repair defective, cancer-prone disorder, xeroderma pigmentosum, and these cells are now beginning to be characterized at the molecular level. Studies such as these that provide a greater understanding of the genetic basis of DNA repair should also offer new insights into other cellular processes, including genetic recombination, differentiation, mutagenesis, carcinogenesis and aging.

Microinjection of Escherichia coli UvrA, B, C and D proteins into fibroblasts of xeroderma pigmentosum complementation groups A and C does not result in restoration of UV-induced unscheduled DNA synthesis

The UV-induced unscheduled DNA synthesis (UDS) in cultured human fibroblasts of repair-deficient xeroderma pigmentosum complementation groups A and C was assayed after injection of identical activities of either Uvr excinuclease (UvrA, B, C and D) from Escherichia coli or endonuclease V from phage T4. Under conditions where the T4 enzyme was able to induce repair synthesis in both XP complementation groups in agreement with earlier observations (de Jonge et al., 1985), no effect of the UvrABCD excinuclease could be observed either when the enzymatic complex was injected into the cytoplasm, or when it was delivered directly into the nucleus. In addition, no effect of the E. coli excinuclease was found on the repair ability of normal repair-proficient human fibroblasts. We conclude that the UvrABCD excinuclease may not work on DNA lesions in human chromatin.

Structure of the uvrB gene of Escherichia coli. Homology with other DNA repair enzymes and characterization of the uvrB5 mutation

The complete nucleotide sequence of the Escherichia coli uvrB gene has been determined. The coding region of the uvrB gene consists of 2019 nucleotides which direct the synthesis of a 673 amino-acid long polypeptide with a calculated molecular weight of 76.614 daltons. Comparison of the UvrB protein sequence to other known DNA repair enzymes revealed that 2 domains of the UvrB protein (domain I = 6 amino acids, domain II = 14 amino acids) are also present in the protein sequence of the uvrC gene. We show that the structural homologies between UvrB and UvrC are as well reflected by the cross-reactivity of anti-uvrB and anti-uvrC antibodies with UvrC and UvrB protein respectively. In the N-terminal part of UvrB, domain III (17 amino acids) shows a strong homology with one part of the AlkA gene product. Adjacent to domain III, an ATP binding site consensus sequence is found in domain IV. The uvrB5 mutant gene from strain AB1885 has been cloned on plasmid pBL01. We show that the uvrB5 mutation is due to a point deletion of a CG basepair and results in the synthesis of an 18 kD protein composed of the 113 N-terminal amino acids of the wild type uvrB gene and a 43 amino acid long tail coded in the -1 frame.

Sequences of the E. coli uvrB gene and protein

The UvrB protein is one of the three subunits of the E. coli ABC excinuclease. We have reported the sequences of the other two subunits, the UvrA and UvrC proteins. In this paper the sequence of the UvrB protein is presented. The protein sequence was determined from the DNA sequence of the uvrB gene and was confirmed by sequencing the NH2-terminus of the UvrB protein and analyzing its overall amino acid composition. The coding region of uvrB is 2019 basepairs, specifying a protein of 672 amino acids and Mr of 76,118. The sequence of the UvrB protein shows a moderate level of homology to that of the UvrC protein and to the ATP binding site of the UvrA protein. During purification of UvrB protein a proteolytic product, UvrB, is produced in high quantities. We find that UvrB results from removal of about 40 amino acids from the COOH-terminus of the UvrB protein. The uvrB gene has complex regulatory features. On the 5' side, the coding region is preceded by 3 promoters, a DnaA box and an SOS box. On the 3' side the gene is followed by an REP (Repetitive Extragenic Palindrome) sequence which has been implicated in gene regulation by an unknown mechanism.

In vitro study of the interaction of the LexA repressor and the UvrC protein with a uvrC regulatory region

The in vitro interaction of the LexA repressor with a regulatory region of the uvrC gene has been studied by polyacrylamide gel electrophoresis. Although the uvrC promoter region shows some homology with the canonic LexA binding site, no specific binding of the repressor to this DNA sequence could be observed, but only a cooperative nonspecific binding. By the same technique we show that the UvrC protein does not bind specifically to this regulatory DNA sequence either, although the protein is able to bind nonspecifically and cooperatively to the double-stranded DNA fragment.

