Stabilizing Effect of Colicin E2 on the “Spheroplast Membrane”

Cells of Escherichia coli W3110 and its thymineless mutant, both of which are colicin E2 sensitive, were treated with colicin E2, and then converted to spheroplasts. These spheroplasts seemed to be more stable than those from untreated cells; suspensions of spheroplasts of untreated cells were lysed spontaneously and the turbidity was reduced by approximately 45% on incubation with ethylenediaminetetraacetic acid-lysozyme, whereas suspensions of spheroplasts of colicin E2-treated cells showed 25% reduction in turbidity. This change was irreversible and 5 min of treatment with colicin E2 at 37 C was necessary for stabilization. This process was inhibited by 2,4-dinitrophenol or streptomycin. Cells harboring the colicin E2 factor were not affected by treatment in this way with colicin E2. Alteration of composition of phospholipids was not observed.     

Delineation of the translocation of colicin E7 across the inner membrane of <Emphasis Type="Italic">Escherichia coli</Emphasis>

The lysis protein of the colicinogenic operon is essential for colicin release and its main function is to activate the outer membrane phospholipase A (OMPLA) for the traverse of colicin across the cell envelope. However, little is known about the involvement of the lysis protein in the translocation of colicin across the inner membrane into the periplasm. The introduction of specific point mutations into the lipobox or sorting signal sequence of the lysE7 gene resulted in the production of various forms of lysis proteins. Our experimental results indicated that cells with wild-type mature LysE7 protein exhibited higher efficiency of colicin E7 translocation across the inner membrane into the periplasm than those with premature LysE7 protein. Moreover, the degree of permeability of the inner membrane induced by the mature LysE7 protein was significantly increased as compared to the unmodified LysE7 precursor. These results suggest that the efficiency of colicin movement into the periplasm is correlated with the increase in inner membrane permeability induced by the LysE7 protein. Thus, we propose that mature LysE7 protein has two critical roles: firstly mediating the translocation of colicin E7 across the inner membrane into the periplasm, and secondly activating the OMPLA to allow colicin release.     

Role for Endonuclease I in the Transmission Process of Colicin E<Subscript>2</Subscript>

The bactericide colicin E₂ is believed to act by binding to surface receptors and thereby initiating the movement of periplasmic endonuclease I to the membrane or cytoplasm, with subsequent DNA degradation. Escherichia coli cells are found to become resistant to colicin E₂ by losing their endonuclease I through mutation or osmotic shock treatment.     

Novel colicin Fy of Yersinia frederiksenii inhibits pathogenic Yersinia strains via YiuR-mediated reception, TonB import, and cell membrane pore formation

A novel colicin type, designated colicin Fy, was found to be encoded and produced by the strain Yersinia frederiksenii Y27601. Colicin Fy was active against both pathogenic and nonpathogenic strains of the genus Yersinia. Plasmid YF27601 (5,574 bp) of Y. frederiksenii Y27601 was completely sequenced. The colicin Fy activity gene (cfyA) and the colicin Fy immunity gene (cfyI) were identified. The deduced amino acid sequence of colicin Fy was very similar in its C-terminal pore-forming domain to colicin Ib (69% identity in the last 178 amino acid residues), indicating pore forming as its lethal mode of action. Transposon mutagenesis of the colicin Fy-susceptible strain Yersinia kristensenii Y276 revealed the yiuR gene (ykris001_4440), which encodes the YiuR outer membrane protein with unknown function, as the colicin Fy receptor molecule. Introduction of the yiuR gene into the colicin Fy-resistant strain Y. kristensenii Y104 restored its susceptibility to colicin Fy. In contrast, the colicin Fy-resistant strain Escherichia coli TOP10F' acquired susceptibility to colicin Fy only when both the yiuR and tonB genes from Y. kristensenii Y276 were introduced. Similarities between colicins Fy and Ib, similarities between the Cir and YiuR receptors, and the detected partial cross-immunity of colicin Fy and colicin Ib producers suggest a common evolutionary origin of the colicin Fy-YiuR and colicin Ib-Cir systems.     

