Growth inhibition of Escherichia coli by E colicin plasmids

Plasmids were isolated from E colicinogenic strains and transformed into prototrophic Escherichia coli K 12 strain DB364. Screening of E colicinogenic transformants for growth on defined medium revealed an apparent amino acid auxotrophy mediated by E4 and, to a lesser extent, E7 colicin plasmids. The auxotrophy was further investigated in E4 colicinogenic strains. From such auxotrophic transformants, denoted Pmi+ (plasmid-mediated inhibition of growth), Pmi- variants were obtained at a frequency of 3 X 10(-4) per bacterium. Plasmid loss was not detected among Pmi- clones. Isolation of E4 colicin plasmids from Pmi- clones and retransformation of strain DB364 with these plasmids showed that 40% of the plasmids were unable to inhibit growth of DB364 and were inferred to have alterations in an E4 colicin plasmid gene termed pmi. All such plasmids were indistinguishable from native E4 colicin plasmids, with respect to colicin immunity, colicin production and excretion, and sensitivity to lysis by mitomycin C. Experiments examining the nutritional basis of the plasmid-mediated auxotrophy indicated that at least seven amino acids, isoleucine, leucine, valine, arginine, methionine, serine and glycine, were involved in the auxotrophy. However, supplementation with only these seven amino acids did not completely restore growth. Assays of the activities of enzymes involved in amino acid biosynthesis in colicinogenic and non-colicinogenic strains under repressing and derepressing growth conditions suggested that E4 colicin plasmids did not repress synthesis of the implicated amino acids.     

Colicins are not transiently accumulated in the periplasmic space before release from colicinogenic cells

Colicins are released into the spent medium from colicinogenic cells. The pathway of release has been investigated in this study. The localization in producing cells of colicins A, E3 and of cloacin DF13 has been determined at various times after mitomycin C addition: no transient accumulation in the periplasmic space of colicinogenic E. coli K12 strains was detected by electron microscopy for any of the bacteriocins tested. Furthermore, asynchronous induction in individual cells was detected for each bacteriocin tested. These results strongly suggest that colicins, as well as cloacin DF13, do not transit through the periplasmic space before release from colicinogenic cells.     

Further characterization of SOS system induction in recBC mutants of Escherichia coli

Expression of several SOS functions such as induction of lambda prophage, inhibition of cell division and induction of both umuC and recA genes after UV-irradiation, nalidixic acid or mitomycin C addition was studied in an RecBC- mutant. UV-irradiation and mitomycin C induced all SOS functions studied in the RecBC- cells but at a lower level and delayed with respect to the wild-type strain. On the contrary, nalidixic acid was unable to trigger any of these SOS functions. In the RecBC- mutant, adenine only had a stimulating effect on the amplification of RecA protein synthesis following UV-irradiation. Nevertheless, in the wild-type strain the stimulating effect occurred in all SOS functions studied following UV-irradiation as well as in the amplification of RecA protein synthesis by nalidixic acid but not in the other SOS functions triggered by this compound. Furthermore, adenine produced a decrease in the mitomycin C-mediated induction of all SOS functions studied in both RecBC- and wild-type strains.     

Plasmid ColE3 specifies a lysis protein.

Tn5 insertion mutations in plasmid ColE3 were isolated and characterized. Several of the mutants synthesized normal amounts of active colicin E3 but, unlike wild-type colicinogenic cells, did not release measurable amounts of colicin into the culture medium. Cells bearing the mutant plasmids were immune to exogenous colicin E3 at about the same level as wild-type colicinogenic cells. All of these lysis mutants mapped near, but outside of, the structural genes for colicin E3 and immunity protein. Cells carrying the insertion mutations which did not release colicin E3 into the medium were not killed by UV exposure at levels that killed cells bearing wild-type plasmids. The protein specified by the lysis gene was identified in minicells and in mitomycin C-induced cells. A small protein, with a molecular weight between 6,000 and 7,000, was found in cells which released colicin into the medium, but not in mutant cells that did not release colicin. Two mutants with insertions within the structural gene for colicin E3 were also characterized. They produced no colicin activity, but both synthesized a peptide consistent with their map position near the middle of the colicin gene. These two insertion mutants were also phenotypically lysis mutants--they were not killed by UV doses lethal to wild-type colicinogenic cells and they did not synthesize the small putative lysis protein. Therefore, the lysis gene is probably in the same operon as the structural gene for colicin E3.     