Multiple control elements for the uvrC gene unit of Escherichia coli

We have sequenced the control region of the uvrC protein including two open reading frames (ORF) encoding polypeptides of 28 kd and 23 kd molecular weight. The uvrC gene is preceded by five promoters. The P1, P2a and P2b promoter sequences are 5' to the 28 kd and the 23 kd proteins respectively. The P3 and P4 promoters are located within the structural gene for the 23 kd protein. The P3 promoter is required for adequate in vivo expression. There are three putative lexA protein binding sites, detected at the 3' end of the 28 kd protein (lexA1), within the coding sequences for the 23 kd protein (lexA2) and within the P3 promoter (lexA3). Promoter P2 is responsible for transcription of the uvrC gene, producing transcripts of 2.8 and 1.6 kb. The upstream region including the 28 kd protein is required for enhanced expression under non-induced conditions. These results show that the uvrC gene is controlled by multiple promoters and is transcribed as part of a multigene unit.

Deletion analysis of the Escherichia coli lactose promoter P2

The Escherichia coli lactose (lac) operon transcription control region includes at least two sequences which are recognized by RNA polymerase holoenzyme in vitro, the normal lac promoter (termed P1) and an overlapping upstream promoter (termed P2). The structure of the P2 and the effect of RNA polymerase interaction at P2 on the association of RNA polymerase with P1 was analyzed by the isolation and characterization of various mutations at P2. A set of deletions with varying lengths of DNA between the lac P2 -10 region and a "-35 region" contributed by the vector DNA were constructed. In vitro studies indicate that as the spacing between the -10 region and "-35 region" is increased from 16 to 22 base pairs (bp), the steady state occupancy as measured by exonuclease III protection experiments and the ability to initiate transcripts from P2 decrease. Studies were also conducted using a single base pair insertion and a two base pair deletion between the natural -35 and -10 regions of P2. The mutation which decreases the in vitro occupancy and transcription initiation potential of P2 does not significantly affect the steady state in vitro occupancy of P1 nor the in vivo expression of the lac operon. These results are not consistent with the model that RNA polymerase occupancy at P2 competes with the P1 expression and therefore that this competition plays a role in cAMP bound catabolite gene activator protein (CAP-cAMP) control of the lac operon.

Analysis of regulatory sequences upstream of the E. coli uvrB gene; involvement of the DnaA protein

A region located upstream of the uvrB promoters P1 and P2 was found to cause high plasmid loss when cloned in multicopy vectors. Two sequence elements responsible for this phenomenon were identified by mapping of spontaneous mutations that restore plasmid maintenance: a sequence known to have in vitro promoter activity and a partially overlapping sequence that shows extensive homology to recognition sites for the DnaA protein. Accordingly alterations in the level of DnaA protein in vivo were found to affect the extent of plasmid loss. A possible role for interaction of the DnaA protein with the region of interest is discussed in relation to regulation of uvrB expression.

Organisation and control of the Escherichia coli uvrC gene

The Escherichia coli uvrC gene has been cloned into multicopy plasmids from the transducing phage lambda uvrC+ and the structural gene assigned to a 1.9-kb BglII fragment. Deletion of upstream sequences shows the presence of an in vivo uvrC promoter close to the start of the structural gene, as confirmed by subcloning the uvrC fragment into actively transcribed or 'promoter-free' restriction sites in various plasmid vectors. The control of uvrC transcription has been investigated using hybrid uvrC-cat operons. There are at least two promoters upstream of uvrC. Only the proximal promoter, some two orders of magnitude less effective than the cat promoter, is required for in vivo expression of the uvrC gene. We can find no evidence that expression of the uvrC gene on multicopy plasmids is either autogenously controlled or controlled by the product of the lexA gene.

Analysis of a cloned colicin Ib gene: complete nucleotide sequence and implications for regulation of expression

The complete nucleotide sequence of a 2,971 base pair EcoRI fragment carrying the structural gene for colicin Ib has been determined. The length of the gene is 1,881 nucleotides which is predicted to produce a protein of 626 amino acids and of molecular weight 71,364. The structural gene is flanked by likely promoter and terminator signals and in between the promoter and the ribosome binding site is an inverted repeat sequence which resembles other sequences known to bind the LexA protein. Further analysis of the 5' flanking sequences revealed a second region which may act either as a second LexA binding site and/or in the binding of cyclic AMP receptor protein. Comparison of the predicted amino acid sequence of colicin Ib with that of colicins A and E1 reveals localised homology. The implications of these similarities in the proteins and of regulation of the colicin Ib structural gene are discussed.

