Purification and characterization of cloacin DF13 receptor from Enterobacter cloacae and its interaction with cloacin DF13 in vitro

Insight from TonB hybrid proteins into the mechanism of iron transport through the outer membrane

We created hybrid proteins to study the functions of TonB. We first fused the portion of Escherichia coli tonB that encodes the C-terminal 69 amino acids (amino acids 170 to 239) of TonB downstream from E. coli malE (MalE-TonB69C). Production of MalE-TonB69C in tonB(+) bacteria inhibited siderophore transport. After overexpression and purification of the fusion protein on an amylose column, we proteolytically released the TonB C terminus and characterized it. Fluorescence spectra positioned its sole tryptophan (W213) in a weakly polar site in the protein interior, shielded from quenchers. Affinity chromatography showed the binding of the TonB C-domain to other proteins: immobilized TonB-dependent (FepA and colicin B) and TonB-independent (FepADelta3-17, OmpA, and lysozyme) proteins adsorbed MalE-TonB69C, revealing a general affinity of the C terminus for other proteins. Additional constructions fused full-length TonB upstream or downstream of green fluorescent protein (GFP). TonB-GFP constructs had partial functionality but no fluorescence; GFP-TonB fusion proteins were functional and fluorescent. The activity of the latter constructs, which localized GFP in the cytoplasm and TonB in the cell envelope, indicate that the TonB N terminus remains in the inner membrane during its biological function. Finally, sequence analyses revealed homology in the TonB C terminus to E. coli YcfS, a proline-rich protein that contains the lysin (LysM) peptidoglycan-binding motif. LysM structural mimicry occurs in two positions of the dimeric TonB C-domain, and experiments confirmed that it physically binds to the murein sacculus. Together, these findings infer that the TonB N terminus remains associated with the inner membrane, while the downstream region bridges the cell envelope from the affinity of the C terminus for peptidoglycan. This architecture suggests a membrane surveillance model of action, in which TonB finds occupied receptor proteins by surveying the underside of peptidoglycan-associated outer membrane proteins.

Biphasic binding kinetics between FepA and its ligands

The Escherichia coli FepA protein is an energy- and TonB-dependent, ligand-binding porin that functions as a receptor for the siderophore ferric enterobactin and colicins B and D. We characterized the kinetic and thermodynamic parameters associated with the initial, energy-independent steps in ligand binding to FepA. In vivo experiments produced Kd values of 24, 185, and 560 nM for ferric enterobactin, colicin B, and colicin D, respectively. The siderophore and colicin B bound to FepA with a 1:1 stoichiometry, but colicin D bound to a maximum level that was 3-fold lower. Preincubation with ferric enterobactin prevented colicin B binding, and preincubation with colicin B prevented ferric enterobactin binding. Colicin B release from FepA was unexpectedly slow in vivo, about 10-fold slower than ferric enterobactin release. This slow dissociation of the colicin B.FepA complex facilitated the affinity purification of FepA and FepA mutants with colicin B-Sepharose. Analysis of a fluorescent FepA derivative showed that ferric enterobactin and colicin B adsorbed with biphasic kinetics, suggesting that both ligands bind in at least two distinct steps, an initial rapid stage and a subsequent slower step, that presumably establishes a transport-competent complex.

Identification and cloning of a fur regulatory gene in Yersinia pestis

Yersinia pestis is one of many microorganisms responding to environmental iron concentrations by regulating the synthesis of proteins and an iron transport system(s). In a number of bacteria, expression of iron uptake systems and other virulence determinants is controlled by the Fur regulatory protein. DNA hybridization analysis revealed that both pigmented and nonpigmented cells of Y. pestis possess a DNA locus homologous to the Escherichia coli fur gene. Introduction of a Fur-regulated beta-galactosidase reporter gene into Y. pestis KIM resulted in iron-responsive beta-galactosidase activity, indicating that Y. pestis KIM expresses a functional Fur regulatory protein. A cloned 1.9-kb ClaI fragment of Y. pestis chromosomal DNA hybridized specifically to the fur gene of E. coli. The coding region of the E. coli fur gene hybridized to a 1.1-kb region at one end of the cloned Y. pestis fragment. The failure of this clone to complement an E. coli fur mutant suggests that the 1.9-kb clone does not contain a functional promoter. Subcloning of this fragment into an inducible expression vector restored Fur regulation in an E. coli fur mutant. In addition, a larger 4.8-kb Y. pestis clone containing the putative promoter region complemented the Fur- phenotype. These results suggest that Y. pestis possesses a functional Fur regulatory protein capable of interacting with the E. coli Fur system. In Y. pestis Fur may regulate the expression of iron transport systems and other virulence factors in response to iron limitation in the environment. Possible candidates for Fur regulation in Y. pestis include genes involved in ferric iron transport as well as hemin, heme/hemopexin, heme/albumin, ferritin, hemoglobin, and hemoglobin/haptoglobin utilization.

