Effect of the plasmid ColIb-P9 on cellular processes related to DNA repair

Summary The plasmid ColIb-P9 introduced into Escherichia coli K12 umuC mutant cells suppresses the deficiencies in mutagenesis and repair of mutants after UV-irradiation. These data suggest that ColIb-P9 encodes a product with a function similar to that of the chromosomal gene umuC. Tn5 insertion mutants of ColIb-P9 were isolated with an altered ability to restore UV-mutagenesis in the umuC mutant. The same plasmid mutations were shown to eliminate the effects of ColIb-P9 on UV-mutagenesis, survival after UV and mitomycin C treatment, reactivation of UV-irradiated in unirradiated cells, Weigle-reactivation, induction of colicin E1 synthesis. The ColIb-P9 genes responsible for the enhancement of UV-mutagenesis were cloned within a 14 Md SalI fragment. Their location was established by restriction analysis of the mutant plasmid ColIb 6-13::Tn5.While the action of the plasmids ColIb-P9 and pKM101 is similar, these plasmids were shown to have opposite effects on cell survival and colicin E1 synthesis after mitomycin C treatment. A study of the mutant plasmids ColIb::Tn5 and pGW12 (muc ^- mutant of pKM101) has shown the difference in the effects of ColIb-P9 and pKM101 to be associated with the plasmid genes responsible for the protective and mutagenesis-enhancing effects of these plasmids in UV-irradiated cells.Abbreviations MC mitomycin C - ICS induction of colicin synthesis     

The influence of colicinogenic plasmids ColIb-P9, ColIa-CA53 and ColV-K30 on the repair, mutagenesis and induction of colicin E1 synthesis

Summary The presence of colicinogenic plasmids ColIb-P9 and ColIa-CA53 in E. coli K-12 cells, wild-type with respect to repair, enhanced the survival of cells after UV irradiation and increased the frequency of UV-induced argE3 and his-4 reversions, while the presence of ColV-K30 negatively affected repair and mutagenesis. The plasmid ColIb-P9 showed a UV-protective effect in E. coli cells carrying mutations in genes uvrA, uvrB, uvrC, polA, recB, recF, though in none of the mutants did cell survival reach the wild-type level. The effect of ColIb-P9 on mutagenesis did not depend on the uvrA or recB genes. The plasmids' protective effect and the enhancement of mutagenesis depended on the recA ⁺ lexA⁺ genotype. The frequency of 2-aminopurine-induced mutations was not affected by ColIb-P9 or ColV-K30. The presence of ColIb-P9 decreased the ability of ColEl-carrying cells to induce colicin E1 synthesis caused by DNA-damaging agents: UV, MNNG, mitomycin C, whereas ColV-K30 increased the percentage of colicin E1-producing cells. These plasmid effects on the level of induction of colicin E1 synthesis were not observed in the case of induction caused by chloramphenicol which did not depend on the products of recA and lexA genes.Abbreviations AP 2-aminopurine - MNNG N-methyl-N-nitro-N-nitrosoguanidine - ICS induction of colicin synthesis - CM chlorampheniol - MC mitomycin C     

Outer membrane proteins of Escherichia coli K-12: Isolation of a common receptor protein for bacteriophage T6 and colicin K

Summary tsx mutants, resistant to T6-like bacteriophages and colicin K, of Escherichia coli K-12 lack an outer membrane protein of 26,000 molecular weight. This protein is shown to have receptor activity for both bacteriophage T6 and colicin K. The protein has been purified and its amino acid composition determined. Some tsx mutants appear to have an altered receptor protein, as indicated by their ability to plate extended host-range mutants of bacteriophage T6. These mutants are also cotransducible with proC and can be arranged in an order of increasing resistance to the host range phages, which appear to have differing degrees of ability to propagate on the tsx mutants.The tsx protein was shown to be catabolite repressible both by use of varying growth conditions and cya and crp mutants.     

