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     

Genetic and biochemical characterization of periplasmic-leaky mutants of Escherichia coli K-12.

Periplasmic-leaky mutants of Escherichia coli K-12 were isolated after nitrosoguanidine-induced mutagenesis. They released periplasmic enzymes into the extracellular medium. Excretion of alkaline phosphatase, which started immediately in the early exponential phase of growth, could reach up to 90% of the total enzyme production in the stationary phase. Leaky mutants were sensitive to ethylenediaminetetraacetic acid, cholic acid, and the antibiotics rifampin, chloramphenicol, mitomycin C, and ampicillin. Furthermore, they were resistant to colicin E1 and partially resistant to phage TuLa. Their genetic characterization showed that the lky mutations mapped between the suc and gal markers, near or in the tolPAB locus. A biochemical analysis of cell envelope components showed that periplasmic-leaky mutants contained reduced amounts of major outer membrane protein OmpF and increased amounts of a 16,000-dalton outer membrane protein.     

Mutagenesis of plasmid DNA with hydroxylamine: Isolation of mutants of multi-copy plasmids

Summary An investigation of in vitro mutagenesis of plasmid DNA with hydroxylamine is described. The treated plasmid DNA was used to transform Escherichia coli K12. Mutants of the plasmid NTP3, which codes for resistance to ampicillin and sulphonamides, were isolated and characterised. They were classified according to the reduction in level of their -lactamase activity. Hydroxylamine-induced mutants of NTP14 were also isolated. This plasmid codes for ampicillin resistance, synthesis of colicin E1, and the EcoRI restriction and modification enzymes. One class of mutants is lethal to the host strain at temperatures above 33° C, but carrier strains grow well at 28° C. There is evidence that these mutants code for a temperature-sensitive EcoRI modification activity: the lethal effect probably results from the cleavage of the host-cell DNA by the restriction enzyme at non-permissive temperatures. The possible genetic uses of the mutant plasmids for the production of hybrid plasmids in the bacterial cell are discussed.     

Isolation and properties of bacteriocin-tolerant mutants ofKlebsiella edwardsii var.edwardsii

Bacteriocin-resistant mutants ofKlebsiella edwardsii var.edwardsii were isolated, some of which, although still adsorbing the bacteriocin, were nevertheless insensitive (tolerant) to its effect.Selection was carried out with bacteriocins produced byKlebsiella pneumoniae (strains S6 and S8) andEnterobacter cloacae (strain DF 13). These bacteriocins are adsorbed by different receptor sites but have the same mode of action. Most of the isolated mutants (80–90%) could no longer adsorb any of the bacteriocins used. Therefore it is suggested that the different receptor sites on sensitive bacteria have some components in common. Seven different groups of tolerant mutants were isolated. The majority of these mutants are tolerant to the three bacteriocins used (Group I). In the other groups tolerance to one or two bacteriocins is accompanied by either sensitivity to, or resistance (non-adsorption) against, the other(s). The latter mutants must be considered as receptor mutants in which the specific stimulus sent from the bacteriocin receptor site through the cytoplasmic membrane to the intracellular target fails to initiate. Many tolerant mutants were extremely sensitive to desoxycholate and to ethylenediaminetetraacetate.The skillful technical assistance of Miss E. A. Spanjaerdt Speckman and Mr. E. Hoogendijk is gratefully acknowledged.     

Isolation of nonsense suppressor mutants in Pseudomonas.