New aerobactin-mediated iron uptake system in a septicemia-causing strain of Enterobacter cloacae

Unlike the great majority of the aerobactin-producing enteric bacteria documented in the literature, Enterobacter cloacae EK33, isolated from a case of human neonatal meningitis, did not show any homology at the DNA level with the prototype aerobactin system encoded by the ColV-K30 plasmid. However, both the nuclear magnetic resonance spectrum and fast-atom bombardment mass spectrometry of the siderophore purified from EK33 confirmed its identity with aerobactin. Bioassay screening of a gene library of total DNA of EK33 led to the isolation of several aerobactin-positive clones. Under conditions of iron limitation, these clones expressed in Escherichia coli a protein of 72 kilodaltons that reacted with antiserum raised against the pColV-K30 74-kilodalton aerobactin receptor, while the original E. cloacae strain synthesized an 85-kilodalton protein which also cross-reacted with the antiserum. Restriction endonuclease analysis of the cloned DNA confirmed the structural differences between the two aerobactin genetic systems.

Iron and virulence in the family Enterobacteriaceae

The ability of bacterial pathogens to acquire iron in the host is an essential component of the disease process. Pathogenic Enterobacteriaceae spp. may either scavenge host iron sources such as heme or induce high-affinity iron-transport systems to remove iron from host proteins. The ease with which iron is acquired from the host will be at least partially determined by the iron status of the host at the time of infection. In response to infection, mammalian hosts reduce serum iron levels and withhold iron from the invading microorganisms. Thus the competition for iron is an active process which influences the outcome of a host-bacterial interaction.

Plasmid-determined cloacin DF13-susceptibility in Enterobacter cloacae and Klebsiella edwardsii; identification of the cloacin DF13/aerobactin outer membrane receptor proteins

Both Enterobacter cloacae H478 and Klebsiella 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 from Escherichia coli (Co1V-K30) revealed that the corresponding outer membrane receptor proteins of Ent. cloacae H478 and K. edwardsii S15 had apparent mol wts of 85 000 and 76 000, respectively. E. coli transconjugants harbouring either the plasmid from Ent. cloacae H478 or K. edwardsii S15 expressed a cloacin DF13/aerobactin outer membrane receptor protein with a mol wt of 74 000. The receptor protein encoded by the Ent. cloacae and K. edwardsii plasmids were immunologically more related to each other than to the pCo1V-K30-encoded receptor protein.

Colicin E3 and its immunity genes

A DNA segment of plasmid ColE3-CA38 was cloned into pBR328 and its nucleotide sequence was determined. This segment contains the putative promoter-operator region, the structural genes of protein A (gene A) and protein B (gene B) of colicin E3, and a part of gene H. Just behind the promoter region, there is an inverted repeat structure of two 'SOS boxes', the specific binding site of the lexA protein. This suggests that the expression of colicin E3 is regulated directly by the lexA protein. Genes A and B face the same direction, with an intergenic space of nine nucleotides between them. ColE3-CA38 and ColE1-K30 are homologous in their promoter-operator regions, but hardly any homology was found in their structural genes. On the other hand, ColE3-CA38 is fairly homologous to CloDF13 throughout the regions sequenced, with some exceptions including putative receptor-binding regions. By deletion mapping of the immunity gene and recloning of gene B, it was shown genetically that protein B itself is the actual immunity substance of colicin E3. It was also found that the expression of E3 immunity partially depends on the recA function. Thus, we propose two modes of expression of E3 immunity: in the uninduced state, only a slight amount of protein B is produced constitutively to protect the cell from being attacked by the exogenous colicin; and in the SOS-induced state, a large amount of protein B is produced to protect the protein synthesis system of the host cell from ribosome inactivation by endogenously produced colicin E3.

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.

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.

Properties and proteolysis of ferric enterobactin outer membrane receptor in Escherichia coli K12

A protein with a relative subunit molecular weight of 81000 (81K) has been isolated in virtually pure form from the outer membrane of low iron grown cells of Escherichia coli K12. The 81K protein, which is part of the receptor complex for translocation of the siderophore ferric enterobactin, displays activity in vitro for binding both ferric enterobactin and colicin B. The dissociation constant for the 81K-ferric enterobactin compound at 4 degrees C in 2% Triton-0.1 M Tris, pH 7, was determined to be 10 nM. The N-terminal amino acid was identified as phenylalanine, and the amino acid composition was shown to be similar to that published for the ferric aerobactin-cloacin receptor of Enterobacter cloacae. A plasmid-bearing strain of E. coli was employed to confirm that degradation of 81K to a slightly smaller, inactive form (81K) is performed by a second outer membrane component, protein a. The endoproteolytic action of protein a was verified by the finding of alanine as the N-terminal residue of 81K. A survey of enteric species suggests that the 81K-protein a interaction is confined to the K12 strain of E. coli.