Distal regulatory functions for the uvrC gene of E. coli

We find that the uvrC gene is preceded by three promoters (P1, P2 and P3), identified by heparin-resistant RNA polymerase-DNA complex formation, P2 and P3 promoters are located proximal to the 5' end of the uvrC gene, while the P1 promoter is separated from the uvrC structural gene by an interposed DNA region of more than 1 kb. We have reported that P2 and P3 are not sufficient to promote uvrC complementation. However, plasmids containing the direct fusion of the P1 promoter to the uvrC gene complements the uvrC defect. Insertion of IS1 downstream from the P1 promoter leads to efficient synthesis of the uvrC protein as measured in maxicells. Fusion of the lac promoter to the uvrC structural gene can substitute for in vivo regulatory functions. We conclude that uvrC protein synthesis is controlled in a complex manner and that a distal promoter, P1, is required.

Recognition of messenger RNA during translational initiation in Escherichia coli

The structural aspects of recognition by E. coli ribosomes of translational initiation regions on homologous messenger RNAs have been reviewed. Also discussed is the location of initiation region on mRNA, its confines, typical nucleotide sequences responsible for initiation signal, and the influence of RNA macrostructure on protein synthesis initiation. Most of the published DNA nucleotide sequences surrounding the start of various E. coli genes and those of its phages have been collected.

Indirect induction of SOS functions in Salmonella typhimurium

Infection of non-UV-irradiated cells of Salmonella typhimurium with UV-damaged P22 or KB1 phage induces recA-dependent inhibition of cell division, cell mutagenesis and prophage induction but not inhibition of respiration. On the contrary, respiration and ATP concentration are increased after treatment with UV-damaged phage in both RecA+ and RecA- strains, showing that this increase is not recA-dependent. Furthermore, infection with UV-damaged phage prevents both inhibition of respiration and decrease in ATP level in the UV-irradiated RecA+ strain. This indirect induction of SOS functions is related to degradation of phage DNA as well as to the multiplicity of infection used, suggesting that DNA degradation may play an important role in the mechanism of expression of the SOS system. Our results give also support to the hypothesis that there exists a differentiation in the expression of the various SOS functions.

Nucleotide sequence of the regulatory region of the uvrD gene of Escherichia coli

We have sequenced the control region of the Escherichia coli uvrD gene and demonstrated the presence of a nucleotide sequence which is a perfect match for the consensus LexA protein binding site [Little and Mount, Cell 29 (1982) 11-22]. Upstream of this presumed LexA binding site is a promoter sequence, uvrD P1 which would be under LexA control while farther downstream is another possible promoter, uvrD P2, which would be independent of LexA control. Downstream of the LexA binding site is a potential transcription terminator in the form of a stem-loop structure followed by a series of T residues. On the basis of this sequence analysis, expression of the uvrD gene would be expected to increase after DNA damage or replication inhibition as part of the SOS response, as is reported in the preceding paper [Arthur and Eastlake, Gene 25 (1983) 309-316].

In vivo regulation of the uvrA gene: role of the "-10" and "-35" promoter regions

The effect of increasing deletions in the uvrA promoter region on the transcriptional efficiency was quantitatively analysed by fusion to the galK structural gene. A physical analysis of uvrA messenger RNA synthesis from the different deletion plasmids was performed using the S1 mapping technique. Both methods indicate that the uvrA "-10" promoter sequence is sufficient to trigger uvrA transcription. Although not essential, the "-35" region, which is overlapping with the LexA binding site, is shown to have an enhancing function, as the exposure of this region after SOS induction results in a 3- to 4-fold increase in uvrA transcription. A model is presented which accounts both for the observed basal and induced expression of the uvrA gene on a molecular level.

The SOS system of Escherichia coli in the regulation of bacteriophage lambda development

A sequence homologous to the known SOS boxes is found in the Po promoter of phage lambda. It is suggested that the sequence found is a binding site for the LexA repressor. The mechanism of the LexA part in regulation of lambda development is discussed. It is based on the competitive transcription of the RNA encoding CII protein and the short OOP-RNA transcribed from the Po promoter.