Colicin M is only bactericidal when provided from outside the cell

Summary The colicin M structural gene, cma, was subcloned in a vector which allowed temperature-inducible control of its expression. Induction of expression of cma in colicin M uptake proficient strains was lethal for the host cell when the colicin M immunity protein was not present. In liquid culture cells lysed, and no colonies were formed on solid media. These effects were not observed in mutants defective in the colicin receptor (FhuA) or uptake functions (TonB, TolM), nor in wild-type cells treated with trypsin prior to induction of cma expression. It was concluded that cytoplasmic colicin M is not toxic for the producing cell. To exert a lethal effect the colicin has to enter the cell from outside. Cells expressing cma released small amounts of colicin M.     

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.     

Induction of Colicin Production by High Temperature or Inhibition of Protein Synthesis

Escherichia coli K-12 colicinogenic for ColE1 yielded mutants that appeared to produce colicin at 43 C but not at 30 or 37. These mutants proved to have the mutation recA⁻ Further study revealed that both recA⁻ and recA⁺ bacteria, when carrying ColE1 or ColE2, produce more colicin during growth at higher temperatures or after brief exposure to temperatures beyond the growth range. Counts of lacunae demonstrated that the increase of colicin production is due to an increase in the number of cells that yield colicin. Heat treatment causes lacunae to increase by the same factor in recA⁺ and recA⁻ cells, although recA⁻ bacteria produce 500 times fewer lacunae than recA⁺. Inhibition of protein synthesis, notably by chloramphenicol, also induces colicin production in as much as 90% of the cells after removal of inhibition (to permit colicin synthesis). Induction of colicin production by chloramphenicol requires that ribonucleic acid synthesis continue during the period of inhibition. These results are discussed in relation to the regulation of colicin production.     

The properties of UV sensitive mutants of Escherichia coli K12 which are also refractory to colicin E2

Summary Among mutants refractory to colicin E2 at low temperatures but sensitive at high temperatures (designated Ref-II), three strains are described which are also UV sensitive. Although colicin refractivity is temperature dependent UV sensitivity is expressed at all temperatures. Although the UV sensitive lesion appears to be similar in its effects to that in Rec (recombinationless) strains, mutants specifically isolated as Rec strains are in fact more sensitive to E2 than are wild type strains. It is suggested that E2 refractivity and UV sensitivity in the mutants probably reflects the phenotypic expression of distinct although linked genes. It is also suggested that the degradation of DNA stimulated by adsorption of E2 to wild type bacteria may be caused by the same enzyme(s) which causes enhanced breakdown of DNA in some rec ^– mutants after UV irradiation.     

Lipopolysaccharide Defective Mutant of Escherichia coli with Decreased Sensitivity to Colicin E2

Several colicin-sensitivity mutants were isolated from Escherichia coli K-12. The mutants could not form colonies in the presence of colicin E2, but recovered their colony-forming ability on trypsin treatment even after prolonged incubation with the colicin. They showed increased sensitivity to hydrophobic antibiotics and detergents, as well as resistance against P1 and T4 phages, both of which seemed due to structural changes of lipopolysaccharide (LPS). Quantitative analysis by gas-liquid chromatography revealed that the mutant-LPS contained a different stereoisomer of heptose with decreased amounts of neutral sugars (rhamnose, glucose and galactose). LPS extracted from the parental colicin-sensitive strain could neutralize the killing activity of colicin E2 in vitro, but the mutant-LPS could not. The mutant strains retained functional receptor proteins for colicin E2. These observations suggest that LPS plays an important role in the early stage of the interaction of colicin E2 with E. coli cells.     

THE PHENOTYPIC AND FITNESS EFFECTS OF COLICIN RESISTANCE IN ESCHERICHIA COLI K-12

Previous studies indicate that most natural isolates of Escherichia coli are resistant to most or all colicins (antibiotics produced by E. coli) when assessed in the laboratory. Additionally, resistance to different colicin types appears to arise in a nonindependent manner. One possible mechanism to explain this nonindependence is pleiotropy: Multiple resistances are selected after exposure to a single colicin. This study, which was designed to address the role of pleiotropy in the generation of colicin resistance, revealed that 96% of colicin resistant mutants were resistant to two or more colicins. Mutational class was important because putative translocation mutants (Tol pathway mutants) resisted fewer colicins than putative receptor mutants. To determine whether colicin resistance is costly, the effects of colicin resistance mutations on maximal growth rate in a rich medium were also examined. Relative to the sensitive ancestor, translocation mutations lowered maximal growth rates by 17%, whereas putative receptor mutations did not significantly lower growth rates. Thus, when nutrients are abundant, the most advantageous forms of colicin resistance may not impose a cost. The ecological consequences of pleiotropic colicin resistance could involve population cycling between colicin sensitivity and resistance. Additionally, if the cost of resistance depends on the environment, ecological diversification could result.     