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.

The cloacin receptor of ColV-bearing Escherichia coli is part of the Fe3+-aerobactin transport system

Escherichia coli strains which contain the Fe3+-aerobactin transport system specified by the ColV plasmid became deficient in aerobactin-dependent iron transport when they were converted to cloacin-resistant derivatives. An outer membrane protein with a molecular mass of 74,000 daltons was overproduced under iron-limiting growth conditions and was absent in cloacin-resistant mutants. Fe3+-aerobactin protected cells against cloacin. These results suggest that the cloacin receptor protein, controlled by the colV plasmid, also participates in Fe3+-aerobactin transport.

Siderophore production by Enterobacter cloacae and a common receptor protein for the uptake of aerobactin and cloacin DF13

Iron-starved cultures of Enterobacter cloacae produced two siderophores, identified as enterochelin and aerobactin. The aerobactin was excreted in larger amounts than was enterochelin, and it was synthesized preferentially in the late logarithmic and stationary growth phases under iron-deficient conditions. Enterochelin was synthesized by cultures in the logarithmic phase of growth and preferentially in medium with 1 microM ferric chloride. Both siderophores appeared to be excreted immediately after their synthesis, since no intracellular aerobactin or enterochelin could be detected. The killing activity of the bacteriocin cloacin DF13 was inhibited by aerobactin. It was shown that aerobactin and cloacin DF13 bound to the same receptor sites located in the outer membrane. The synthesis of these receptor sites was induced by iron limitation. We conclude that the receptor for the uptake of aerobactin also functions as receptor for cloacin DF13.

Cytotoxicity of pyocin S2 to tumor and normal cells and its interaction with cell surfaces

Cytotoxicity and adsorption of pyocin S2 produced by Pseudomonas aeruginosa M47 (PAO 3047) to virally transformed mammalian cells, human malignant cells and normal cells in the same species were studied. Pyocin S2 inhibited the growth of not only tumor cells (XC, TSV-5, mKS-A TU-7, HeLa-S3 and AS-II cells) but also normal cells (BALB/3T3 and BHK 21 cells). The inhibitory effects on the cells increased with an increase of pyocin S2 activity. On the other hand, there were some tumor cells (155-4 T2 and HCG-27 cells) and normal cells (normal rat kidney and human embryo lung cells) which were resistant to pyocin S2. The pyocin S2 activity was neutralized by the cell membrane preparations from pyocin S2-sensitive cells, but not by those from pyocin-resistant cells. This neutralization ability was inhibited by high concentrations of D-galactose, N-acetyl-D-galactosamine and N-acetyl neuraminic acid and completely destroyed by periodate and neuraminidase. The inhibition by the saccharides was concentration dependent. These results suggest that the toxicity of pyocin S2 in the cell membrane and further, that the carbohydrate moiety, especially of D-galactose, N-acetyl-D-galactosamine and sialic acid, may play an important role as an initial binding site for pyocin S2.

Characterization of binding sites for a bacteriocin produced by Mycobacterium smegmatis

A bacteriocin from Mycobacterium smegmatis ATCC 14468 which adsorbed to the cell wall-enriched fraction and the crude lipopolysaccharide preparation from Mycobacterium diernhoferi ATCC 19340 was inhibited by D-glucose and alpha-linked glucosylated derivatives.

Mutational loss of sensitivity to mutacin GS-5 in Streptococcus pyogenes: characterization of a mutant deficient in receptor protein

By means of a stepwise selection procedure, mutants capable of growing in the presence of relatively high multiplicities of a bacteriocin from Streptococcus mutans GS-5 were obtained from a sensitivie strain of Streptococcus pyogenes. Mutacin-neutralizing activity of cell extracts containing receptor protein was examined in one variant that adsorbed 1/6 the amount of bacteriocin adsorbed by the parent strain under conditions equivalent to "saturation." Partially purified receptor protein from both parent and mutant cells neutralized an equivalent amount of bacteriocin on a weight-to-weight basis, indicating that in vitro there was no significant difference in affinity for the mutacin between the respective receptor fractions. Cell extracts from the mutant, solubilized by treatment with trichloroacetic acid, neither neutralized mutacin activity nor interfered with receptor protein-mediated mutacin neutralization in vitro. The mutant phenotype may thus represent a cell surface density of receptor protein which results in the adsorption of sublethal amounts of mutacin. The mutant retained its sensitivity to other mutacins, e.g., those produced by strains LM-7 and BHT of S. mutans, and did not differ from wild-type cells with respect to either detergent sensitivity (sodium lauryl sulfate and Triton X-100) or to inhibition by penicillin, rifampin, bacitracin, erythromycin, and tetracycline.

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.