Localization of a Porphyromonas gingivalis 26-kilodalton heat-modifiable, hemin-regulated surface protein which translocates across the outer membrane.

We recently identified a 26-kDa hemin-repressible outer membrane protein (Omp26) expressed by the periodontal pathogen Porphyromonas gingivalis. We report the localization of Omp26, which may function as a component of a hemin transport system in P. gingivalis. Under hemin-deprived conditions, P. gingivalis expressed Omp26, which was then lost from the surface after a shift back into hemin-rich conditions. Experiments with 125I labeling of surface proteins to examine the kinetics of mobilization of Omp26 determined that it was rapidly (within less than 1 min) lost from the cell surface after transfer into a hemin-excess environment. When cells grown under conditions of hemin excess were treated with the iron chelator 2,2'-bipyridyl, Omp26 was detected on the cell surface after 60 min. One- and two-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis and immunoblot analyses using purified anti-Omp26 monospecific polyclonal immunoglobulin G antisera established that Omp26 was heat modifiable (39 kDa unheated) and consisted of a single protein species. Immunogold labeling of negatively stained and chemically fixed thin-section specimens indicated that Omp26 was associated with the cell surface and outer leaflet of the P. gingivalis outer membrane in hemin-deprived conditions but was buried in the deeper recesses of the outer membrane in hemin-excess conditions. Analysis of subcellular fractions of P. gingivalis grown either in hemin-excess or hemin-deprived conditions detected Omp26 only in the cell envelope fraction, not in the cytoplasmic fraction or culture supernatant. Limited proteolytic digestion of hemin-deprived P. gingivalis with trypsin and proteinase K verified the surface location of Omp26 as well as its susceptibility to proteolytic digestion. Heat shock treatment of hemin-excess-grown P. gingivalis also resulted in Omp26 translocation onto the outer membrane surface even in the presence of hemin. Furthermore, hemin repletion of heat-shocked, hemin-deprived P. gingivalis did not result in Omp26 translocation off the outer membrane surface, suggesting that thermal stress inactivates this transmembrane event. This newly described outer membrane protein appears to be associated primarily with the outer membrane, in which it is exported to the outer membrane surface for hemin binding and may be imported across the outer membrane for intracellular hemin transport.     

Colicins and bacterial membranes: structures and functions. I. Effects of colicins on the protein composition of the membranes of sensitive and tolerant Escherichia coli.

Treatment of Escherichia coli K12 C600 with colicin K or E1, but not E3, caused changes in the protein composition of the bacterial cytoplasmic membrane and an impairment of the membrane-associated ATP-linked transhydrogenase activity. The major compositional changes were loss and/or reduction in the levels of protein bands 4, 8, 9, 10, 13, and 18 with approximate molecular weights of 122,000, 81,000, 75,000, 73,000, 62,000, and 44,000, respectively. Colicin K or E1 treatment had no significant effect on the protein composition or the ATP-linked transhydrogenase activity of the cytoplasmic membranes of the isogenic tolerant strain E. coli K12 C600 TolII (A592). The cytoplasmic membranes of the untreated tolerant mutant were characteristically devoid of protein bands 4 and 13. It is proposed that protein bands 4 and/or 13 participate in colicin action by acting as receptors for colicins at the cytoplasmic membrane level. Some observations on the structural and functional heterogeneity of the cytoplasmic membrane preparations were made.     

Assembly of colicin A in the outer membrane of producing Escherichia coli cells requires both phospholipase A and one porin,but phospholipase A is sufficient for secretion

Three oligomeric forms of colicin A with apparent molecular masses of about 95 to 98 kDa were detected on sodium dodecyl sulfate (SDS)-polyacrylamide gels loaded with unheated samples from colicin A-producing cells of Escherichia coli. These heat-labile forms, called colicins Au, were visualized both on immunoblots probed with monoclonal antibodies against colicin A and by radiolabeling. Cell fractionation studies show that these forms of colicin A were localized in the outer membrane whether or not the producing cells contained the cal gene, which encodes the colicin A lysis protein responsible for colicin A release in the medium. Pulse-chase experiments indicated that their assembly into the outer membrane, as measured by their heat modifiable migration in SDS gels, was an efficient process. Colicins Au were produced in various null mutant strains, each devoid of one major outer membrane protein, except in a mutant devoid of both OmpC and OmpF porins. In cells devoid of outer membrane phospholipase A (OMPLA), colicin A was not expressed. Colicins Au were detected on immunoblots of induced cells probed with either polyclonal antibodies to OmpF or monoclonal antibodies to OMPLA, indicating that they were associated with both OmpF and OMPLA. Similar heat-labile forms were obtained with various colicin A derivatives, demonstrating that the C-terminal domain of colicin A, but not the hydrophobic hairpin present in this domain, was involved in their formation.     