Isolation and characterization of a mutant of Escherichia coli K12 synthesizing DNA polymerase I and endonuclease I constitutively

A mutant of Escherichia coli K12, highly resistant to ultraviolet radiation, has been isolated. Preliminary tests show that this mutant is also resistant to mitomycin C, nalidixic acid, fluorouracil and thymineless death. The mutant strain apparently repairs its damaged DNA more efficiently than wild-type E. coli K12 strains and, to do so, constitutively produces 35 times more DNA polymerase I and 12 times more endonuclease I than the wild-type strain.     

FLO11 is the primary factor in flor formation caused by cell surface hydrophobicity in wild-type flor yeast

Some strains of Saccharomyces cerevisiae form a biofilm called a "flor" on the surface of wine after ethanolic fermentation, but the molecular mechanism of flor formation by the wild-type flor strain involved in wine making is not clear. Previously, we found that expression of the C-terminally truncated form of NRG1 (NRG1(1-470)) on a multicopy plasmid increases the hydrophobicity of the cell surface, conferring flor formation on the non-flor laboratory strain. Here we show that in Ar5-H12, a wild-type flor haploid strain, flor formation is regulated by NRG1(1-470). Moreover, the disruptant of the wild-type flor diploid strain (Deltaflo11/Deltaflo11) show a weak ability to form the flor. The expression of FLO11 is always high in the wild-type flor strain, regardless of carbon source. Thus FLO11 is primary factor for wild-type flor strains. Furthermore, the disruptant (Deltaflo11) shows lower hydrophobicity of cell surface than the wild type. However, the hydrophobicity of the wild-type flor strains grown in ethanol medium was much higher than those grown in glucose medium. These results indicate that cell surface hydrophobicity is closely related to flor formation in wild-type flor yeasts.     

Simultaneous exploitation of different peptide permeases by combinations of synthetic peptide smugglins can lead to enhanced antibacterial activity

Necrotizing Escherichia coli (NTEC) strains grown in the presence of mitomycin C released cell associated necrotizing factors CNF1 and CNF2 to culture medium. Using culture filtrates from 96 mitomycin C treated E. coli strains, we have found that a modified HeLa cell assay was a more sensitive and specific method for the detection of CNF1 and CNF2 than the Vero cell assay and the rabbit skin test.     

Mitomycin C and Temperature Induction of Colicin B in the Absence of Deoxyribonucleic Acid Synthesis

An Escherichia coli K-12 strain and its mutant, temperature-sensitive in deoxyribonucleic acid (DNA) synthesis, were used as hosts for two different ColB factors (ColB3-K166 and ColB4-K98). Induction of either colicin occurred in both hosts in the presence of mitomycin C at 42 C. Induction of the temperature-sensitive colicinogenic hosts also occurred without mitomycin C at 42 C at which temperature no DNA synthesis was observed. Colicin synthesis was a nonlethal event in ColB4-K98(+) cultures, whereas in cultures of ColB3-K166(+) induction led to death of a large fraction of the population.     

High-sensitivity detection of newly induced LamB protein on the Escherichia coli cell surface.

The kinetics of the appearance at the cell surface of the outer membrane LamB protein after induction were determined by using specific antibodies and radioiodinated protein A as a probe. This was done in two different induction systems. First, LamB protein was induced in a wild-type strain by the simultaneous addition of cyclic AMP and maltose. Second, an operon fusion strain in which the lamB gene is expressed under lac promoter control was used; in this system, LamB protein can be induced by isopropyl-beta-D-thiogalactopyranoside. When uninduced cells were grown in glucose minimal medium, background expression of the lamB gene was found to be ca. 10-fold lower in lac-lamB cells than in wild-type cells. The level of LamB protein present in uninduced wild-type cells could, however, be reduced by supplementing the growth medium with Casamino Acids. After induction, the LamB protein appeared at the cell surface of both strains within a few minutes, and then the LamB level per cell increased linearly. The time lag in cell surface exposure of LamB protein differed slightly under both induction conditions: the LamB protein appeared at the surface of lac-lamB cells within 3 min of induction, whereas in wild-type cells it could not be detected earlier than after 4 to 5 min of induction.     