A strain of Escherichia coli harboring the drug resistance plasmid RP1 was treated with the mutagen N-methyl-N-nitro-N-nitro-N-nitrosoguanidine, and mutants were isolated in which ampicillin resistance had been lost due to an amber mutation in the plasmid. One of these mutants was again treated, and a strain was isolated in which tetracycline resistance was also lost due to an amber mutation in the plasmid. The plasmid containing amber mutations in the genes amp and tet was named pLM2. This plasmid could be transferred to strains of Pseudomonas aeruginosa, P. phaseolicola, and P. pseudoalcaligenes. Mutants resistant to ampicillin and tetracycline could not be obtained from P. phaseolicola carrying pLM2. However, strains of E. coli, P. aeruginosa, and P. pseudoalcaligenes carrying the plasmid did produce mutants simultaneously resistant to both antibiotics. All of the mutants of E. coli had developed nonsense suppressors since they became phenotypically lac+, although harboring a lac amber mutation, and formed plaques with amber mutants of phages PRR1 and PRD1 that attack organisms carrying RP1. Approximately 20% of the resistant mutants of P. aeruginosa and P. pseudoalcaligenes were sensitive to the amber mutant of PRD1. These mutants were of variable stability and grew somewhat more slowly than their parent strains. One of the suppressor mutants of P. pseudoalcaligenes, designated ERA(pLM2)S4, was used for the isolation of nonsense mutants of bacteriophage PHA6, a virus having a segmented genome of double-stranded ribonucleic acid and an envelope of lipids and proteins.     

Recombination-deficient mutants of colicinogenic Salmonella typhimurium detected by their failure to produce colicin

Survivors of nitrosoguanidine-treated cultures of a colicinogenic strain of Salmonella typhimurium were tested for spontaneous production of colicin E1. Of about 1,000 colonies tested, 13 produced no (or very narrow) colicin zones. Four of these isolates proved to be more sensitive to ultraviolet (UV) light, X rays, and methyl methane sulfonate than the parent strain and did not show enhanced production of colicin when treated with mitomycin C (which acts as an inducer on wild-type cells). Further studies showed that these isolates were of two classes. Three mutants were extremely sensitive to UV, failed to show spontaneous release of two temperate phages, and were infertile as recipients in transduction or in an Hfr cross although they accepted an F' factor normally. These independently isolated mutants were inferred to be recombination-deficient; one of them had the additional property of increased spontaneous mutability at two loci. The other colicin-nonreleasing isolate was only moderately sensitive to UV, showed enhanced spontaneous release of two temperate phages, and was of approximately normal fertility as a recipient in transduction or conjugation.     

Defeat of colicin tolerance in Escherichia coli ompA mutants: evidence for interaction between colicin L-JF246 and the cytoplasmic membrane.

Escherichia coli ompA mutants are tolerant to colicin L-JF246. This tolerance can be overcome by a variety of treatments that have as their target the outer membrane or the peptidoglycan layers of the cell envelope. Thus, increasing the concentration of colicin L, releasing lipopolysaccharide from the outer membrane by treatment of intact cells with ethylenediaminetetracetic acid (EDTA), converting cells to spheroplasts by treatment with lysozyme-EDTA or penicillin, or trypsin, treatment of intact cells will result in an increased colicin sensitivity. These treatments alter the outer membrane of ompA mutants and suggest that the altered outer membrane may allow the penetration of at least a portion of the colicin L molecule to a site of action located within this barrier. To substantiate this, we have demonstrated that membrane vesicles prepared from ompA mutants are sensitive to colicin L and that 14C-labeled colicin L binds rapidly to both the outer and inner membrane fractions of the cell.     

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.     

Study of envelope proteins in E. coli cet and recA mutants by SDS acrylamide gel electrophoresis

