Alterations in the carboxy-termianl half of cloacin destabilize the protein and prevent its export by Escherichia coli

Several overlapping carboxy-terminal and internal deletions were constructed in the cloacin structural gene. The expression, the binding of the cloacin DF13 immunity protein and the release into the culture medium of the mutant cloacin polypeptides were studied by immunoblotting and ELISAs. Minor alterations at the carboxy-terminal end of the cloacin did not affect protein expression, stability or release to a large extent, but larger carboxy-terminal deletions strongly destabilized the protein and no release was observed. The removal of a particular region within the carboxy-terminal portion of cloacin strongly destabilized the polypeptide and made it a target for proteolytic degradation. Binding of immunity protein did not affect stability and release of the mutant polypeptides. By using immunoelectron microscopy, the polypeptides that were not exported were located in the cytoplasm of producing cells. Large aggregates of these mutant polypeptides were not observed in the cytoplasm: the polypeptides were present in a soluble form.     

Uptake of cloacin DF13 by susceptible cells: removal of immunity protein and fragmentation of cloacin molecules.

Monoclonal antibodies (MAb) directed against different epitopes on the equimolar complex of cloacin and immunity protein (cloacin DF13) were isolated, characterized, and used to study the uptake of cloacin DF13 by susceptible cells. Four MAbs recognized the amino-terminal part, one MAb recognized the central part, and three MAbs recognized the carboxyl-terminal part of the cloacin molecule. Three MAbs reacted with the immunity protein. Five MAbs inhibited the lethal action of cloacin DF13, but none of the MAbs inhibited the binding of cloacin DF13 to its purified outer membrane receptor protein or the in vitro inactivation of ribosomes. Binding of cloacin DF13 to susceptible cells cultured in broth resulted in a specific, time-dependent dissociation of the complex and a fragmentation of the cloacin molecules. Increasing amounts of immunity protein were detected in the culture medium from about 20 min after the addition of cloacin DF13. Cloacin was fragmented into two carboxyl-terminal fragments with relative molecular masses of 50,000 and 10,000. The larger fragment was detected 5 min after the binding of the bacteriocin complex to the cells. The smaller fragment was detected after 10 min. Both fragments were associated with the cells and could not be detected in the culture supernatant fraction. Cells grown in brain heart infusion were much less susceptible to cloacin DF13 than cells grown in broth, although they possessed a similar number of outer membrane receptor molecules. This decreased susceptibility correlated with a decreased translocation, dissociation, and fragmentation of cloacin DF13.     

Protein H encoded by plasmid Clo DF13 involved in lysis of the bacterial host

Summary We studied the expression of gene H, located between 9.3% and 11% on the Clo DF13 genome, as well as the functions of the gene product. We found that treatment of bacterial cells with mitomycin-C results in the induced synthesis of three Clo DF13 specified proteins namely cloacin DF13, immunity protein and protein H. Evidence was obtained that the genes encoding these proteins form one, mitomycin-C induceable, operon; the promoter at 32% in front of the cloacin gene is essential for the induced expression. Furthermore we could demonstrate that protein H is involved in the lethal effect of mitomycin-C treatment of bacteriocinogenic cells. The data in this paper show that a high concentration of protein H in cells, due either to an induced expression of gene H (mitomycin-C induction) or to a gene dosage effect (Clo DF13 cop1 Ts copy control mutant), results in the lysis of bacterial cells. The implication of these data are discussed.     

pCloDF13-encoded bacteriocin release proteins with shortened carboxyl-terminal segments are lipid modified and processed and function in release of cloacin DF13 and apparent host cell lysis.

