Cloning and expression of the cloacin DF13/aerobactin receptor of Escherichia coli (ColV-K30)

A DNA fragment derived from the ColV-K30 plasmid and coding for both sensitivity to cloacin DF13 and Fe3+-aerobactin uptake was cloned into pBR322. The cloned fragment coded for two polypeptides with molecular masses of 74,000 (the cloacin DF13/aerobactin receptor protein) and 50,000 daltons, respectively. When grown with sufficient iron, cells harboring pFS8 (with this fragment) possessed about 10 times as many receptor protein molecules as compared with cells of Escherichia coli (ColV-K30). The synthesis of the receptor protein specified by pFS8, however, was independent of the availability of iron, in contrast to strains harboring the intact ColV-K30 plasmid. Aerobactin was taken up but not synthesized by cells harboring pFS8. No growth occurred when iron-starved cultures of these cells were incubated with Fe3+-aerobactin, suggesting that expression of other ColV-K30-encoded genes is necessary to remove the iron from the Fe3+-aerobactin complex.     

Chromosomal genes for ColV plasmid-determined iron(III)-aerobactin transport in Escherichia coli.

Four chromosomal genes, tonA (fhuA), fhuB, tonB, and exbB, were required for the transport of iron(III)-aerobactin specified by the plasmids ColV-K311, ColV-K229, ColV-K328, and ColV-K30. These genes also determine the transport system in Escherichia coli for the iron ionophore ferrichrome. Aerobactin and ferrichrome are both iron ligands of the hydroxamate type, but they are of different structure. The ColV plasmids determine an outer membrane protein that serves as a receptor for cloacin. Cloacin-resistant mutants were devoid of iron(III)-aerobactin transport but were unimpaired in ferrichrome transport. We conclude that for iron(III)-aerobactin transport two outer membrane proteins, the TonA and the cloacin receptor protein, have to interact functionally or structurally or both.     

Regulation of the ColV plasmid-determined iron (III)-aerobactin transport system in Escherichia coli.

Regulation by iron was studied in Escherichia coli strains whose iron supply was entirely dependent on the iron(III)-aerobactin system determined by the ColV plasmid. By the insertion of phage Mu (Ap lac) into the ColV plasmid, mutants were selected that could no longer grow in iron-limited media. The inserted Mu (Ap lac) strongly reduced the amount of aerobactin and he cloacin receptor protein formed by the cells. Their production was no longer subject to regulation by iron. The Mu (Ap lac) insertion apparently led to a polar effect on the expression of the presumably closely linked genes that control the synthesis of aerobactin and the cloacin receptor protein. The expression of the beta-galactosidase gene on the inserted phage genome came under the control of the iron state of the cells. Under iron-limited growth conditions, the amount of beta-galactosidase synthesized was, depending on the strain studied, 6 to 30 times higher than under iron-sufficient growth conditions. In fur mutants with an impaired iron regulation of ll iron supply systems studied so far, high amounts of beta-galactosidase were synthesized independent of the cells' iron supply. The results demonstrate an iron-controlled promoter on the ColV plasmid which is subject to regulation by the chromosomal fur gene.     

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.     

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.     

Novel aerobactin receptor in Klebsiella pneumoniae

Several Klebsiella pneumoniae strains which produced enterochelin but not aerobactin were nevertheless sensitive to cloacin DF13. In contrast, a strain of serotype K1:O1 which produced both siderophores was cloacin-resistant. Loss by mutation of the O1 but not K1 antigen rendered this strain cloacin-sensitive, indicating that the O1 antigen prevented access of cloacin to the cloacin/aerobactin receptor. Unlike the K1:O1 strain, the aerobactin-negative strains failed to hybridize in a colony blot assay with an aerobactin receptor gene probe prepared from pColV-K30. However, antisera raised against the 74 kDa pColV-K30 aerobactin receptor cross-reacted with a 76 kDa outer-membrane protein in each K. pneumoniae strain. In addition to the 76 kDa protein, the K1:O1 strain also produced a strongly cross-reacting 74 kDa protein. To determine whether these aerobactin-negative strains could use aerobactin, mutants unable to synthesize siderophores were isolated. Aerobactin promoted the growth of these mutants in iron-deficient media. The evidence presented suggests that some K. pneumoniae strains produce an aerobactin iron-uptake system without apparent production of aerobactin and which is probably based on a 76 kDa receptor, the gene for which does not hybridize with aerobactin receptor gene encoded on pColV-K30.     

Subcloning of the cloacin DF13/aerobactin receptor protein and identification of a pColV-K30-determined polypeptide involved in ferric-aerobactin uptake.

A plasmid containing a pColV-K30 fragment that encoded only for the cloacin DF13/aerobactin receptor protein was constructed. Escherichia coli cells harboring this plasmid were sensitive to cloacin DF13 but were unable to take up ferric-aerobactin. Another pColV-K30-determined polypeptide (molecular weight, 50,000), localized in the membrane fraction, was essential for the uptake of ferric-aerobactin.     

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.     

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.     

Role of tol genes in cloacin DF13 susceptibility of Escherichia coli K-12 strains expressing the cloacin DF13-aerobactin receptor IutA.

IutA is the outer membrane protein receptor for ferric aerobactin and the bacteriocin cloacin DF13. Although the same receptor is shared, ferric aerobactin transport across the outer membrane in Escherichia coli is TonB dependent, whereas cloacin DF13 transport is not. We have recently observed that tolQ is required for cloacin DF13 susceptibility (J.A. Thomas and M.A. Valvano, FEMS Microbiol. Lett. 91:107-112, 1992). In this study, we demonstrate that the genes tolQ, tolR, and tolA, but not tolB, tolC, and ompF, are required for the internalization of cloacin DF13 and they are not involved in the transport of ferric aerobactin.     