Assessment of resistance to colicinogenic Escherichia coli by E. coli O157:H7 strains

AIMS: To assess a collection of 96 Escherichia coli O157:H7 strains for their resistance potential against a set of colicinogenic E. coli developed as a probiotic for use in cattle. METHODS AND RESULTS: Escherichia coli O157:H7 strains were screened for colicin production, types of colicins produced, presence of colicin resistance and potential for resistance development. Thirteen of 14 previously characterized colicinogenic E. coli strains were able to inhibit 74 serotype O157:H7 strains. Thirteen E. coli O157:H7 strains were found to be colicinogenic and 11 had colicin D genes. PCR products for colicins B, E-type, Ia/Ib and M were also detected. During in vitro experiments, the ability to develop colicin resistance against single-colicin producing E. coli strains was observed, but rarely against multiple-colicinogenic strains. The ability of serotype O157:H7 strains to acquire colicin plasmids or resistance was not observed during a cattle experiment. CONCLUSIONS: Escherichia coli O157:H7 has the potential to develop single-colicin resistance, but simultaneous resistance against multiple colicins appears to be unlikely. Colicin D is the predominant colicin produced by colicinogenic E. coli O157:H7 strains. SIGNIFICANCE AND IMPACT OF THE STUDY: The potential for resistance development against colicin-based strategies for E. coli O157:H7 control may be very limited if more than one colicin type is used.     

Isolation and Characterization of a Copy Mutant of the Bacteriocinogenic Plasmid Clo DF13

After nitrosoguanidine mutagenesis, strain Escherichia coli P678-54, bacteriocinogenic for Clo DF13, yielded a mutant strain that showed an enhanced bacteriocin production. The results from conjugation experiments indicated that the mutation, responsible for the enhanced bacteriocin production, is located on the Clo DF13 plasmid. The following properties of strains harboring the mutant Clo DF13 plasmid could be observed. (i) The bacteriocin production in these strains can be further enhanced at least fourfold by mitomycin C. (ii) The fraction of spontaneously induced cells, as revealed by lacunae experiments, in cultures of these strains is about nine times higher than in cultures of wild-type Clo DF13-harboring strains. (iii) Chromosomeless minicells from strain P678-54 harboring the mutant Clo DF13 plasmid synthesize about six times more deoxyribonucleic acid, ribonucleic acid, and protein as compared to wild-type Clo DF13-harboring minicells. (iv) Analysis of this mutant Clo DF13-specific ribonucleic acid and protein on polyacrylamide gels revealed mainly the same ribonucleic acid and polypeptide species as synthesized by the wild-type Clo DF13 minicells, but in larger amounts (Kool et al., 1974). (v) Segregation experiments, using a strain with temperature-sensitive polymerase I, show that mutant Clo DF13-harboring cells contain an average of 70 Clo DF13 copies per cell, whereas wild-type Clo DF13-harboring cells contain only about 10 Clo DF13 copies per cell. The data presented in this paper indicate that the mutation on the Clo DF13 plasmid leads to an altered control of Clo DF13 replication and results in an enhanced number of Clo DF13 copies per cell. As a secondary effect, this enhanced number of Clo DF13 copies enhances the probability of "spontaneous" induction per cell. Since the mutation is plasmid specific and affects the number of plasmid copies produced, one can conclude that the Clo DF13 plasmid is not dependent solely on chromosomal information, but that at least plasmid base sequences are involved in Clo DF13 plasmid replication.     