By oligonucleotide-directed mutagenesis, stop codon mutations were introduced at various sites in the pCloDF13-derived bacteriocin release protein (BRP) structural gene. The expression, lipid modification (incorporation of [3H]palmitate), and processing (in the presence and absence of globomycin) of the various carboxyl-terminal shortened BRPs were analyzed by a special electrophoresis system and immunoblotting with an antiserum raised against a synthetic BRP peptide, and their functioning with respect to release of cloacin DF13, lethality, and apparent host cell lysis were studied in Sup-, supF, and supP strains of Escherichia coli. All mutant BRPs were stably expressed, lipid modified, and processed by signal peptidase II, albeit with different efficiencies. The BRP signal peptide appeared to be extremely stable and accumulated in induced cells. Full induction of the mutant BRPs, including the shortest containing only 4 amino acid residues of the mature polypeptide, resulted in phospholipase A-dependent and Mg2+-suppressible apparent cell lysis. The extent of this lysis varied with the mutant BRP used. Induction of all mutant BRPs also prevented colony formation, which appeared to be phospholipase A independent. One shortened BRP, containing 20 amino acid residues of the mature polypeptide, was still able to bring about the release of cloacin DF13. The results indicated that the 8-amino-acid carboxyl-terminal segment of the BRP contains a strong antigenic determinant and that a small segment between amino acid residues 17 and 21, located in the carboxyl-terminal half of the BRP, is important for release of cloacin DF13. Either the stable signal peptide or the acylated amino-terminal BRP fragments (or both) are involved in host cell lysis and lethality.     

Protein H encoded by plasmid CloDF13 is involved in excretion of cloacin DF13.

Excretion of cloacin DF13 was studied in Escherichia coli cells harboring different CloDF13 insertion and deletion mutant plasmids. Insertions of a transposon at position 9.8 or 11.5% of the CloDF13 plasmid blocked the expression of gene H and strongly reduced the specific excretion of cloacin DF13 into the culture medium, but had no effect on the production of cloacin DF13. Insertions in or deletions of regions of the CloDF13 DNA upstream the cloacin operon did not affect the excretion or production of the bacteriocin. Introduction of a CloDF13 plasmid that encodes for the gene H product in cells harboring a CloDF13 plasmid with an insertion in gene H stimulated the excretion of cloacin DF13 significantly in mitomycin C-induced and in noninduced cultures. Cloacin DF13 in cloacinogenic cells that did not produce the gene H protein was found to be about 90% located in the cytoplasm. In cells that did produce the gene H product, about 30% of the cloacin DF13 molecules were found in the cytoplasm, about 18% were found in the periplasm, about 2% were in the membranes, and about 50% were located in the culture supernatant. Cyclic AMP stimulated the production but not the excretion of cloacin DF13 in cells cultivated in the presence of glucose.     

The use of mutants in the study of structure-function relationships in cloacin DF13.

A bacteriocin from cells with a mutant Clo DF13 plasmid (cloacin clp03 . immunity protein complex) and a bacteriocin from cells containing the recombinant plasmic Clo DF13 :: Tn901 (cloacin pJN82) have been isolated. Both bacteriocins like wild-type cloacin DF13, are still able to inhibit in vitro protein synthesis, but their in vivo killing activity is absent. Comparison of some physicochemical characteristics of the cloacin clp03 . immunity protein complex and wild-type cloacin complex showed no significant differences. From a comparison of the binding capacity to specific receptors on sensitive cells, the translocation through the cell wall, and the interaction with cytoplasmic membranes, it could be concluded that the cloacin clp03 complex is hampered in its translocation from the outer membrane receptor site to the cytoplasmic membrane, resulting in the observed lack in killing activity. Cloacin pJN82 is shortened at the C-terminal of the molecule by approximately ten amino acid residues. Together with its loss of in vivo killing activity it has lost its capacity to bind immunity protein. Since the immunity protein probably not only provides cloacin-producing cells with "immunity" but is also involved in the translocation of the bacteriocin to the interior of sensitive cells, the absence of this protein is probably the reason for the lack of killing activity of cloacin pJN82. The implications of these findings for the topography of the cloacin molecule as suggested by de Graaf et al. (de Graaf, F.K., Stukart, M.J., Boogerd, F.C. and Metselaar, K. (1978) Biochemistry, in press) are discussed.     

