Heterogeneity in expression of the <Emphasis Type="Italic">Escherichia coli</Emphasis> colicin K activity gene <Emphasis Type="Italic">cka</Emphasis> is controlled by the SOS system and stochastic factors

Phenotypic diversity provides populations of prokaryotic and eukaryotic organisms with the flexibility required to adapt to and/or survive environmental perturbations. Consequently, there is much interest in unraveling the molecular mechanisms of heterogeneity. A classical example of heterogeneity in Escherichia coli is the subset (3%) of the population that expresses the colicin K activity gene (cka) upon nutrient starvation. Here, we report on the mechanism underlying this variable response. As colicin synthesis is regulated by the LexA protein, the central regulator of the SOS response, we focused on the role of LexA and the SOS system in the variable cka expression. Real-time RT-PCR showed that the SOS system, without exogenous DNA damage, induces moderate levels of cka expression. The use of cka-gfp fusions demonstrated that modification of the conserved LexA boxes in the cka promoter region affected LexA binding affinity and the percentage of cka-gfp expressing cells in the population. A lexA-gfp fusion showed that the lexA gene is highly expressed in a subset of bacteria. Furthermore, cka-gfp fusions cloned into higher copy plasmid vectors increased the percentage of cka-gfp positive bacteria. Together, these results indicate that the bistability in cka expression in the bacterial population is determined by (1) basal SOS activity, (2) stochastic factors and possibly (3) the interplay of LexA dimers at cka operator. Other LexA regulated processes could exhibit similar regulation.     

Two overlapping SOS-boxes in ColE operons are responsible for the viability of cells harboring the Col plasmid

In this study, oligonucleotide-directed site-specific mutagenesis was used to change the consensus sequences of the LexA binding motifs in either one of the two SOS-boxes of the ColE7 operon. The results indicated that both mutants produced larger amounts of colicin than cells harboring the wild-type ColE7 plasmid. This finding would imply that two biologically functional SOS boxes exist in the ColE7 operon. In the non-induced state, no lysis of cells harboring wild-type plasmids occurred at 37°C, whereas, cells harboring recombinant plasmids containing either one of the mutated SOS boxes underwent lysis within 100 min under the same conditions. This result indicated that adaptation of two SOS boxes of the ColE operon would obviously tightly control the expression of ColE operons. In such a way that it may prevent excessive expression of the lysis (cel) gene, thus safeguard the host cells from being lysed in ordinary living conditions.     

Discovery of critical Tol A-binding residues in the bactericidal toxin colicin N: a biophysical approach

Colicins translocate across the Escherichia coli outer membrane and periplasm by interacting with several receptors. After first binding to outer membrane surface receptors via their central region, they interact with TolA or TonB proteins via their N-terminal regions. Finally, the toxic C-terminal region is inserted into or across the cytoplasmic membrane. We have measured the binding of colicin N to TolA by isothermal titration microcalorimetry (ITC) and tryptophan fluorescence. The isolated N-terminal domain exhibits a higher affinity for TolA ( K _d = 1 μM) than does the whole colicin (18 μM), and similar behaviour has been observed when the N-terminal domain of the g3p protein of the bacteriophage fd, which also binds TolA, is examined in isolation and in situ . This may indicate a similar mechanism in which a cryptic TolA binding site is revealed after primary receptor binding. The isolated colicin N N-terminal domain appears to be unstructured in circular dichroism and fluorescence studies. We have used mutagenesis and ITC to characterize the TolA binding site and have shown it to be of a different sequence and much further from the N-terminus than previously thought.     

Characterization of Colicin S4 and Its Receptor, OmpW, a Minor Protein of the Escherichia coli Outer Membrane

Analysis of the nucleotide sequence of an Escherichia coli colicin S4 determinant revealed 76% identity to the pore-forming domain of the colicin A protein, 77% identity to the colicin A immunity protein, and 82% identity to the colicin A lysis protein. The N-terminal region, which is responsible for the Tol-dependent uptake of colicin S4, has 94% identity to the N-terminal region of colicin K. By contrast, the predicted receptor binding domain shows no sequence similarities to other colicins. Mutants that lacked the OmpW protein were resistant to colicin S4.     

Nucleotide sequence and LexA regulation of the Escherichia coli recN gene.