Isolation and molecular and functional properties of the amino-terminal domain of colicin A

A plasmid was constructed which allowed easy and efficient production and purification of the NH2-terminal domain of colicin A. In only three steps, an homogenous 18-kDa polypeptide was obtained. The NH2- and COOH-terminal sequences of the protein were determined and showed that it corresponded to the NH2-terminal 171 amino acid residues of the 63-kDa colicin A. Although colicin A is a highly asymmetric protein, hydrodynamic studies indicated that the NH2-terminal domain (designated AT) has a globular structure. This fragment is not the receptor-binding domain of colicin A but is required for the transfer of colicin A across the outer membrane of sensitive cells. However, it has a low affinity for phospholipid films and this affinity is not pH-dependent, in contrast to that of colicin A.     

Biosynthesis and export of colicin A in Citrobacter freundii CA31

Synthesis of colicin A after induction with mitomycin C was studied. Specific inhibition of chromosomal protein synthesis occurred very shortly after mitomycin addition. There was no coordinate synthesis of colicin A (61000 Mr) and low-molecular-weight protein. Free and membrane-bound polysome fractions were isolated from cells induced with mitomycin C. Colicin A is synthesized in vitro in the free polysomes and not in the membrane-bound polysomes. Conditions are described which allow a practically specific labelling of colicin A in vivo. By using this system it was possible to demonstrate that colicin A is not transferred cotranslationally across the cytoplasmic membrane. In contrast, this protein leaves the cell where it was made long after synthesis. Preliminary evidence, suggesting that pauses occur during synthesis of colicin A, is presented.     

Brucella outer membrane protein Omp31 is a haemin-binding protein

The expression of haemin-binding proteins (HBPs) in the outer membrane is one of the strategies used by Gram-negative bacteria to obtain iron from the host. No HBP has been described in Brucella spp. We investigated whether Omp31, an outer membrane protein from Brucella with homology to HBPs from Bartonella quintana, is an HBP. Soluble recombinant Omp31 bound specifically to haemin-agarose, while an unrelated Brucella protein (SurA) did not. A similar experiment showed that native Omp31 found in the Brucella suis membrane fraction also binds to haemin-agarose. Recombinant Omp31 was electrophoresed by SDS-PAGE, transferred to nitrocellulose, and incubated with a haemin solution. Haemin bound to Omp31 and to albumin (positive control) but not to SurA. IPTG-induced recombinant Escherichia coli cells expressing Omp31 on their membrane bound significantly more haemin than uninduced cells or controls carrying a similar plasmid without the omp31 gene, showing that Omp31 also binds haemin in a bacterial membrane environment. Viable Brucella ovis cells bound haemin in solution, and this binding was markedly inhibited by preincubation of cells with antibodies to Omp31 and to an exposed prominent loop of the protein, thus showing that Omp31 functions as an HBP in brucellae. To test whether the expression of Omp31 is iron-regulated, B. suis was grown in trypticase-soy broth (TSB) and in iron-depleted TSB. The expression of Omp31, as assessed by Western blot, was significantly higher in bacteria grown under iron limitation. Overall, these results show that Omp31 from B. suis, B. melitensis and B. ovis is an HBP, whose expression seems to be induced by iron limitation.     

The state of energization of the membrane of Escherichia coli as affected by physiological conditions and colicin K.

