Escherichia coli outer membrane protein K is a porin.

Protein K is an outer membrane protein found in pathogenic encapsulated strains of Escherichia coli. We present evidence here that protein K is structurally and functionally related to the E. coli K-12 porin proteins (OmpF, OmpC, and PhoE). Protein K was found to cross-react with antibody to OmpF protein and to share 8 out of 17 peptides in common with the OmpF protein. Strains that are OmpC porin- and OmpF porin- and contain protein K as their major outer membrane protein have increased rates of uptake of nutrients and a faster growth rate relative to the parental porin- strain. The protein K-containing strains are at least 1,000-fold more sensitive to colicins E2 and E3 than is the porin -deficient strain. These data suggest that protein K is a functional porin in E. coli. The porin function of protein K was also demonstrated in vitro, using black lipid membranes. Protein K increased the conductance in these membranes in discrete, uniform steps characteristic of channels with a size of about 2 nS.     

Outer Membrane Protein PhoE Takes the Place of OmpC/OmpF in Maintenance of the Surface Structure of Escherichia coli Cells

OmpC and OmpF, outer membrane porin proteins, are important in the maintenance of the cell surface structure of Escherichia coli cells [T. Nogami and S. Mizushima, J. Bacteriol., 156, 402 (1983)]. Mutants lacking both proteins are unstable and frequently revert or mutate to strains which either have regained one or both of the proteins or constitutively produce PhoE, another porin protein. In the present work, the structural importance of PhoE was studied in relation to OmpC. and OmpF. The strain devoid of both OmpC and OmpF was highly susceptible to Tris-HCl buffer at a concentration of 120 mm in terms of viability and cell structure. This strain was also susceptible to osmotic shock. In contrast, the strain possessing PhoE in place of OmpC/OmpF was as stable as the strain possessing OmpC/OmpF against these treatments. PhoE, like OmpC and OmpF, was assembled into a hexagonal lattice with lipopolysaccharide that covered the peptidoglycan sacculus. These results suggest that PhoE can take the place of OmpC/OmpF in the maintenance of the cell surface structure. The importance of porins in general in the maintenance of the cell structure is discussed.     

Isolation and characterization of mutations altering expression of the major outer membrane porin proteins using the local anaesthetic procaine

Mutations at several different chromosomal locations affect expression of the major outer membrane porin proteins (OmpF and OmpC) of Escherichia coli K12. Those that map at 21 and 47 minutes define the structural genes for OmpF and OmpC, respectively. A third locus, ompB, is defined by mutations that map at 74 minutes. The ompB locus contains two genes whose products regulate the relative amounts of ompF and ompC expression. One of these genes, ompR, encodes a positive regulatory protein that interacts at the ompF and ompC promoters. Mutations in ompR exhibit an OmpF- OmpC- or an OmpF+ OmpC- phenotype. The product of the second gene, envZ, affects regulation of the porin proteins in an unknown manner. Previously isolated mutations in envZ exhibit an OmpF- OmpC+ phenotype and also have pleiotropic effects on other exported proteins. In the presence of local anaesthetics such as procaine, wild-type strains exhibit properties similar to these envZ mutants, i.e. OmpF- OmpC+. Using ompF-lac fusion strains, we have exploited this procaine effect to isolate two new classes of envZ mutations. One of these classes exhibits an OmpF+ OmpC- phenotype. The other allows expression of both OmpF and OmpC but alters the relative amounts found under various growth conditions. Like previously isolated envZ mutations, these also affect regulation of other exported proteins, such as lambda receptor. These results permit a more detailed analysis of the omp regulon and they may shed light on one of the mechanisms by which local anaesthetics exert their effect.     

Characterization of monoclonal antibodies to the outer membrane protein (OmpD) of Salmonella typhimurium.

A panel of monoclonal antibodies, seven against the trimeric and seven against the monomeric forms to outer membrane protein D (OmpD) of Salmonella typhimurium were produced. The specificities of these monoclonal antibodies for the porin proteins of S. typhimurium and their cross-reactions with Salmonella porins OmpC and OmpF were determined by Western immunoblotting and enzyme-linked immunosorbent assay. We observed that OmpD shared more epitopes and had greater structural similarity with OmpC than with OmpF.     

Porin channels in Escherichia coli: studies with liposomes reconstituted from purified proteins.