Antimodification activity of the ArdA and Ocr proteins

The ArdA and Ocr antirestriction proteins, whose genes are in transmissible plasmids (ardA) and bacteriophage genomes (0.3 (ocr)), specifically inhibit type I restriction-modification enzymes. The Ocr protein (T7 bacteriophage) was shown to inhibit both restriction (endonuclease) and modification (methylase) activities of the EcoKI enzyme in a broad range of intracellular concentrations (starting from 10–20 molecules per cell). In contrast to Ocr, the ArdA protein (ColIb-P9 transmissible plasmid) inhibited both of the EcoKI activities only at high intracellular concentrations (30000–40000 molecules per cell). When the ArdA concentration was several fold lower, only endonuclease activity of EcoKI was inhibited. It was assumed that a poorer ArdA ability to inhibit EcoKI modification activity is related to the substantial difference in life cycle between transmissible plasmids (symbiosis with the bacterial cell) and bacteriophages (infection and lysis of bacteria). The Ocr and ArdA mutants that inhibited exclusively endonuclease activity of EcoKI were obtained. Antirestriction proteins incapable of homodimerization were assumed to inhibit only endonuclease activity of type I restriction-modification enzymes.     

Exchange of colicin receptor capacity between strains of Escherichia coli sensitive or resistant to colicin K-K235

Phage and colicin-resistant mutants were derived from Escherichia coli K-12P678. Two classes of phage T6 and colicin K-resistant mutants (genotype tsx) were isolated. Tsx-2 mutants, which demonstrated mucoid growth and increased sensitivities to many antibiotics, became sensitive to colicin K when pretreated with ethylenediaminetetraacetate (EDTA), whereas Tsx-1 mutants did not. Reassociation of EDTA-released material partially restored resistance to colicin K for Tsx-2 mutants. When EDTA-released material from strain P678 was associated with either class of K-resistant mutant, an increase in colicin K sensitivity resulted. Observations suggest that colicin K can act on its target site once it penetrates the cell surface. In addition, results suggest that functional colicin K receptors can be transferred from sensitive to resistant strains, thus conferring colicin sensitivity.Non-standard Abbreviations SDS sodium dodecyl sulfate     

Translocation of colicin from the receptor to the inner cell membrane: function of the peptidoglycan layer

Sensitivity of spheroplasts (prepared in two ways) of a colicin-sensitive strain, of colicinresistant and of colicin-tolerant mutants and of strains immune to colicins E1 and E2 was estimated and compared. Generally, the removal of the peptidoglycan layer brought about a slight nonspecific support for colicin translocation across the cell wall in sensitive,tolB tolerant and immune bacteria.tolB spheroplasts were colicin E1-sensitive, but E2-insensitive. Spheroplasts were always fragile and lysed spontaneously, especially those produced by lysozyme. Bacteria carryingtolA, tolQ andtolR mutations kept their colicin insensitivity as spheroplasts, just as the resistant ones. Bacteria rendered colicinogenic and hence colicin-immune turned to high colicin sensitivity in spheroplast form. The results indicate a change in plasma membrane associated with the spheroplast formation.     