The bacterial protein colicin K, when added to sensitive Escherichia coli in the presence of 3,3'-dihexyloxacarbocyanine, cuases a doubling in fluorescence of the probe. Glucose and oxygen cause a decreased fluorescence while anoxia and cyanide cause a rise in fluorescence. These results in conjunction with the work of other laboratories suggest that colicin K causes a depolarization of the transmembrane electrical potential. Fluorescence in the absence of colicin K was relatively independent of KCl, NaCl, and MgCl2 concentrations below 0.1 M. Although colicin K caused rapid efflux of the K+ analogue 86Rb+, the fluorescence rise was only partially blocked by 0.13 M KCl. The level of fluorescence caused by the action of colcin K was inversely proportional to the logarithm of the concentration of MgCl2 over the range of 2 muM to 4 mM. This suggests that a Nernst electrochemical potential for an anion can counteract a membrane depolarization caused by colcin. After colcin K action, the fluorescence of the carbocyanine could be further increased by anoxia or cyanide. The distribution of the weak base dimethyloxazolidinedione indicated that the pH in the interior of aerobic E. coli supplied with lactate was alkaline by 0.1 unit and unaffected by colicin. These results suggest that colicin K does not completely depolarize the membrane potential and does not interfere with the component of membrane energization generated by electron transport. Colicin K does not act as a cationophore. The partial depolarization of the membrane may account for the inhibition of active solute transport caused by colicin K.     

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

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

Purification and molecular properties of a new colicin.

The process of isolation and purification of a new colicin isolated from a Citrobacter strain is described. Escherichia coli sensitive cells are protected by vitamin B12 from the action of this bacteriocin; this suggests that it belongs to the E group of colicins. Therefore, we have called it colicin E4. It has a molecular weight of 56 000 and two molecular forms of isoelectric points 9.4 and 8.2 are separated in electrofocusing on polyacrylamide gels. It has a sedimentation coefficient of 3.4 S and the absorption coefficient A1(280%) nm is 6.23 cm(-1). Using an antibody raised against pure colicin E4, no cross-reaction was detected against colicins A, E1 or K. The physiological effect of colicin E4 on sensitive cells is very similar to that of colicins E1, K or I which disrupt the energized membrane state.     

Gene encoding a hybrid OmpF-PhoE pore protein in the outer membrane of Escherichia coli K12

Summary To study the structure-function relationship of outer membrane pore proteins of E. coli K12, a hybrid gene was constructed in which the DNA encoding amino acid residues 2–73 of the mature PhoE protein is replaced by the homologous part of the related ompF gene. The product of this gene is incorporated normally into the outer membrane. It was characterized with respect to its pore activity and its phage receptor and colicin receptor properties. It is concluded (i) that the preference of the PhoE protein pore for negatively charged solutes is partly determined by the amino terminal 73 amino acids, (ii) that part of the receptor site of PhoE protein for phage TC45 is located in this part of the protein, (iii) that colicin N uses OmpF protein as (part of) its receptor, (iv) that the specificity of OmpF protein as a colicin N receptor is completely located within the 80 amino terminal amino acid residues, whereas the specificity of this protein as a colicin A receptor is completely located within the 260 carboxy terminal amino acid residues, and (v) that the amino terminal 73 amino acid residues of PhoE protein span the membrane at least once.     

Mutant of Escherichia coli defective in response to colicin K and in active transport.

A mutant of Escherichia coli has been isolated that grows poorly on succinate and exhibits a markedly reduced sensitivity to colicin K. This mutant is also deficient in the respiration-linked transport of proline and thiomethyl-beta-D-galactoside but appears normal for the adenosine triphosphate-dependent transport of glutamine and arginine. A temperature-conditional revertant of the mutant grows on succinate and is sensitive to colicin K at 27 C, but fails to grow on succinate and is insensitive to colicin K at 42 C. Proline transport in the temperature-conditional revertant is reduced at 42 C when either glucose or succinate is used as energy source. Glutamine transport, on the other hand, is normal at 42 C with glucose as energy source, but is reduced with succinate, although not to the same extent as is proline transport. The lack of growth on succinate and the deficiencies in transport at 42 C are not due to a temperature-dependent lesion in either the electron transport chain or in Ca2+, Mg2+-activated adenosine triphosphatase activity. Membrane vesicles prepared from the temperature-conditional revertant are impaired in proline transport at both 27 and 42 C. These findings suggest the existence in the cytoplasmic membrane of E. coli cells of a component, presumably protein, that is required for colicin K action and that functions in respiration-linked and, to a lesser degree, in adenosine triphosphate-dependent active transport systems. This protein may serve as the primary target of colicin K action.     