Obligatory coupling of colicin release and lysis in mitomycin-treated Col+ Escherichia coli

Previous work has shown that Escherichia coli K12 strains carrying the small, high copy number ColE2-P9 plasmid produce large amounts of colicin and then lyse and release colicin when grown in broth culture containing mitomycin C. Strains carrying the larger, low copy number ColIa-CA53 plasmid produced much less colicin and did not lyse or discharge more than 15% of their colicin when grown under the same conditions. Naturally-occurring Col+ strains and E. coli K12 derivatives carrying different Col plasmids could be classified either as ColE2+-like or ColIa+-like according to whether or not they produced large amounts of colicin and lysed and discharged colicin when grown in the presence of mitomycin, and also by the size and presumed copy number of the Col plasmid they carried. Strains carrying multiple copies of the cloned colicin Ia structural gene produced large amounts of colicin but did not lyse or release colicin when grown in the presence of mitomycin. This result rules out the possibility that high level accumulation of colicin is sufficient to cause lysis. Conditions were sought under which colicin Ia could be released from the producing cells. It was found that mitomycin-treated cultures of strains carrying both ColE2 and ColIa plasmids released both colicins when they lysed, although colicin Ia release occurred later than colicin E2 release. It was also noted that colicin Ia-laden cells released their colicin when diluted into fresh culture medium.     

In Vivo Processing of DNase Colicins E2 and E7 Is Required for Their Import into the Cytoplasm of Target Cells

DNase colicins E2 and E7, both of which appropriate the BtuB/Tol translocation machinery to cross the outer membrane, undergo a processing step as they enter the cytoplasm. This endoproteolytic cleavage is essential for their killing action. A processed form of the same size, 18.5 kDa, which corresponds to the C-terminal catalytic domain, was detected in the cytoplasm of bacteria treated with either of the two DNase colicins. The inner-membrane protease FtsH is necessary for the processing that allows the translocation of the colicin DNase domain into the cytoplasm. The processing occurs near residue D420, at the same position as the FtsH-dependent cleavage in RNase colicins E3 and D. The cleavage site is located 30 amino acids upstream of the DNase domain. In contrast, the previously reported periplasm-dependent colicin cleavage, located at R452 in colicin E2, was shown to be generated by the outer-membrane protease OmpT and we show that this cleavage is not physiologically relevant for colicin import. Residue R452, whose mutated derivatives led to toxicity defect, was shown to have no role in colicin processing and translocation, but it plays a key role in the catalytic activity, as previously reported for other DNase colicins. Membrane associated forms of colicins E2 and E7 were detected on target cells as proteinase K resistant peptides, which include both the receptor-binding and DNase domains. A similar, but much less proteinase K-resistant form was also detected with RNase colicin E3. These colicin forms are not relevant for colicin import, but their detection on the cell surface indicates that whole nuclease-colicin molecules are found in a stable association with the outer-membrane receptor BtuB of the target cells.     

Interaction of 125I-Labeled Colicin E1 with Escherichia coli

Colicin E1 protein was labeled with ¹²⁵I to specific activities of up to 2 × 10⁸ cpm/mg of protein and with no loss of the colicin biological activity. The labeled colicin bound to colicin E1-sensitive, tolerant, and immune E1-colicinogenic Escherichia coli. An E. coli mutant resistant to colicin E1 exhibited a much lower colicin-binding capacity. The average number of bound colicin molecules per sensitive cell increased as a function of the colicin concentration in the colicin cell interaction mixture and continued to increase even after loss of viability of the entire culture. Up to 2,400 colicin E1 molecules bound per cell, but saturation was not reached. Binding kinetics showed that maximum binding occurred within 2 to 5 min of colicin addition. Survival and binding assays indicated that one colicin killing unit corresponded to an average of about 100 colicin molecules bound per bacterial cell. This number, however, decreased to about 8 in more extensively washed cells. Trypsin digestion of the colicin-treated cells removed the majority of the cell-bound colicin, but in general provided little rescue from colicin killing. At low colicin concentrations, a linear relationship existed between survival and the number of trypsin-inaccessible colicin molecules. Under these circumstances and in agreement with single-hit kinetics, the relationship between the number of colicin killing units and the number of trypsin-inaccessible colicin molecules was close to 1. After trypsin digestion, cells that were nearly saturated with colicin retained about 200 trypsin-inaccessible colicin molecules per cell. The trypsin-inaccessible colicin might represent those colicin molecules that bound to the specific E colicin receptors of E. coli cells.     