Changes in protein synthesis on mitomycin C induction of wild-type and mutant CloDF13 plasmids.

Mitomycin C treatment of Escherichia coli K-12 cells containing the nonconjugative plasmid CloDF13 resulted in inhibition of host chromosome protein synthesis and a high rate of synthesis of two CloDF13-specified proteins whose molecular weights correspond to cloacin and immunity protein. Five molecules of immunity protein were synthesized for each cloacin DF13 molecule. Mitomycin C-treated cells containing a copy mutant of CloDF13 made three to four times as much of each protein as cells containing wild-type CloDF13. CloDF13 plasmids that contained the transposon Tn1 were isolated. Two did not induce after mitomycin C treatment, failing both to inhibit host cell synthesis and to produce the two new proteins. In minicells, they showed reduced CloDF13-specified protein synthesis and produced three Tn1-specified proteins.     

The use of mutants in the study of structure-function relationships in cloacin DF13

A bacteriocin from cells with a mutant Clo DF13 plasmid (cloacin clp03· immunity protein complex) and a bacteriocin from cells containing the recombinant plasmic Clo DF13 :: Tn901 (cloacin pJN82) have been isolated. Both bacteriocins like wild-type cloacin DF13, are still able to inhibit in vitro protein synthesis, but their in vivo killing activity is absent. Comparison of some physicochemical characteristics of the cloacin clp03 · immunity protein complex and wild-type cloacin complex showed no significant differences.From a comparison of the binding capacity to specific receptors on sensitive cells, the translocation through the cell wall, and the interaction with cytoplasmic membranes, it could be concluded that the cloacin clp03 complex is hampered in its translocation from the outer membrane receptor site to the cytoplasmic membrane, resulting in the observed lack in killing activity.Cloacin pJN82 is shortened at the C-terminal of the molecule by approximately ten amino acid residues. Together with its loss of in vivo killing activity it has lost its capacity to bind immunity protein. Since the immunity protein probably not only provides cloacin-producing cells with “immunity” but is also involved in the translocation of the bacteriocin to the interior of sensitive cells, the absence of this protein is probably the reason for the lack of killing activity of cloacin pJN82.The implications of these findings for the topography of the cloacin molecule as suggested by de Graaf et al. (de Graaf, F.K., Stukart, M.J., Boogerd, F.C. and Metselaar, K. (1978) Biochemistry, in press) are discussed.     

Molecular structure of the immunity gene and immunity protein of the bacteriocinogenic plasmid Clo DF13.

The nucleotide sequence of the Clo DF13 DNA region comprising the immunity gene has been determined. We also elucidated the aminoacid sequence of the 40 N-terminal and 7 C-terminal aminoacids of the purified immunity protein. From analysis of the data obtained we were able to locate the immunity gene between 11.7 and 14.5% on the Clo DF13 map, and to determine the complete aminoacid sequence of the immunity protein. It was observed that the Clo DF13 immunity gene encodes an 85 aminoacid protein and is transcribed in the same direction as the cloacin gene. These experimental data support our model, presented elsewhere, which implicates that the cloacin and immunity genes of Clo DF13 are coordinately transcribed from the cloacin promoter. We also present DNA sequence data indicating that an extra ribosome binding site precedes the immunity gene on the polycistronic mRNA. This ribosome binding site might explain the fact that in cloacinogenic cells more immunity protein than cloacin is synthesized. The comparison of the complete aminoacid sequence of the Clo DF13 immunity protein, with the aminoacid sequence data of the purified, comparable Col E3 immunity protein revealed that both proteins have extensive homologies in primary and secondary structure, although they are exchangeable only to a low extent in vivo and in vitro. It was also observed that a lysine residue was modified in immunity protein isolated from excreted bacteriocin complexes.     

Production and excretion of cloacin DF13 by Escherichia coli harboring plasmid CloDF13.