Rates of diffusion of uncharged and charged solute molecules through porin channels were determined by using liposomes reconstituted from egg phosphatidylcholine and purified Escherichia coli porins OmpF (protein 1a), OmpC (protein 1b), and PhoE (protein E). All three porin proteins appeared to produce channels of similar size, although the OmpF channel appeared to be 7 to 9% larger than the OmpC and PhoE channels in an equivalent radius. Hydrophobicity of the solute retarded the penetration through all three channels in a similar manner. The presence of one negative charge on the solute resulted in about a threefold reduction in penetration rates through OmpF and OmpC channels, whereas it produced two- to tenfold acceleration of diffusion through the PhoE channel. The addition of the second negatively charged group to the solutes decreased the diffusion rates through OmpF and OmpC channels further, whereas diffusion through the PhoE channel was not affected much. These results suggest that PhoE specializes in the uptake of negatively charged solutes. At the present level of resolution, no sign of true solute specificity was found in OmpF and OmpC channels; peptides, for example, diffused through both of these channels at rates expected from their molecular size, hydrophobicity, and charge. However, the OmpF porin channel allowed influx of more solute molecules per unit time than did the equivalent weight of the OmpC porin when the flux was driven by a concentration gradient of the same size. This apparent difference in "efficiency" became more pronounced with larger solutes, and it is likely to be the consequence of the difference in the sizes of OmpF and OmpC channels.     

A comparative analysis of the spatial structure of nonspecific porins from <Emphasis Type="Italic">Yersinia ruckeri</Emphasis> using optical spectroscopy and molecular modeling

The spatial organization of outer-membrane porins is studied by optical spectroscopy and molecular modeling. It was found that the OmpF and OmpC porins from Yеrsiniа ruckeri are β-structured membrane proteins typical of the pore-forming proteins of other Gram-negative bacteria. The spatial structures of monomers and trimers of the OmpC and OmpF porins from Y. ruckeri are simulated using methods of structural bioinformatics. It was found that the structural stability of the more thermostable OmpF trimer is sustained by a greater number of hydrogen bonds and hydrophobic interactions. The main differences of the spatial structures of the test porins are observed in the structure of their outer loops. There are three tryptophan residues in the molecules of the OmpC and OmpF porins of Y. ruckeri. It is demonstrated by moleculardynamics methods that after thermal denaturation the solvent accessibility of the Trp212 residue in OmpF porin increased by two times, while the solvent accessibility of a Trp184 residue in OmpC porin was not increased. It is hypothesized that the red-shifted tryptophan fluorescence spectrum of OmpF porin during thermal denaturation is due to the behavior of the Trp212 residue.     

Copper sensitivity in an envelope mutant of Escherichia coli and its suppression by ColV, I-K94

A phage K3-resistant isolate from Escherichia coli P678-54 was devoid of both the OmpA and OmpC proteins but had high levels of the OmpF protein. Associated with these changes, the strain showed increased sensitivity to inhibition by detergents and greatly increased sensitivity to Cu²⁺. Introduction of the ColV, I-K94 plasmid into this mutant produced a derivative with markedly increased resistance to Cu²⁺ ions but unchanged detergent sensitivity. Analysis of membranes showed that the ColV, I-K94⁺ derivative had essentially no OmpF protein in its outer membrane. A ca 36 K outer membrane protein was present which resembled the OmpC protein in size and failure to dissociate in SDS at low temperature. It was distinct from the OmpC protein, however, in failing to allow either tetracycline uptake or the adsorption of T4-type phages. The possible significance of OmpF porin derepression (and its reversal by ColV, I-K94) for enterobacterial survival in aquatic situations is discussed.     

OmpC-like porin from outer membrane of Yersinia enterocolitica: Molecular structure and functional activity

OmpC-like porin was isolated from the outer membrane (OM) of Yersinia enterocolitica cultured at 37°C (the “warm” variant) and its physicochemical and functional properties were studied. The amino acid sequence of OmpC porin was established, and the primary structure and transmembrane topology of this protein were analyzed in comparison with the OmpF porin isolated from Y. enterocolitica cultured at 6°C (the “cold” variant). Both porins of Y. enterocolitica had a high homology degree (65%) between themselves and with OmpC and OmpF porins from OM of Escherichia coli (58 and 76% homology, respectively). The secondary structure of OmpC and OmpF porins from OM of Y. enterocolitica consists of 16 β-strands connected by short “periplasmic” and longer “extracellular” loops with disordered structure, according to the topological model developed for porins of E. coli. The molecular structures of OmpC and OmpF porins of Y. enterocolitica have significant differences in the structure of the “extracellular” loops and in the position of one of three tryptophan residues. Using the bilayer lipid membrane (BLM) technique, pores formed by OmpC porin of Y. enterocolitica were shown to differ in electrophysiological characteristics from channels of OmpF protein of this microorganism. The isolated OmpC porin reconstructed into BLM displayed functional plasticity similarly to OmpF protein and nonspecific porins of other enterobacteria. The conductivity level of the channels formed by this protein in the BLM was regulated by value of the applied potential.     