The Tip of the Hydrophobic Hairpin of Colicin U Is Dispensable for Colicin U Activity but Is Important for Interaction with the Immunity Protein

The hydrophobic C terminus of pore-forming colicins associates with and inserts into the cytoplasmic membrane and is the target of the respective immunity protein. The hydrophobic region of colicin U of Shigella boydii was mutated to identify determinants responsible for recognition of colicin U by the colicin U immunity protein. Deletion of the tip of the hydrophobic hairpin of colicin U resulted in a fully active colicin that was no longer inactivated by the colicin U immunity protein. Replacement of eight amino acids at the tip of the colicin U hairpin by the corresponding amino acids of the related colicin B resulted in colicin U(575–582ColB), which was inactivated by the colicin U immunity protein to 10% of the level of inactivation of the wild-type colicin U. The colicin B immunity protein inactivated colicin U(575–582ColB) to the same degree. These results indicate that the tip of the hydrophobic hairpin of colicin U and of colicin B mainly determines the interaction with the corresponding immunity proteins and is not required for colicin activity. Comparison of these results with published data suggests that interhelical loops and not membrane helices of pore-forming colicins mainly interact with the cognate immunity proteins and that the loops are located in different regions of the A-type and E1-type colicins. The colicin U immunity protein forms four transmembrane segments in the cytoplasmic membrane, and the N and C termini face the cytoplasm.     

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.     

Role of ionic strength in colicin K adsorption.

The rate of colicin K adsorption to Escherichia coli, and consequent death of the bacteria, is progressively inhibited with increasing ionic strength of the medium. Comparison of the kinetics of colicin adsorption with the kinetics of colicin killing suggests that the lethal event provoked by colicin occurs soon after irreversible colicin adsorption. Factors, such as salts, which protect bacteria against the lethal action of colicin act by preventing colicin adsorption.     

Interaction of Colicins with Bacterial Cells IV. Immunity Breakdown Studied with Colicins Ia and Ib

Colicinogenic cells are immune to the lethal effect of the colicin which they produce. In the presence of very high concentrations of colicin, however, colicinogenic cells are no longer immune to the homologous colicin. This phenomenon, immunity breakdown, was studied with colicins Ia and Ib. The biochemical effects of colicin Ib on Escherichia coli were studied with a standard noncolicinogenic strain. At multiplicities of about 10 or higher, colicin Ib inhibited incorporation of leucine into protein and incorporation of (32)P-inorganic phosphate into deoxyribonucleic acid and ribonucleic acid by more than 95%. Under the same conditions, (32)P incorporation into phospholipid and nucleotide fractions was inhibited only partially (about 80 and 60%, respectively). Inhibition of (32)P incorporation into the terminal phosphorus of adenosine triphosphate was also considerably less than that of macromolecular synthesis (50 to 60%). (32)P incorporation into the nonnucleotide organic phosphate fraction was not inhibited. Respiration was not affected. Colicin Ia showed the same biochemical effects as colicin Ib. A mutant of an Ib-colicinogenic E. coli strain selected for resistance to low concentrations of colicin Ia was shown to be resistant to high concentrations of homologous colicin Ib, whereas the parent Ib-colicinogenic strain is sensitive to high concentrations of colicin Ib. This mutant lost its specific receptors for colicin Ib. Moreover, the biochemical effects of high concentrations of colicin Ib on Ib-colicinogenic cells during immunity breakdown were similar to the effects found in sensitive cells exposed to low concentrations of the same colicin. It is concluded that the killing of colicinogenic cells in the presence of high concentrations of homologous colicin is indeed caused by the homologous colicin molecules.     