In vivo transcription of the E. coli uvrB gene: both promoters are inducible by UV

The transcriptional activity of the tandem promoters of the Escherichia coli uvrB gene was measured in vivo. Both promoters are shown to be inducible by UV irradiation. P1, the most proximal promoter, is responsible for the main part of transcription both in uninduced and induced cells. Plasmids have been constructed carrying small deletions in the lexA binding site that overlaps with P2, the distal promoter. These deletions result in constitutive transcription from P1. This indicates that the DNA region which contains P2 functions mainly as a target site for regulation of P1 transcription in vivo.

Autoinduced synthesis of colicin E2

Escherichia coli K-12 cells carrying the high copy number plasmid ColE2-P9 and a sfiA-lacZ gene fusion exhibit abnormally high levels of SOS-regulated phi sfiA-lacZ expression. Increased sfiA-lacZ expression is caused by the action of colicin E2, which is a DNase, rather than by the presence of multiple copies of a binding site for LexA protein, the repressor for the sfiA and colicin E2 genes. Expression of sfiA-lacZ was reduced to normal levels if the ColE2+ strain lacked the outer membrane colicin E2 receptor protein (BtuB) or if they carried an increased number of colicin E2 immunity genes. The results suggest that cultures of ColE2+ strains contain a small number of cells which produce colicin which can then enter other, non-producing cells in the culture and cause sufficient damage to the DNA to induce the SOS system. The levels of colicin E2 immunity in the producing cells is presumably sufficient to prevent extensive lethal effects of the colicin, but insufficient to prevent limited endonuclease activity. An important consequence of this phenomenon is that the DNase action of colicin E2 can stimulate its own production.

Compilation and analysis of Escherichia coli promoter DNA sequences

The DNA sequence of 168 promoter regions (-50 to +10) for Escherichia coli RNA polymerase were compiled. The complete listing was divided into two groups depending upon whether or not the promoter had been defined by genetic (promoter mutations) or biochemical (5' end determination) criteria. A consensus promoter sequence based on homologies among 112 well-defined promoters was determined that was in substantial agreement with previous compilations. In addition, we have tabulated 98 promoter mutations. Nearly all of the altered base pairs in the mutants conform to the following general rule: down-mutations decrease homology and up-mutations increase homology to the consensus sequence.

The coupled use of 'footprinting' and exonuclease III methodology for RNA polymerase binding and initiation. Application for the analysis of three tandem promoters at the control region of colicin El

In order to determine the initiation site for three promoters P1, P2 and P3 (5' to 3') in close proximity in the colicin E1 control region we developed a new methodology that couples ternary complex formation and the analysis of the 3' border protected from exonuclease III digestion. The initiation of transcription could be detected by measuring the shift in the position of the 3' protected border when RNA polymerase moved from its binary complex position to its ternary complex position. The latter stops at a specific nucleotide because transcription is initiated with one or more NTPs missing. This approach, coupled with "footprinting", can also be used to decide whether the formation of an RNA polymerase binary or ternary complex at one site excludes or weakens binding at neighboring sites. The location of 3' protected borders reveals the formation of respective binary and ternary complexes at non-saturating RNA polymerase conditions, whereas at saturating conditions only the distal 3' boundary is seen and exonuclease cannot penetrate further. However, if "footprinting" reveals proximal 5' patterns this establishes that simultaneous binding has occurred on the same DNA fragment. The data showed that this was true for P1 and P3 which are only 8 nucleotides apart. P2 could only be detected at non-saturating conditions since it overlaps both P1 and P3. The evidence from the literature and this study establishes P1 as the true colicin E1 promoter with the possibility that supercoiling may eliminate any role for P2 and P3.