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.     

The complete nucleotide sequence of the bacteriocinogenic plasmid CloDF13

The complete nucleotide sequence of the bacteriocinogenic plasmid CloDF13 has been determined. The plasmid consists of 9957 base pairs (molecular weight 6.64 X 10(6] with a GC content of 54.4%. At this moment 16 identified biological functions can be assigned to the primary structure of the CloDF13 DNA. The functions include those of eight protein encoding genes, two untranslated RNA species, and six DNA sites. We discuss these functions in relation to the structure of CloDF13 DNA. For convenience we have divided the CloDF13 genome into five defined regions: region I (origin of vegetative replication, priming and control of replication, type I incompatibility), region II (cloacin DF13, cloacin immunity, cloacin release, cloacin operon control), region III (double-stranded DNA-phage interaction, type II incompatibility, multimer resolution), region IV (inhibition of male specific RNA phages and transfer of Flac), and region V (mobility proteins, basis of mobility).     

tolQ is required for cloacin DF13 susceptibility in Escherichia coli expressing the aerobactin/cloacin DF13 receptor IutA

We investigated the role of the tolQ gene in the import of cloacin DF13 across the outer membrane of Escherichia coli strains expressing the IutA receptor. The IutA outer-membrane protein is the receptor for the siderophore ferric aerobactin and also binds cloacin DF13, a bacteriocin produced by strains of Enterobacter aerogenes. In this report we present evidence that tolQ is required for the internalization of cloacin DF13 upon binding to IutA but it is not involved in the transport of ferric aerobactin.     

Plasmid-determined cloacin DF13-susceptibility inEnterobacter cloacae andKlebsiella edwardsii; identification of the cloacin DF13/aerobactin outer membrane receptor proteins

BothEnterobacter cloacae H478 andKlebsiella edwardsii S15 were shown to harbour a relatively large conjugative plasmid that coded for cloacin DF13-susceptibility and the production and uptake of a hydroxamate iron chelator, most probably aerobactin. Protein-blotting experiments with antiserum raised against the purified cloacin DF13/aerobactin receptor protein fromEscherichia coli (Co1V-K30) revealed that the corresponding outer membrane receptor proteins ofEnt. cloacae H478 andK. edwardsii S15 had apparent mol wts of 85 000 and 76000, respectively.E. coli transconjugants harbouring either the plasmid fromEnt. cloacae H478 orK. edwardsii S15 expressed a cloacin DF13/aerobactin outer membrane receptor protein with a mol wt of 74000. The receptor protein encoded by theEnt. cloacae andK. edwardsii plasmids were immunologically more related to each other than to the pCo1V-K30-encoded receptor protein.     

Molecular structure and function of the bacteriocin gene and bacteriocin protein of plasmid Clo DF13.

In this paper we present the complete nucleotide sequence of the bacteriocin gene of plasmid Clo DF13. According to the predicted aminoacid sequence the bacteriocin, cloacin DF13, consists of 561 aminoacids and has a molecular weight of 59,293 D. To obtain insight into the structure and function of specific parts of the cloacin molecule, we constructed a hydration profile and we predicted the secondary structure of the protein. According to our predictions, the N-terminus of cloacin DF13 (corresponding to the first 150-180 aminoacids) is relatively hydrophobic and is rich in glycine residues. The data obtained support previous findings that the N-terminal part of cloacin DF13 is involved in translocation of this protein across the cell membrane. The C-terminal part of the cloacin protein is rich in positively charged aminoacids; this might reflect the RNase activity located within this domain. A comparison of the bacteriocin genes and corresponding proteins of Clo DF13 and Col E1 did not reveal any homology at the level of either the nucleotide or the aminoacid sequence. The codon usage of both genes, however, exhibits striking similarities. The sequence data obtained during this study enabled us to present the nucleotide sequence of the entire cloacin operon. The structure of this operon and the regulation of expression of the genes, located within this operon, is discussed.     

Expression of the pCloDF13 encoded bacteriocin release protein or its stable signal peptide causes early effects on protein biosynthesis and Mg2+ transport

The effect of the pCloDF13 encoded bacteriocin release protein (BRP) onEscherichia coli cell lethality was studied. Induction of the BRP resulted in a strong inhibition of the incorporation of radioactive labeled amino acids and affected the transport of Mg²⁺ ions. Similar effects were obtained when the BRP stable signal peptide was expressed as a separate entity. Kinetic studies revealed that these effects occurred prior to quasi-lysis and release of cloacin DF13. The results indicated that the BRP induced cell lethality is caused by early effects on protein synthesis and Mg²⁺ transport, due to the accumulation of stable BRP signal peptides in the cytoplasmic membrane.     

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.     

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.     

Metabolic depletion inhibits the uptake of nontransferrin-bound iron by K562 cells

The effect of metabolic inhibitors on nontransferrin bound iron transport by K562 cells was investigated. Incubation with 1 microM rotenone, 10 microM antimycin, or 0.5 mM 2,4-dinitrophenol effectively reduced ATP levels by approximately 50%. Both the rate and extent of Fe+3 uptake were impaired in ATP-depleted cells, which display a reduced Vmax for uptake. K562 cell ferrireductase activity was also lowered by metabolic inhibitors, suggesting that the apparent energy requirements for transport reside in the reduction of Fe+3 to Fe+2. However, ATP depletion was found to inhibit the rate and extent of Fe+2 uptake as well. Thus, the transbilayer passage of Fe+2 and/or Fe+3 appears to be an energy-requiring process. These features possibly reflect properties of the transport mechanism associated with a recently identified K562 cell transport protein, called SFT for "Stimulator of Fe Transport," since exogenous expression of its activity is also affected by ATP depletion.