Detection of induced synthesis of colicin E9 using ColE9p::gfpmut2 based reporter system

The majority of colicin operons are regulated by an SOS response inducible promoter (SOS promoter), located at upstream of the colicin operons. Therefore, colicin synthesis is induced by DNA damaging agents like mitomycin C (MMC) because the resulting DNA damage switches on the SOS response in bacteria. In this study, we have described the strategy for fusion of the SOS promoter of the colicin E9 operon (ColE9p) with a promoterless green fluorescent reporter gene (gfpmut2). We observed that the ColE9p–gfpmut2 is inducible by MMC which confirmed that the ColE9p–gfpmut2 is sensitive to SOS response inducing agents. The data implies that the ColE9p–gfpmut2 based reporter system is suitable for monitoring the ColE9 synthesis induced by SOS response inducing agents including antibiotics. Using green fluorescent protein expression from the ColE9p–gfpmut2 as an indicator of ColE9 synthesis; we have investigated, first time, the inducing effects of cephalexin antibiotic on ColE9 synthesis. Our data demonstrated that the cephalexin has potential to induce ColE9 synthesis from E. coli JM83 host cells albeit the level of this induction is very low hence its detection required a highly sensitive method.     

The target of the negative regulator of pMB1 replication overlaps with part of the repressor coding sequence

Summary Plasmid mutants (svir), insensitive to inhibition by the repressor of initiation of pMB1 replication, have been selected by exploiting their ability to support growth in the presence of repressor and inhibitor of plasmid replication. The alteration in the mechanism that controls plasmid replication causes a change in the plasmid copy number. svir mutants are dominant, as expected for mutants in the target of a repressor, but at the same time they are unable to synthesise a repressor active on the wild-type target. This lack of cross interaction between svir mutants and a co-resident wild-type plasmid results in their compatibility. These findings are explained by postulating that the target of the inhibitor of pMB1 replication coincides with part of the DNA segment that codes for the inhibitor itself. As a consequence single base pair changes in the target result in altered repressor molecules.     

Nucleotide sequence and regulated expression of the Salmonella fljA gene encoding a repressor of the phase 1 flagellin gene

Summary The nucleotide sequence of Salmonella abortus-equi fljA, which together with the phase 2 flagellin gene constitutes the fljBA operon and encodes the repressor for the phase 1 flagellin gene fliC, was determined. The repressor was predicted to be a basic protein consisting of 179 amino acid residues (M_r = 20419 Da) encoded by ORFII. This was confirmed by the fact that host fliC is repressed by plasmid-encoded ORFII, which indeed expresses a 20 kDa product as determined by urea SDS-polyacrylamide gel electrophoresis. An amino acid sequence capable of forming a helix-turn-helix type of structure was predicted in the C-terminal region of FljA. A rho-independent intercistronic terminator was detected between fljB and ftjA. Chloramphenicol acetyltransferase (CAT) assays of fusions indicated that the terminator is capable of reducing expression of fljA to the level of a few percent, relative to fljB in broth cultures and to 1 % in M9 glycerol cultures.     

Protein folding forces

We investigate the average inter-residue folding forces derived from mutational data of the 15 proteins: barstar, barnase, chymotrypsin inhibitor 2 (CI2), Src SH3 domain, spectrin R16 domain, Arc repressor, apo-azurin, cold shock protein B (cspB), C-terminal domain of ribosomal protein L9 (CTL9), FKBP12, α-lactalbumin, colicin E7 immunity protein 7 (IM7), colicin E9 immunity protein 9 (IM9), spectrin R17 domain, and ubiquitin. The residue-specific contributions to folding in most of the 15 protein molecules are highly non-uniformly distributed and are typically about 1 piconewton (pN) per interaction. The strongest folding forces often occur in some of the helices and strands of folding nuclei which suggests that folding nucleation−condensation is partially directed by formation of some secondary structure interactions. The correlation of the energy changes of mutants with inter-residue contact maps of the protein molecules provides a higher resolution than assigning the mutant data to certain positions in the polypeptide strand alone. In contrast to previous Φ-value analysis, we now can partially resolve folding motions. Compaction of at least one α-helix along its axis mediated by internal hydrogen bonds and stabilized by diffuse tertiary structure interactions appears to be one important molecular event during early folding in barstar, CI2, spectrin R16 domain, Arc repressor, α-lactalbumin, IM7, IM9, and spectrin R17 domain. A lateral movement of at least two strands neighbored in sequence towards each other appears to be involved in early folding of the SH3 domain, cspB, CTL9, and FKBP12.