The nucleotide sequence of a 2224 bp region of the Escherichia coli chromosome that carries the LexA regulated recN gene has been determined. A region of 1701 nucleotides encoding a polypeptide of 567 amino acids with a predicted molecular weight of 63,599 was identified as the most probable sequence for the recN structural gene. The proposed initiation codon is preceded by a reasonable Shine-Dalgarno sequence and a promoter region containing two 16 bp sequences, separated by 6 bp, that match the consensus sequence (SOS box) for binding LexA protein. DNA fragments containing this putative promoter region are shown to bind LexA in vitro and to have LexA-regulated promoter activity in vivo. The amino acid sequence of RecN predicted from the DNA contains a region that is homologous to highly conserved sequences found in several DNA repair enzymes and other proteins that bind ATP. A sequence of 9 amino acids was found to be homologous to a region of the RecA protein of E. coli postulated to have a role in DNA/nucleotide binding.     

Induction of the SOS Response in Ultraviolet-Irradiated Escherichia coli Analyzed by Dynamics of LexA, RecA and SulA Proteins

The SOS response in Escherichia coli is induced after DNA-damaging treatments including ultraviolet light. Regulation of the SOS response is accomplished through specific interaction of the two SOS regulator proteins, LexA and RecA. In ultraviolet light-treated cells, nucleotide excision repair is the major system that removes the induced lesions from the DNA. Here, induction of the SOS response in Escherichia coli with normal and impaired excision repair function is studied by simulation of intracellular levels of regulatory LexA and RecA proteins, and SulA protein. SulA protein is responsible for SOS-inducible cell division inhibition. Results of the simulations show that nucleotide excision repair influences time-courses of LexA, RecA and SulA induction by modulating the dynamics of RecA protein distribution between its normal and SOS-activated forms.     

Genetic analysis of ColN plasmid determinants for colicin production, release, and immunity.

Colicin N was identified as the 39,000-molecular-weight protein encoded by the 4,900-base-pair, multiple copy number, amplifiable plasmid ColN -284. Its production was controlled by the SOS regulatory circuit and by catabolite repression. Colicin accumulated intracellularly to ca. 10(6) molecules per cell after growth for 2 to 3 h in medium containing 0.5 microgram of mitomycin C per ml and was then released as the cells underwent partial lysis. Strains carrying pColN -284 and its derivatives exhibited low-level immunity to colicin N and were fully sensitive to all other colicins tested. Regions of the plasmid responsible for colicin N activity (cna), for mitomycin-induced lysis ( cnl ), and for colicin N immunity ( cni ) were localized and characterized by cloning, transposon Tn5 and hydroxylamine mutagenesis, and restriction endonuclease deletion and mapping analysis. The results are discussed in terms of both the organization of the cna, cnl , and cni genes and the respective role of cnl expression and colicin N production in mitomycin sensitivity, colicin export, and induced partial lysis of ColN + cells.     

The DNA-binding activity of the Neisseria gonorrhoeae LexA orthologue NG1427 is modulated by oxidation

Neisseria gonorrhoeae is a human-specific organism that is not usually exposed to UV light or chemicals but is likely to encounter reactive oxygen species during infection. Exposure of N. gonorrhoeae to sublethal hydrogen peroxide revealed that the ng1427 gene was upregulated sixfold. N. gonorrhoeae was thought to lack an SOS system, although NG1427 shows amino acid sequence similarity to the SOS response regulator LexA from Escherichia coli. Similar to LexA and other S24 peptidases, NG1427 undergoes autoproteolysis in vitro, which is facilitated by either the gonococcal or E. coli RecA proteins or high pH, and autoproteolysis requires the active and cleavage site residues conserved between LexA and NG1427. NG1427 controls a three gene regulon: itself; ng1428, a Neisseria-specific, putative integral membrane protein; and recN, a DNA repair gene known to be required for oxidative damage survival. Full NG1427 regulon de-repression requires RecA following methyl methanesulphonate or mitomycin C treatment, but is largely RecA-independent following hydrogen peroxide treatment. NG1427 binds specifically to the operator regions of the genes it controls, and DNA binding is abolished by oxidation of the single cysteine residue encoded in NG1427. We propose that NG1427 is inactivated independently of RecA by oxidation.     