Assembly of colicin genes from a few DNA fragments. Nucleotide sequence of colicin D

The nucleotide sequence of a 2.4 kb Dral-EcoRV fragment of pColD-CA23 DNA was determined. The segment of DNA contained the colicin D structural gene (cda) and the colicin D immunity gene (cdi). From the nucleotide sequence it was deduced that colicin D had a molecular weight of 74683D and that the immunity protein had a molecular weight of 10057D. The amino-terminal portion of colicin D was found to be 96% homologous with the same region of colicin B. Both colicins share the same cell-surface receptor, FepA, and require the TonB protein for uptake. A putative TonB box pentapeptide sequence was identified in the amino terminus of the colicin D protein sequence. Since colicin D inhibits protein synthesis, it was unexpected that no homology was found between the carboxy-terminal part of this colicin and that of the protein synthesis inhibiting colicin E3 and cloacin DF13. This could indicate that colicin D does not function in the same manner as the latter two bacteriocins. The observed homology with colicin B supports the domain structure concept of colicin organization. The structural organization of the colicin operon is discussed. The extensive amino-terminal homology between colicins D and B, and the strong carboxy-terminal homology between colicins B, A, and N suggest an evolutionary assembly of colicin genes from a few DNA fragments which encode the functional domains responsible for colicin activity and uptake.     

A molecular, genetic and immunological approach to the functioning of colicin A, a pore-forming protein

We have constructed, by recombinant DNA techniques, one hybrid protein, colicin A-beta-lactamase (P24), and two modified colicin As, one (P44) lacking a large central domain and the other (PX-345) with a different C-terminal region. The regulation of synthesis, the release into the medium and the properties of these proteins were studied. Only P44 was released into the medium. This suggests that both ends of the colicin A polypeptide chain might be required for colicin release. None of the three proteins was active on sensitive cells in an assay in vivo. However, P44 was able to form voltage-dependent channels in phospholipid planar bilayers. Its lack of activity in vivo is therefore probably caused by the inability to bind to the receptor in the outer membrane. PX-345 is a colicin in which the last 43 amino acids of colicin A have been replaced by 27 amino acids encoded by another reading frame in the same region of the colicin A structural gene; it was totally unable to form pores in planar bilayers at neutral pH but showed a very slight activity at acidic pH. These results confirm that the C-terminal domain of colicin A is involved in pore formation and indicate that at least the 43 C-terminal amino acid residues of this domain play a significant role in pore formation or pore function. Fifteen monoclonal antibodies directed against colicin A have been isolated by using conventional techniques. Five out of the 15 monoclonal antibodies could preferentially recognize wild-type colicin A. In addition, the altered forms of the colicin A polypeptide were used to map the epitopes of ten monoclonal antibodies reacting specifically with colicin A. Some of the antibodies did not bind to colicin A when it was pre-incubated at acidic pH suggesting that colicin A undergoes conformational change at about pH 4. The effects of monoclonal antibodies on activity in vivo of colicin A were investigated. The degree of inhibition observed was related to the location of the epitopes, with monoclonal antibodies reacting with the N terminus giving greater inhibition. The monoclonal antibodies directed against the C-terminal region promoted an apparent activation of colicin activity in vivo.     

The biology of colicin M

Abstract This communication summarizes our present knowledge of colicin M, an unusual member of the colicin group. The gene encoding colicin M, cma , has been sequenced and the protein isolated and purified. With a deduced molecular size of 29 453 Da, colicin M is the smallest of the known colicins. The polypeptide can be divided into functional domains for cell surface receptor binding, uptake into the cell, and killing activity. To kill, the colicin must enter from outside the cell. Colicin M blocks the biosynthesis of both peptidoglycan and O-antigen by inhibiting regeneration of the bactoprenyl-P carrier lipid. Autolysis occurs as a secondary effect following inhibition of peptidoglycan synthesis. Colicin M is the only colicin known to have such a mechanism of action. Immunity to this colicin is mediated by the cmi gene product, a protein of 13 890 Da. This cytoplasmic membrane protein confers immunity by binding to and thus neutralizing the colicin. Cmi shares properties with both immunity proteins of the pore-forming and the cytoplasmically active colicins. Genes for the colicin and immunity protein are found next to each other, but in opposite orientation, on pColM plasmids. The mechanism of colicin M release is not known.     