Molecular structure of uvrC gene of Escherichia coli: identification of DNA sequences required for transcription of the uvrC gene

We have carried out experiments to identify the regulatory regions of the uvrC gene of Escherichia coli. A uvrC+ plasmid, pUV7, containing the intact transcriptional unit for the uvrC gene, was used to subclone either the structural gene or combinations of the structural gene and 5'-flanking sequences. The plasmids so constructed were tested for ability to restore UV-resistant phenotype to uvrC- cells as an indication of expression of the uvrC gene. The chromosomal DNA in plasmid pUV7 was probed for strong binding with E. coli RNA polymerase in an attempt to identify a restriction fragment which bears the regulatory sequences for the uvrC transcriptional unit. The results indicate that DNA sequences at least 0.9 Kb upstream from the structural gene, but not the 5'-proximal sequences, regulate expression of the uvrC gene. Analysis of protein synthesis encoded by plasmid pUV7 and its derivatives suggest that there may be another gene that lies between the promoter and the uvrC gene and codes for a 27,000-Mr protein. The relation of this gene to uvrC function is not clear.

Properties and regulation of the UVRABC endonuclease

This report summarizes the cloning of the uvrA, uvrB and uvrC genes of E. coli, the identification and isolation of the gene products, the regulation of the genes, and reconstitution of active UVRABC endonuclease from the individually isolated components.

How Escherichia coli sets different basal levels in SOS operons

The recA and sfiA genes of Escherichia coli are SOS operons regulated negatively by the LexA repressor. The steady state level of expression of recA is 10-fold higher than that of sfiA, as measured by means of recA::lac and sfiA::lac operon fusions. To study the molecular basis of this difference, we have compared the expression of these two operons in strains in which the concentration of LexA repressor was normal (lexA+), zero (spr amber mutation) or higher than normal (plasmid pJL45, carrying the lexA gene linked to the lac promoter). The results indicate (i) that the recA promoter is about 4 times stronger than the sfiA promoter (as measured in the spr strains), (ii) that neither operon has a physiologically significant level of lexA-independent expression (pJL45 strains), and (iii) that the recA operator has about 2.5 times lower affinity than the sfiA operator for LexA repressor (comparison of lex+ and spr strains). Considering our previous results that the sfiA operon (high operator affinity of LexA) is derepressed very rapidly after inducing treatments and that the recA operon (low operator affinity) is repressed very rapidly when induction is stopped, we conclude that differences in operator affinity do not affect inducibility but serve only to set the basal levels of the different SOS functions.

A physical map of the Escherichia coli bio operon

The endpoints of the Escherichia coli bio DNA insertions in 24 lambda bio transducing phage were mapped electron micrographically in heteroduplexes of the type lambda bio/lambda att2, which permit simultaneous measurement of the lambda deletion and bio insertion endpoints. A physical map of the bio operon was constructed and correlated with the genetic map, the molecular sizes of the bio gene products, and the restriction map. The order att lambda-bioA-pBopA-bioBFCD-uvrB was confirmed. The maximum size of the bio operon was estimated at 5.5 kb, and the locus was found to be fully saturated with genes. There appears to be little space between the bioA gene and att lambda, while bioD mapped within 0.7 kb from uvrB. The size of the uvrB locus was estimated not to exceed 2.6 kb.

The nucleotide sequence of the bacteriocin promoters of plasmids Clo DF13 and Co1 E1: role of lexA repressor and cAMP in the regulation of promoter activity

Treatment of cells, harbouring the bacteriocinogenic plasmic Clo DF13 with mitomycin-C, which induces the cellular SOS response, results in a significantly increased transcription of the operon encoding the bacteriocin cloacin DF13, the immunity protein and the lysis protein H. The nucleotide sequences of the promoter regions and N-terminal parts of the bacteriocin genes of Clo DF13, Col E1 and the pMB1 derivative pBR324 have been determined. A comparison of these sequences with those of corresponding regions of the lexA, recA and uvrB genes revealed that the promoter regions of the bacteriocin genes studied contain binding sites for the lexA protein, which is the repressor of the E. coli DNA-repair system. Using both, a thermosensitive lexA host strain and a host with pACYC184 into which the lexA gene had been cloned, we were able to demonstrate, that in vivo the lexA protein is involved in the regulation of bacteriocin synthesis. From the data presented, we conclude that bacteriocin synthesis is controlled at least by the lexA repressor. It has been reported that also catabolite repression might play an essential role in the control of bacteriocin synthesis. Computer analysis of the DNA sequence data indicated that the promoter regions of both, the cloacin DF13 and colicin E1 genes contain potential binding sites for the cyclic AMP-cyclic AMP Receptor Protein complex.