The production and the mechanism of excretion of cloacin DF13 were investigated in noninduced and mitomycin C-induced cell cultures. A mitomycin C concentration was selected which did not cause lysis of cloacinogenic cells, but at the same time induced a maximal production of cloacin DF13. Native cloacin DF13, possessing killing activity, was first released into the cytoplasm. Shortly thereafter, the bacteriocin was transported through the cytoplasmic membrane and accumulated in the periplasm. Finally, cloacin DF13 was excreted into the culture medium. A small amount of cloacin DF13 remained associated with the cell surface. Producing cells did not become permeable for the cytoplasmic enzyme beta-galactosidase. Apparently the cloacin DF13 leaves the producing cells by an excretion process which is not similar to the mechanism proposed for bacterial secretory proteins. The processes of excretion by producing cells and of uptake by susceptible cells were also not identical because mutant cloacin DF13, which was not transported through the outer membrane into susceptible cells, was excreted like the wild-type cloacin DF13. The composition of the culture medium greatly affected production of cloacin DF13. The presence of sugars known to cause catabolite repression not only inhibited the production but also strongly reduced the excretion of cloacin DF13 into the culture medium.     

Uncoupling of synthesis and release of cloacin DF13 and its immunity protein by Escherichia coli

Summary The synthesis of the bacteriocin cloacin DF13 and its release into the culture medium were genetically uncoupled by subcloning the gene encoding the bacteriocin release protein (BRP) from pCloDF13. The gene was cloned under the control of the IPTG-inducible lpp-lac promoter-operator system on the expression vector pINIIIA1, giving pJL1. A 4 kb DNA fragment of pJL1, containing the tandem lpp-lac promoter, the BRP gene and lacI (BRP cassette), was cloned into the pCloDF13 derivative plasmid pJN67, which encodes cloacin DF13 but not the release protein. Furthermore, the pCloDF13 immunity protein gene was subcloned downstream of the temperature-inducible P _L promoter of the expression vector pPLc236, together with the BRP cassette. Growth, induction and excretion experiments with Escherichia coli cells harbouring the constructed plasmids revealed that: i) the BRP is the only pCloDF13-derived gene product responsible for the observed growth inhibition and apparent lysis of strongly induced cells. This growth inhibition and lysis can be prevented by Mg²⁺ ions added to the culture medium, and involves induction of phospholipase A activity. (ii) The expression of the BRP gene can be regulated by varying the IPTG concentration. (iii) A separately controlled and moderate induced BRP synthesis can be used to bring about the release of large amounts of cloacin DF13 under conditions that allow a strong induction of the bacteriocin and which do not result in lysis of cells. (iiii) Preliminary results indicated that the BRP can stimulate the release of immunity protein in the absence of cloacin or cloacin fragments.     

Molecular characterisation of the colicin E2 operon and identification of its products

Summary The DNA sequence of the entire colicin E2 operon was determined. The operon comprises the colicin activity gene, ceaB, the colicin immunity gene, ceiB, and the lysis gene, celB, which is essential for colicin release from producing cells. A potential LexA binding site is located immediately upstream from ceaB, and a rho-independent terminator structure is located immediately downstream from celB. A comparison of the predicted amino acid sequences of colicin E2 and cloacin DF13 revealed extensive stretches of homology. These colicins have different modes of action and recognise different cell surface receptors; the two major regions of heterology at the carboxy terminus, and in the carboxy-terminal end of the central region probably correspond to the catalytic and receptor-recognition domains, respectively. Sequence homologies between colicins E2, A and E1 were less striking, and the colicin E2 immunity protein was not found to share extensive homology with the colicin E3 or cloacin DF13 immunity proteins. The lysis proteins of the ColE2, ColE1 and CloDF13 plasmids are almost identical except in the aminoterminal regions, which themselves have overall similarity with lipoprotein signal peptides. Processing of the ColE2 prolysis protein to the mature form was prevented by globomycin, a specific inhibitor of the lipoprotein signal peptidase. The mature ColE2 lysis protein was located in the cell envelope. The results are discussed in terms of the functional organisation of the colicin operons and the colicin proteins, and the way in which colicins are released from producing cells.     