Disc-electrophoresis of E. coli envelope proteins on SDS acrylamide gels reproducibly revealed up to 50 distinct polypeptide bands. Corresponding molecular weights ranged from 105,000 to 20,000 daltons or less. Major bands corresponded to molecular weights of 73,000, 48,000, 36,000 and 30,000 with the latter constituting up to 20% of the total envelope protein depending upon the method of isolation. Minimum levels of detection using stained gels equaled 0.25 μg protein or 1% of total sample analyzed; for a polypeptide of molecular weight 40,000 daltons this was calculated to be equivalent to 1,200 molecules per cell envelope. In envelopes from a cetB^? mutant strain (refractory to colicin E2), an additional band, constituting up to 5% of the total envelope protein was present. The molecular weight of this protein, which was maximally present in wild type envelopes in only trace amounts, is 44,000 daltons, indicating a cellular concentration of approximately 6 × 10³ molecules per envelope. This new band was not affected by heating envelope preparations to 100° prior to electrophoresis, but was largely eliminated by washing isolated envelopes in low ionic strength buffer, or by pre-incubating cells with trypsin prior to preparation of envelopes. Treatment of isolated envelopes with Triton X-100, which preferentially releases inner membrane proteins from the envelope (18), resulted in the extraction of a preponderance of the high molecular weight polypeptides, including the 44,000 dalton protein from envelopes of the mutant. The major polypeptides of the envelope and the low molecular weight components were not extracted by Triton X-100. The properties of the 44,000 dalton protein indicated that it is relatively loosely associated with the surface envelope and may be exposed on the external surface of the cytoplasmic membrane. Possible explanations for the appearance of this protein in mutant strains and its relationship to the inability of these to respond, specifically to surface bound colicin E2, will be discussed. Extensive analysis of envelopes from recA^? mutants was also carried out and revealed an unusual amount of variation in polypeptide profiles obtained from different preparations. However, no consistent quantitative or qualitative difference between recA and rec⁺ strains was obtained. In recA, cetB double mutants, the increased level of the 44,000 dalton polypeptide was identical to that found in the rec⁺, cetB mutant.     

Colicin Tolerance Induced by Ampicillin or Mutation to Ampicillin Resistance in a Strain of Escherichia coli K-12

A mutant (G11el) of Escherichia coli selected as being resistant to ampicillin and showing signs of an envelope defect was also found to be tolerant to colicins E2 and E3. The colicin tolerance of G11el could be partially repressed by Mg(2+) ions. Transition from tolerance to sensitivity and vice versa by shifting the concentration of Mg(2+) in the growth medium required several generations. This indicated that synthesis of new envelope material was needed for transition. Previous physiological results have indicated a change in the envelope lipopolysaccharide (LPS) of G11el. However, chemical analyses revealed no differences in carbohydrate composition between LPS from G11el and its parent strain G11al. Genetic experiments showed that the mutation in G11el is located at about 20 min on the E. coli K-12 chromosome. The mutation was dominant over wild type in partial diploids with the mutation located on the episome. Because colicin tolerance was the most striking phenotypic effect as a result of mutation in the actual locus, this gene will be named tolD until the exact gene product is known. Spheroplasts formed from G11al and G11el by ethylenediaminetetraacetate-lysozyme treatment did not adsorb colicin E2; however, penicillin spheroplasts of G11al and G11el were tolerant to colicin E2. Thus, colicin tolerance can be induced biochemically. It is suggested that colicin tolerance often is a secondary consequence of a change in the cell envelope.     

Functional Interaction of the tonA/tonB Receptor System in Escherichia coli

Host range mutants of phage T1 (T1h), which productively infected tonB mutants of Escherichia coli, were isolated. The phage mutants were inactivated by isolated outer membranes of E. coli in contrast to the wild-type phage, which only adsorbed reversibly. For the infection process, the tonB function is apparently only required for the irreversible adsorption of the phage T1, but not for the transfer of the phage DNA through the outer membrane and the cytoplasmic membrane of the cell. Mutants of the tonA gene expressing normal amounts of outer membrane receptor proteins were isolated and found to be partially sensitive to phage T5 and resistant to the phages T1 and T1h, colicin M, and albomycin and unable to take up iron as a ferrichrome complex. One tonA mutant remained partially sensitive to T5, colicin M, and albomycin and supported growth of T1h (not of T1) with the same plating efficiency as the parent strain. Only a small region of the tonA receptor protein seems to function for all the very different substrates. A newly isolated host range mutant of T5 (T5h) adsorbed faster to tonA(+) cells than did wild-type T5 and infected tonA missense mutants resistant to wild-type T5. The interplay of the tonA with the tonB function was observed with phage T5 infection, although T5 required only the tonA receptor. Ferrichrome inhibited plaque formation of T5 only when plated on tonB mutants. Adsorption of T5 to cells in liquid medium was influenced by ferrichrome as follows: complete inhibition by 0.1 muM ferrichrome with tonB mutants, not more than 35% inhibition by 1 to 100 muM ferrichrome with the tonB(+) parent strain in the presence of glucose as energy source, and 90% inhibition by 1 muM ferrichrome with partially starved parent cells. We conclude that there exist different functional states of the receptor protein that depend on the energy state of the cell and the tonB function. The latter seems to be required only for translocation processes with outer membrane proteins involved.     