Colicin synthesis and cell death.

Colicin E1 is a small plasmid, containing the cea gene for colicin, the most prominent product of the plasmid. Colicin is a 56-kilodalton bacteriocin which is especially toxic to Escherichia coli cells that do not contain the plasmid. Under normal growth conditions very low levels of the plasmid are produced as a result of cea gene repression by the host LexA protein. Conditions that lower the concentration of LexA protein result in elevated levels of colicin synthesis. The LexA protein concentration can be lowered by exposing the cells to DNA-damaging reagents such as UV light or mitomycin C. This is because DNA damage signals the host SOS response; the response leads to activation of the RecA protease which degrades the LexA protein. DNA-damaging reagents result in very high levels of colicin synthesis and subsequent death of plasmid-bearing cells. Elevated levels of colicin are also produced in mutants of E. coli that are deficient in LexA protein. We found that comparably high levels of colicin can be produced in such mutants in the absence of cell death. In lexA strains carrying a defective LexA repressor, colicin synthesis shows a strong temperature dependence. Ten to twenty times more colicin is synthesized at 42 degrees C. This sharp dependence of synthesis on temperature suggests that there are factors other than the LexA protein which regulate colicin synthesis.     

LexA repressor induces operator-dependent DNA bending

LexA, the repressor of the SOS system in Escherichia coli induces a substantial DNA bending upon interaction with the operator of the caa gene, which codes for the bacterial toxin colicin A. Analysis by gel electrophoresis of a family of DNA fragments of identical length, but bearing the caa operator at different positions, shows that DNA bending occurs close to or within the operator sequence upon LexA binding. In contrast, the interaction of LexA with the recA operator induces no detectable bending on 5% polyacrylamide gels. This difference between the two operators is likely to be due to an intrinsic bendability of the caa operator related to thymine tracts located on both sides of the operator. Such tracts do not exist in the recA operator. The free DNA fragments harbouring the caa operator show a slight tendency to bend even in the absence of the LexA repressor. The centre of this intrinsic bend is located close to or within the caa operator.     

Dynamic aspects of colicin N translocation through the Escherichia coli outer membrane.

Colicin N is a bacteriocin that kills sensitive Escherichia coli cells. After binding to the cell surface-exposed receptor, a short period exists when a significant number of the cell-associated colicin N molecules are sensitive to external enzymes. Two colicin N populations are discriminated by proteases: the susceptible pool bound to OmpF porin on the cell surface and another population corresponding to protease-inaccessible colicin N. During translocation, colicin N reaches the periplasmic space and proteolytic cleavage of the colicin occurs only when the outer membrane barrier is permeabilized.     

Molecular cloning and nucleotide sequence of a pectin lyase gene from Pseudomonas marginalis N6301.

A pectin lyase (PNL;EC4.2.2.10) gene of Pseudomonas marginalis N6301 was cloned and expressed in Escherichia coli. We purified PNL from P. marginalis N6301 and determined N-terminal 33 amino acids sequence. From this sequence, we synthesized two oligonucleotide probes. From the analysis of Southern hybridization, 2. 1kb EcoRI-SmaI fragment from the chromosomal DNA of P. marginalis was found to hybridize with oligonucleotide probes. Then, we cloned the fragment into pUC119 vector and transformed into E. coli DH5 alpha. A plasmid thus obtained was designated as pPNL6301. E. coli DH5 alpha harboring pPNL6301 expressed PNL activity. The nucleotide sequence of pn1 gene in the plasmid pPNL6301 encoding PNL from P. marginalis N6301 was determined. The structural gene of pn1 consisted of 936 base pairs. An open reading frame that encodes a 34,103 dalton polypeptide composed of 312 amino acids was assigned. The molecular weight of the polypeptide predicted from the amino acid composition was close to that of PNL of P. marginalis N6301 determined. The nucleotide sequence of the 5'-flanking region of pn1 gene showed the presence of the consensus sequence of LexA binding site, Pribnow box and ribosome binding site as found in Escherichia coli. The amino acid sequence homology of PNLs and nucleotide sequence homology of pn1 gene between P. marginalis N6301 and E. carotovora Er were 60.8% and 57.2%, respectively.