Purification and characterization of a complex between cloacin and its immunity protein isolated from Enterobacter cloacae (Clo DF13). Dissociation and reconstitution of the complex.

Cell of Enterobacter cloacae (Clo DF13) produce a bacteriocin which is characterized by its very effective killing activity against sensitive bacteria. Purification and characterization of the excreted bacteriocin has revealed that this bacteriocin consists of an equimolar complex of two plasmid-specific gene products: the cloacin and its inhibitor the immunity protein. Dissociation of the complex by treatment with sodium dodecylsulfate induces the endonucleolytic activity of the cloacin but strongly reduces the killing activity. The purified complex possesses no activity in vitro. Both cloacin and immunity protein isolated from the complex were functionally identical to cloacin and immunity protein purified from the bacteriocinogenic cells by other methods. Reconstitution of the complex results in a partial restoration of killing activity.     

Mutants of the Clo DF13 plasmid inEscherichia coli with a decreased bacteriocinogenic activity

Summary Three Clo DF13 mutant plasmids (designated asclp03, clp05 andclp21) that show a decreased cloacin activity were isolated. The decreased cloacin activity was not due to a reduced number of Clo DF13 copies per cell. The cloacins produced by theclp03 and theclp21 mutant plasmids have a strongly decreased killing activityin vivo in comparison with the wild type cloacin and the cloacin of theclp05 mutant plasmid. Furthermore no lacunae could be observed fromclp03 orclp21 harbouring strains, while strains harbouring theclp05 plasmid showed a 50–100 times decreased frequency of lacunae. In addition theclp05 mutant showed a decreased rate of RNA synthesis inclp05 harbouringEscherichia coli minicells. No complementation between the three mutant plasmids was observed. We suggest that theclp03 andclp21 mutations are located in the gene coding for the cloacin. Since the cloacin produced by theclp05 mutant plasmid has retained all the known wild type cloacin activities, the reduced inhibition zone in the stab test is probably caused by a mutation affecting the expression of the cloacin gene. The nature of this mutation is discussed.     

Sensitivity of Escherichia coli to cloacin DF13 involves the major outer membrane protein OmpF

Fourteen spontaneous cloacin DF13-insensitive mutants of an Escherichia coli strain expressing the aerobactin-cloacin DF13 receptor protein IutA were isolated. The mutants fell into three classes on the basis of outer membrane profiles analyzed by electrophoresis in denaturing polyacrylamide gels. The most frequent class lacked the IutA protein and was unable to bind cloacin DF13 or aerobactin. A second class of mutants had lost protein species corresponding in size to the porin proteins OmpF and OmpC. To determine which porin was required for the bactericidal activity of cloacin DF13, defined strains with mutations at the ompB (ompR envZ) locus were transformed with a recombinant plasmid carrying the iutA gene and screened for cloacin DF13 sensitivity. OmpF- strains, whether OmpC+ or OmpC-, were insensitive to cloacin DF13, indicating involvement of the OmpF protein in cloacin DF13 killing. An OmpC- OmpF+ strain, on the other hand, was more sensitive than the wild-type parent strain, probably because of compensatory overexpression of OmpF. The third class of cloacin DF13-insensitive mutant had lost an outer membrane protein of approximately 31 kDa. The nature and function of this protein are not yet known, but it is not the protease OmpT. Mutants of classes 2 and 3 bound cloacin DF13 and aerobactin as effectively as the cloacin DF13-sensitive parental strain, indicating that they remained IutA+. We propose that these mutants (more accurately described as cloacin DF13 tolerant) are defective in translocation of the active portion of cloacin DF13 across the bacterial membranes.     

In vitro binding of cloacin DF13 to its purified outer membrane receptor protein and effect of peptidoglycan on bacteriocin-receptor interaction.