Omp85(Tt) from Thermus thermophilus HB27: an ancestral type of the Omp85 protein family

Proteins belonging to the Omp85 family are involved in the assembly of beta-barrel outer membrane proteins or in the translocation of proteins across the outer membrane in bacteria, mitochondria, and chloroplasts. The cell envelope of the thermophilic bacterium Thermus thermophilus HB27 is multilayered, including an outer membrane that is not well characterized. Neither the precise lipid composition nor much about integral membrane proteins is known. The genome of HB27 encodes one Omp85-like protein, Omp85(Tt), representing an ancestral type of this family. We overexpressed Omp85(Tt) in T. thermophilus and purified it from the native outer membranes. In the presence of detergent, purified Omp85(Tt) existed mainly as a monomer, composed of two stable protease-resistant modules. Circular dichroism spectroscopy indicated predominantly beta-sheet secondary structure. Electron microscopy of negatively stained lipid-embedded Omp85(Tt) revealed ring-like structures with a central cavity of approximately 1.5 nm in diameter. Single-channel conductance recordings indicated that Omp85(Tt) forms ion channels with two different conducting states, characterized by conductances of approximately 0.4 nS and approximately 0.65 nS, respectively.     

Lipoprotein nature of the colicin A lysis protein: effect of amino acid substitutions at the site of modification and processing.

The colicin A lysis protein (Cal) is required for the release of colicin A to the medium by producing bacteria. This protein is produced in a precursor form that contains a cysteine at the cleavage site (-Leu-Ala-Ala-Cys). The precursor must be modified by the addition of lipid before it can be processed. The maturation is prevented by globomycin, an inhibitor of signal peptidase II. Using oligonucleotide-directed mutagenesis, the alanine and cystein residues in the -1 and +1 positions of the cleavage site were replaced by proline and threonine residues, respectively, in two different constructs. Both substitutions prevented the normal modification and cleavage of the protein. The marked activation of the outer membrane detergent-resistant phospholipase A observed with wild-type Cal was not observed with the Cal mutants. Both Cal mutants were also defective for the secretion of colicin A. In one mutant, the signal peptide appeared to be cleaved off by an alternative pathway involving signal peptidase I. Electron microscope studies with immunogold labeling of colicin A on cryosections of pldA and cal mutant cells indicated that the colicin remains in the cytoplasm and is not transferred to the periplasmic space. These results demonstrate that Cal must be modified and processed to activate the detergent-resistant phospholipase A and to promote release of colicin A.     

Phospholipase-A-independent damage caused by the colicin A lysis protein during its assembly into the inner and outer membranes of Escherichia coli

The requirement for the activation of phospholipase A by the colicin A lysis protein (Cal) in the efficient release of colicin A by Escherichia coli cells containing colicin A plasmids was studied. In particular, we wished to determine if this activation is the primary effect of Cal or whether it reflects more generalized damage to the envelope caused by the presence of large quantities of this small acylated protein. E. coli tolQ cells, which were shown to be leaky for periplasmic proteins, were transduced to pldA and then transformed with the recombinant colicin A plasmid pKA. Both the pldA and pldA+ strains released large quantities of colicin A following induction, indicating that in these cells phospholipase A activation is not required for colicin release. This release was, however, still dependent on a functioning Cal protein. The assembly and processing of Cal in situ in the cell envelope was studied by combining pulse-chase labelling with isopycnic sucrose density gradient centrifugation of the cell membranes. Precursor Cal and lipid-modified precursor Cal were found in the inner membrane at early times of chase, and gave rise to mature Cal which accumulated in both the inner and outer membrane after further chase. The signal peptide was also visible on these gradients, and its distribution too was restricted to the inner membrane. Gradient centrifugation of envelopes of cells which were overproducing Cal resulted in very poor separation of the membranes. The results of these studies provide evidence that the colicin A lysis protein causes phospholipase A-independent alterations in the integrity of the E. coli envelope.(ABSTRACT TRUNCATED AT 250 WORDS)     

Factors necessary for the export process of colicin E1 across cytoplasmic membrane of Escherichia coli