Genetic control of the protective effect of spermidine in Escherichia coli cells as affected by mitomycin C

The lethal action of mitomycin C and the effect of mutual treatment with mitomycin C and spermidine on Escherichia coli were studied. DNA repair in cells treated with mitomycin C was shown to have some differences, as compared to that of UV-induced pyrimidine dimers. The presence of the additive sbcB mutation increases the resistance of wild-type bacteria as well as of recBrecC and recF mutants to the lethal action of mytomicin C. Preliminary treatment of bacteria with spermidine increases resistance to the lethal action of the mutagen in wild-type bacteria as well as uvrB, recBrecC and sbcB strains. However, no such effect was observed in recF, recFsbcB and uvrE strains. The data suggest that the protective action of spermidine may be connected with stimulation of RecF-pathway of postreplication repair.     

Increased superoxide radical production evokes inducible DNA repair in Escherichia coli

Paraquat induced the SOS response in Escherichia coli. This was measured in terms of acquired resistance towards UV lethality in a wild-type strain and in terms of appearance of beta-galactosidase activity in a din::Mu d(Ap lac) fusion strain. However measured, the induction of the SOS response by paraquat was entirely dioxygen-dependent; whereas induction of the SOS response by mitomycin C was independent of the presence of dioxygen. As expected, recA(Def) and lexA(Ind-) isogenic strains did not show the SOS response. It appears likely that O-2, whose intracellular production is increased by paraquat, leads to DNA damage which in turn induces the SOS response.     

Carbonyl cyanide-m-chlorophenyl hydrazone-resistant Escherichia coli mutant that exhibits a temperature-sensitive unc phenotype.

Two spontaneous Escherichia coli mutant strains which are resistant to an oxidative phosphorylation uncoupler, carbonyl cyanide-m-chlorophenyl hydrazone, were isolated. Strain CM22 (ccr-2) was resistant to another uncoupler, pentachlorophenol, and to the inhibitors of proton-translocating ATPase, namely tributyltin and sodium azide. Carbonyl cyanide-m-chlorophenyl hydrazone or pentachlorophenol administered to cell suspensions of strain CM22 did not cause a pH change induced by H+ influx, and a similar result was obtained with everted particles. The respiratory rate of strain CM22 with succinate was twice that of wild-type strain KH434. When carbonyl cyanide-m-chlorophenyl hydrazone was administered, a stimulation of O2 uptake was observed in wild-type strain KH434 but not in the mutant strain CM22. Strain CM22 did not grow on succinate at 42 degrees C. Isolation of a true revertant at a frequency of 10(-8) demonstrated that the pleiotropic phenotype was induced by a single mutation. P1 transduction indicated that the mutant allele, ccr-2, was cotransduced with the ilv genes at a frequency of about 55%.     

Bacteriophage conversion of heat-labile enterotoxin in Escherichia coli.

A temperate phage designated obeta1 (omicron beta) was mitomycin C induced and isolated from heat-labile enterotoxin (LT)-producing Escherichia coli E2631-C2. Phage obeta1 infected the nonlysogenic, nontoxigenic, mitomycin C-sensitive strain of E. coli K-12 (CSH38) and converted it to lysogeny and enterotoxigenicity. After the establishment of lysogeny, E. coli CSH38(obeta1) produced produced LT and phage particles at maximal levels following mitomycin C induction. The LT Tox+ character is carried by the temperate phage obeta1.     

Evolution of a Site of Specific Genetic Homology on the Chromosome of Escherichia coli

Integration of the factors F(v) and F into the chromosome of a substrain of Escherichia coli K-12 has been studied. The F(v) factor is a fertility factor derived from Col V, lacking the ability to govern the production of colicin V. The derivatives of an Hfr(v) (Hfr isolated from a V colicinogenic parent) strain, PK2 (initially isolated from C600 V(+)), were shown to retain a unique bidirectional sex factor affinity locus between recA and pheA. This site shows no affinity for the E. coli K-12 F factor as shown by inability to isolate Hfr strains with origins in this region from a parental strain containing a cytoplasmic F factor. However this area exhibits two regions of homology to the V colicinogenic factor. One gives rise to Hfr(v) strains identical to the original Hfr(v) strain, PK2, with an origin and polarity of transfer designated pheA-CC injecting markers in the order pheA-his-trp-pro. The second gives rise to strains apparently originating at the same site but with reverse polarity designated recA-C, transferring markers in the order recA-thyA-str-xyl. For strains possessing the F(v) factor only the second homology is apparent. A model for the evolution of these strains is presented.     