The in vitro neutralization of the killing activity of cloacin DF13 by incubation with its purified receptor protein was shown to be the result of the formation of a direct and specific equimolar complex of both proteins. The binding of cloacin DF13 to its receptor protein did not result in a fragmentation of the cloacin molecules nor in the expulsion of immunity protein from the bacteriocin. The rate of the cloacin DF13-receptor interaction in vitro was found to be enhanced significantly in the presence of peptidoglycan, but lysozyme-treated peptidoglycan did not affect this interaction. Incubation of the cloacin DF13 as well as its receptor protein with peptidoglycan showed that the receptor protein but not the cloacin DF13 was able to bind to the peptidoglycan.     

Molecular structure and immunity specificity of colicin E6, an evolutionary intermediate between E-group colicins and cloacin DF13.

The primary structure of a 3.1-kilobase E6 or E3 segment carrying colicin and related genes was determined. Plasmid ColE6-CT14 showed striking homology to ColE3-CA38 throughout this segment, including homology to the secondary immunity gene, immE8, downstream of the E6 or E3 immunity gene. The ColE3-CA38 and ColE6-CT14 sequences, however, contained an exceptional hot spot region encoding both the colicin-active domain (RNase region) and the immunity protein, reflecting their different immunity specificities. On the other hand, some chimeric plasmids were constructed through homologous recombination between colicin E3 and cloacin DF13 operons. The resulting plasmids were deduced to produce chimeric colicins with a colicin E3-type N-terminal part, a cloacin DF13-type C-terminal-active domain, and the DF13 immunity protein. The killing spectra of the chimeric colicins and the immunities of the plasmids were identical to those of colicin E6 and ColE6-CT14, respectively, showing that the colicin E6 immunity specificity is completely equivalent to that of cloacin DF13. Nevertheless, colicin E6 has been found to show a sequence diversity from cloacin DF13 almost to the same extent as that from colicin E3 in their RNase and immunity regions, indicating that only a small number of amino acids defines the immunity specificity for discrimination between colicins E3 and E6 (or cloacin DF13).     

Functioning of a hybrid BRP-β-lactamase protein in the release of cloacin DF13 and lysis of Escherichia coli cells

The gene encoding a hybrid BRP-Bla protein consisting of the pCloDF13 encoded BRP signal sequence, 25 of the 28 amino acid residues of the mature bacteriocin release protein (BRP) and the mature portion of beta-lactamase (Bla) was subcloned in the expression vector pEB112. A similar construct was made using a mutant gene encoding a BRP-Bla protein in which the cysteine residue at the +1 position was changed into a glycine residue. The expression, processing, functioning and subcellular localization of the 'wild-type' and mutant hybrid protein at high-level expression conditions were studied. The 'wild-type' BRP-Bla protein was mainly found in the outer membranes and possessed all the activities of the BRP itself; the protein was able to bring about the release of cloacin DF13 and caused apparent cell-lysis after high-level synthesis. The mutant hybrid protein was predominantly located in the inner membranes, was inactive in the release of cloacin DF13, but caused apparent cell-lysis only after strong induction.     

Effects of divalent cations and of phospholipase A activity on excretion of cloacin DF13 and lysis of host cells

Induction of cloacin DF13 synthesis in Escherichia coli harbouring plasmid CloDF13 results in the release of cloacin DF13, inhibition of growth and ultimately in lysis of the host cells. Expression of the pCloDF13-encoded protein H is essential for both the release of cloacin DF13 and the lysis of the cells. The divalent cations Mg2+ and Ca2+ interfered with the mitomycin C-induced protein H-dependent lysis, but hardly affected the release of cloacin DF13. Essentially all of the bacteriocin was released from the cells before a detectable degradation of the peptidoglycan occurred, independent of the presence of mitomycin C. Experiments with phospholipase A mutants revealed that activation of detergent-resistant phospholipase A was essential for the export of cloacin DF13 across the outer membrane and the lysis of induced cells. Transport of cloacin DF13 across the cytoplasmic membrane was mainly dependent on protein H. A revised model for the excretion of cloacin DF13 is presented.