Factors necessary for the export process of colicin E1 across the cytoplasmic membrane of Escherichia coli were investigated. beta-Galactosidase activities from gene fusions between the colicin E1 and lacZ genes were recovered in the inner membrane fraction of E. coli when the region containing the internal signal-like sequence of colicin E1 [M. Yamada et al. (1982) Proc. Natl Acad. Sci. USA 79, 2827-2831] was present, but were found in the soluble fraction when the region was eliminated. The colicin E1 export was reduced upon insertion mutation in a gene that is located downstream from the colicin E1 gene in the same operon and responsible for mitomycin-C-induced killing of the host cell. A frame shift mutation of the colicin E1 plasmid was constructed to direct the protein which had lost the COOH-terminal 13 residues of original colicin E1 and was altered in 6 residues of the new COOH-terminal portion. The aberrant colicin E1 that was inducibly synthesized remained inside the cells. These results indicate that colicin E1 is exported with the aid of a product of the downstream gene and that the COOH-terminal portion is necessary for the export. The binding of colicin E1 to the cytoplasmic membrane through the internal signal-like sequence may be a step in the protein export process.     

High level expression of His-tagged colicin pore-forming domains and reflections on the sites for pore formation in the inner membrane

There exists ample evidence for the assumption that pore-forming colicins cannot exert their toxicity within the producing cell and that they must gain access to the outer face of the cytoplasmic membrane to achieve this. We wished to construct pET-vectors to produce pore-forming domains of colicin A and N with N-terminal hexa-histidine tags under the control of a T7 promoter. This was only possible when the correct immunity protein was also present. Hence it appears that this system exhibits the peculiarity that there is a toxicity associated with the over produced pore-forming domain. However, when the ratio of colicin to immunity protein is compared it is still clear that direct insertion into the cytoplasmic membrane does not occur and that membrane translocation of the colicin at limited sites may be occurring. This article reviews previous literature on the subject in terms of a model for limited sites of colicin action.     

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.     

Structure of colicin I receptor bound to the R-domain of colicin Ia: implications for protein import

Colicin Ia is a 69 kDa protein that kills susceptible Escherichia coli cells by binding to a specific receptor in the outer membrane, colicin I receptor (70 kDa), and subsequently translocating its channel forming domain across the periplasmic space, where it inserts into the inner membrane and forms a voltage-dependent ion channel. We determined crystal structures of colicin I receptor alone and in complex with the receptor binding domain of colicin Ia. The receptor undergoes large and unusual conformational changes upon colicin binding, opening at the cell surface and positioning the receptor binding domain of colicin Ia directly above it. We modelled the interaction with full-length colicin Ia to show that the channel forming domain is initially positioned 150 A above the cell surface. Functional data using full-length colicin Ia show that colicin I receptor is necessary for cell surface binding, and suggest that the receptor participates in translocation of colicin Ia across the outer membrane.     

Eicosapentaenoic acid facilitates the folding of an outer membrane protein of the psychrotrophic bacterium, Shewanella livingstonensis Ac10

Polyunsaturated fatty acids, such as eicosapentaenoic acid (EPA), are found in various cold-adapted microorganisms. We previously demonstrated that EPA-containing phospholipids (EPA-PLs) synthesized by the psychrotrophic bacterium Shewanella livingstonensis Ac10 support cell division, membrane biogenesis, and the production of membrane proteins at low temperatures. In this article, we demonstrate the effects of EPA-PLs on the folding and conformational transition of Omp74, a major outer membrane cold-inducible protein in this bacterium. Omp74 from an EPA-less mutant migrated differently from that of the parent strain on SDS-polyacrylamide gel, suggesting that EPA-PLs affect the conformation of Omp74 in vivo. To examine the effects of EPA-PLs on Omp74 protein folding, in vitro refolding of recombinant Omp74 was carried out with liposomes composed of 1,2-dipalmitoleoyl-sn-glycero-3-phosphoglycerol and 1,2-dipalmitoleoyl-sn-glycero-3-phosphoethanolamine (1:1molar ratio) with or without EPA-PLs as guest lipids. SDS-PAGE analysis of liposome-reconstituted Omp74 revealed more rapid folding in the presence of EPA-PLs. CD spectroscopy of Omp74 folding kinetics at 4°C showed that EPA-PLs accelerated β-sheet formation. These results suggest that EPA-PLs act as chemical chaperones, accelerating membrane insertion and secondary structure formation of Omp74 at low temperatures.