Interaction between colicinogenic factor V and the integrated F factor in an Hfr strain of Escherichia coli

Kahn, Phyllis L. (Princeton University, Princeton, N.J.), and Donald R. Helinski. Interaction between colicinogenic factor V and the integrated F factor in an Hfr strain of Escherichia coli. J. Bacteriol. 90:1276-1282. 1965.-The production of colicin V by strains of Escherichia coli is determined by a colicinogenic factor, colV. The colV factor possesses a genetic determinant of fertility, F(v). V(+)F(v) (+) cells are characteristically susceptible to a male-specific phage, mu, and able to transfer the colV factor and chromosomal markers to recipient cells. The present work describes an interaction of the colV factor with the chromosome of the Hfr strain, HfrH. A colV-containing HfrH strain, designated HfrHV(+)F(v) (+)(l), was isolated and shown to be insensitive to phage mu and impaired in its fertility properties. Loss of the colV factor by this strain, either spontaneous or induced by acridine orange, resulted in a further 10(3)- or 10(4)-fold loss in fertility. This additional loss of fertility was restored by reinfection of these strains with the colV factor. The colV interaction with the HfrH chromosome also can result in defects in the fertility properties of the colV factor. Altered colV factors were found in recombinants isolated from a cross between the HfrHV(+)F(v) (+)(l) strain and F(-) recipients. It is postulated that in the HfrHV(+)F(v) (+)(l) strain an interaction of the colV episome with the integrated F region of the chromosome occurs, with a resulting modification of the fertility properties of the HfrH strain. This interaction can also result in a defect in certain properties of the colV factor.     

Comparison of the Escherichia coli umu+-encoded function with plasmid R46-mediated error-prone repair in DNA-damaged cells

Escherichia coli strain TK701 umu+ was more resistant than strain TK702 umu when tested against bleomycin (BLM), cis-platinum(II) diamminodichloride (PDD), ultraviolet light and methyl methanesulphonate (MMS), which produce single-strand DNA damage. However, the umu mutant was no more sensitive to mitomycin C (MTC) or proflavine (PF), which cause double-strand DNA binding. Strain TK702 umu was nonmutable by any of the agents, whereas mutations were induced in the wild-type strain by PDD, UV, MMS and MTC. The E. coli umu+ function therefore mimics plasmid R46-mediated error-prone repair in protecting only against single-strand DNA damage, whilst enhancing mutagenesis by both single- and double-strand damaging agents. Comparison of plasmid R46-mediated protection and mutagenesis in umu+ and umu strains indicated that the plasmid confers a greater error-prone DNA-repair activity in the mutant. Results are discussed in terms of analogy between host umu+ and plasmid muc+ functions.     

Respiration shutoff in Escherichia coli K12 strains is induced by far ultraviolet radiations and by mitomycin C

Ultraviolet radiations (254 nm) (UV) cause respiration to shutoff in Escherichia coli B/r. It has been reported [P.A. Swenson, Photochem. Photobiol., 33 (1981) 855-859 and J. Barbé, A. Vericat and R. Guerrero, Mutation Res., 120 (1983) 1-5] that E. coli K12 strains do not shut off respiration after UV. The latter authors also reported that mitomycin C did not cause this 'SOS' response. In this paper we report that higher UV fluences than were previously used will cause respiration shutoff in K12 strain W3110 and that cyclic AMP increases the sensitivity of respiration shutoff of irradiated cell suspensions. We also report that mitomycin C shuts off respiration in this strain. Neither UV nor mitomycin C causes respiration shutoff in the recA56 derivative of W3110. Thus respiration shutoff is a recA dependent response to UV and mitomycin C in E. coli K12 strains.