Evidence for the Direct Action of Colicin K on Aerobic 32Pi Uptake in Escherichia coli In Vivo and In Vitro

Pentachlorophenol (PCP)-sensitive incorporation of (32)P-labeled orthophosphate ((32)P(i)) into nucleotides and nucleic acids by disrupted spheroplasts of Escherichia coli was inhibited by addition of colicin K. Incorporation by intact cells was also inhibited by a similar concentration of colicin K. Various colicin K-resistant mutants were isolated, and their ability to incorporate (32)P(i) was tested. When T6(r)-colK(r) mutants (T6 phage-resistant) and tol I mutants (T6-sensitive, colicin E-sensitive) were converted to disrupted spheroplasts, their (32)P(i)-incorporation became sensitive to colicin K. On the contrary, incorporation by disrupted spheroplasts from tol II mutants (T6-sensitive, colicin E-resistant) was fairly resistant to colicin K like that of intact cells. A modification of the cell surface of T6(r)-colK(r) mutants, caused by mutation to novobiocin-permeable, T4 phage-resistant cells, restored the sensitivity of the cells to colicin K. The modified T6(r)-colK(r) cells did not adsorb T6 phage or colicin K, indicating that the receptors for T6 phage or colicin K are not reactivated by this modification. Similar treatment of tol I mutants did not have this effect. These observations strongly suggest that colicin K can act on its target on the cell membrane if it can penetrate the cell surface to reach this target. The receptor for colicin K on the cell surface, which may be part of the T6 phage-receptor, may have some unknown function in relation to the action of colicin K in normal cells, but tends to become dispensable if the cells become permeable to colicin K.     

Mutant of Escherichia coli with Anomalous Cell Division and Ability to Decrease Episomally and Chromosomally Mediated Resistance to Ampicillin and Several Other Antibiotics

In a mutation experiment with a rough, ampicillin-resistant strain, we isolated two smooth mutants which were both sensitive to ampicillin and carried defects in the cell envelope. One of the strains (with the envA gene) is hindered in its completion of septa and forms chains of cells. The envA gene has been mapped to a position between leu and proB, at 2 to 4 min. The envA gene decreased the resistance mediated by both episomal and chromosomal genes for resistance to several antibiotics. During growth the envA mutant was characterized by abnormal ratios between viable count or cell count and optical density. The ratio between viable count and optical density was affected during shift-up and shift-down experiments. When compared to the parent strain, the envA mutant was found to be more resistant to ultraviolet irradiation on plates. Prestarvation for tryptophan had a protective effect against irradiation both on the parent strain and the envA mutant.     

Mutants of Caulobacter crescentus resistant to beta-lactam antibiotics

A number of mutants of Caulobacter crescentus CB15 resistant ot ampicillin were isolated. The mutants differred in their resistance to several beta-lactam antibiotics. No differences in composition of the penicillin-binding proteins of the mutants compared to the parental strain, or in the affinity of these proteins to penicillin or ampicillin were found. The mutants were found to differ from the parent and also in many cases from each other in outer membrane protein composition.     

Colicin Ia and Ib binding to Escherichia coli envelopes and partially purified cell walls

The specific binding of ¹²⁵ Iodine labelled colicin Ia and Ib to Escherichia coli cell envelopes and partially purified cell walls is demonstrated. Neither partially purified cytoplasmic membranes isolated from a wild type sensitive strain nor envelopes or cell walls prepared from an E. coli mutant known to be defective in the colicin I receptor could bind the colicins. Competition studies suggest that colicins Ia and Ib have a common bacterial receptor which resides in the bacterial cell wall.     