A colicin M derivative containing the lipoprotein signal sequence is secreted and renders the colicin M target accessible from inside the cells

Colicin M is only released in very low amounts by cells harbouring this plasmid encoded colicin, due to the lack of a release (lysis) protein. A fusion gene (lpp'cma) was constructed which determined two proteins: Lpp'-Cma composed of the signal sequence of the murein lipoprotein (Lpp) and colicin M (Cma), and unaltered colicin M. Cells expressing the fusion gene released 50% of the total colicin M into the culture medium, compared to 1% found in the medium of cells synthesizing only colicin M. The release resulted from partial cell lysis caused by colicin M since a colicin M tolerant strain remained unaffected. Lpp'-Cma thus mimics phenotypically the action of colicin release proteins but displays a different lysis mechanism. In strains defective in components of the colicin M uptake system, Lpp'-Cma caused lysis as effectively as in uptake proficient strains. Apparently, Lpp'-Cma renders the colicin M target site accessible from inside the cell which stands in contrast to the action of colicin M which is only bactericidal when provided from outside.Abbreviation bp base pairs     

The iron- and temperature-regulated cjrBC genes of Shigella and enteroinvasive Escherichia coli strains code for colicin Js uptake

A cosmid library of DNA from colicin Js-sensitive enteroinvasive Escherichia coli (EIEC) strain O164 was made in colicin Js-resistant strain E. coli VCS257, and colicin Js-sensitive clones were identified. Sensitivity to colicin Js was associated with the carriage of a three-gene operon upstream of and partially overlapping senB. The open reading frames were designated cjrABC (for colicin Js receptor), coding for proteins of 291, 258, and 753 amino acids, respectively. Tn7 insertions in any of them led to complete resistance to colicin Js. A near-consensus Fur box was found upstream of cjrA, suggesting regulation of the cjr operon by iron levels. CjrA protein was homologous to iron-regulated Pseudomonas aeruginosa protein PhuW, whose function is unknown; CjrB was homologous to the TonB protein from Pseudomonas putida; and CjrC was homologous to a putative outer membrane siderophore receptor from Campylobacter jejuni. Cloning experiments showed that the cjrB and cjrC genes are sufficient for colicin Js sensitivity. Uptake of colicin Js into sensitive bacteria was dependent on the ExbB protein but not on the E. coli K-12 TonB and TolA, -B, and -Q proteins. Sensitivity to colicin Js is positively regulated by temperature via the VirB protein and negatively controlled by the iron source through the Fur protein. Among EIEC strains, two types of colicin Js-sensitive phenotypes were identified that differed in sensitivity to colicin Js by 1 order of magnitude. The difference in sensitivity to colicin Js is not due to differences between the sequences of the CjrB and CjrC proteins.     

Colicins produced by the Escherichia fergusonii strains closely resemble colicins encoded by Escherichia coli

Plasmid DNA of six Escherichia fergusonii colicinogenic strains (three producers of colicin E1, two of Ib and one of Ia) was isolated and the colicin-encoding regions of the corresponding Col plasmids were sequenced. Two new variants of colicin E1, one of colicin Ib, and one of colicin Ia were identified as well as new variants of the colicin E1 and colicin Ib immunity proteins and the colicin E1 lysis polypeptide. The recombinant Escherichia coli producer harboring pColE1 from E. fergusonii strain EF36 (pColE1-EF36) was found to be only partially immune to E1 colicins produced by two other E. fergusonii strains suggesting that pColE1-EF36 may represent an ancestor ColE1 plasmid.