Localization and Solubilization of Colicin Receptors

Envelope fractions isolated from Escherichia coli K-12 C600 and from colicin-resistant and colicin-tolerant (Tol II) mutants derived from this strain were separated on sucrose gradients into cell wall-enriched and cytoplasmic membrane-enriched fractions. These fractions were tested for their ability to neutralize colicins of the E and K groups. Neutralization activity was found in the cell wall-enriched fraction from the parent and the Tol II mutant but was absent from all fractions from the resistant mutant. This was also tested with several other E. coli strains. In all cases, sensitive strains contained the neutralization activity, whereas resistant strains did not. The neutralization activity was solubilized from cell walls or cell envelopes of sensitive or Tol II strains by extraction at room temperature with Triton X-100 plus ethylenediaminetetraacetic acid. The solubilized activity was precipitated by 20% ammonium sulfate, 70% ethanol, or 10% trichloroacetic acid. The activity was destroyed by treatment of the solubilized preparation with trypsin or periodate. These results suggest that this colicin-neutralization activity is due to the presence of specific receptors localized in the cell wall and that intact protein and a carbohydrate are required for this receptor to bind colicin.     

Isolation and characterization of ColE2 plasmid mutants unable to kill colicin-sensitive cells

Summary After transfer from a mutagenized host, twenty one ColE2 plasmid mutants were isolated after screening 10,000 clones for abnormal colicin production. Analysis by SDS polyacrylamide slab gel electrophoresis of proteins synthesized after mitomycin C-induction of mutant cultures, indicates that all but two of the mutations are in the structural gene for colicin E2. Of these, nine produce fragments of colicin in both whole cells and minicells and some are suppressed by nonsense suppressors.Studies with a nonsense mutant producing only a small colicin E2 fragment (ColE2-421) suggest that colicin E2 is not involved in plasmid DNA replication, in the control of its own synthesis, or required for cell death when cells become committed to colicin production. The two plasmid mutants outside the colicin gene segregate plasmid-free cells at 33°, 37° and 43°. One segregates fairly rapidly (about 4% per generation) though the colicin-producing cells make normal amounts of colicin, whilst the other segregates more slowly and the colicin-producing cells make much reduced amounts of colicin.     

Colicinogenic mutant of ColE1 plasmid that fails to confer immunity to colicin E1.

Insertion of the ampicillin transposon (Tn3) into ColE1 DNAs causes various mutations in the plasmids. Escherichia coli K-12 cells carrying one of these mutants showed novel properties; they were sensitive to colicin E1 and were able to produce active colicin E1. The site and the orientation of Tn3 insertion in this mutant ColE1 DNA were determined by heteroduplex analysis and by enzymatic digestion with restriction endonucleases. The potential usefulness of this mutant ColE1 DNA as a cloning vehicle is discussed.     

Transposition of ampicillin resistance to an enterotoxin plasmid in an Escherichia coli strain of human origin.

We examined a strain of Escherichia coli, serotype O159.H34, of human origin which produced heat-stable and heat-labile enterotoxins, was resistant to ampicillin, and produced colicin. By conjugation and transformation experiments plasmids coding for enterotoxin production (Ent), enterotoxin production and ampicillin resistance (Ap-Ent), ampicillin resistance (Ap), and colicin production were isolated. Both the Ent and Ap-Ent plasmids were autotransferring and belonged to the F-incompatibility complex. However, the Apr Ent+ transconjugants showed differences in their levels of resistance and in their abilities to propagate F-specific phages and to transfer resistance. The results suggested there was transposition from the small Ap plasmid to the Ent plasmid. The Ap-Ent plasmids were larger than the enterotoxin factor and when treated with restriction endonuclease BamHI showed an additional fragment not present in the enterotoxin plasmid. The insertion of ampicillin resistance probably occurred at different sites on the enterotoxin plasmid, resulting in the observed variation in phenotype.     

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.