Site-directed mutagenesis studies to probe the role of specific residues in the external loop (L3) of OmpF and OmpC porins in susceptibility of Serratia marcescens to antibiotics

Serratia marcescens is a nosocomial bacterium with natural resistance to a broad spectrum of antibiotics, making treatment challenging. One factor contributing to this natural antibiotic resistance is reduced outer membrane permeability, controlled in part by OmpF and OmpC porin proteins. To investigate the direct role of these porins in the diffusion of antibiotics across the outer membrane, we have created an ompF-ompC porin-deficient strain of S. marcescens. A considerable similarity between the S. marcescens porins and those from other members of Enterobacteriaceae was detected by sequence alignment, with the exception of a change in a conserved region of the third external loop (L3) of the S. marcescens OmpC protein. Serratia marcescens OmpC has aspartic acid instead of glycine in position 112, methionine instead of aspartic acid in position 114, and glutamine in position 124, while in S. marcescens OmpF this is a glycine at position 124. To investigate the role of amino acid positions 112, 114, and 124 and how the observed changes within OmpC porin may play a part in pore permeability, 2 OmpC sites were altered in the Enterobacteriaceae consensus (D112G and M114D) through site-directed mutagenesis. Also, Q124G in OmpC, G124Q in OmpF, and double mutants of these amino acid residues were constructed. Antibiotic accumulation assays and minimal inhibitory concentrations of the strains harboring the mutated porins were performed, while liposome swelling experiments were performed on purified porins. Our results demonstrate that the amino acid at position 114 is not responsible for either antibiotic size or ionic selection, the amino acid at position 112 is responsible for size selection only, and position 124 is involved in both size and ionic selection.     

Crystal structure of osmoporin OmpC from E. coli at 2.0 A

Porins form transmembrane pores in the outer membrane of Gram-negative bacteria with matrix porin OmpF and osmoporin OmpC from Escherichia coli being differentially expressed depending on environmental conditions. The three-dimensional structure of OmpC has been determined to 2.0 A resolution by X-ray crystallography. As expected from the high sequence similarity, OmpC adopts the OmpF-like 16-stranded hollow beta-barrel fold with three beta-barrels associated to form a tight trimer. Unlike in OmpF, the extracellular loops form a continuous wall at the perimeter of the vestibule common to the three pores, due to a 14-residues insertion in loop L4. The pore constriction and the periplasmic outlet are very similar to OmpF with 74% of the pore lining residues being conserved. Overall, only few ionizable residues are exchanged at the pore lining. The OmpC structure suggests that not pore size, but electrostatic pore potential and particular atomic details of the pore linings are the critical parameters that physiologically distinguish OmpC from OmpF.     

Structural relatedness of enteric bacterial porins assessed with monoclonal antibodies to Salmonella typhimurium OmpD and OmpC.

The immunochemistry and structure of enteric bacterial porins are critical to the understanding of the immune response to bacterial infection. We raised 41 monoclonal antibodies (MAbs) to Salmonella typhimurium OmpD and OmpC porin trimers and monomers. Enzyme-linked immunosorbent assays, immunoprecipitations, and/or Western immunoblot techniques indicated that 39 MAbs (11 anti-trimer and 28 anti-monomer) in the panel are porin specific and one binds to the lipopolysaccharide; the specificity of the remaining MAb probably lies in the porin-lipopolysaccharide complex. Among the porin-specific MAbs, 10 bound cell-surface-exposed epitopes, one reacted with a periplasmic epitope, and the remaining 28 recognized determinants that are buried within the outer membrane bilayer. Many of the MAbs reacting with surface-exposed epitopes were highly specific, recognizing only the homologous porin trimers; this suggests that the cell-surface-exposed regions of porins tends to be quite different among S. typhimurium OmpF, OmpC, and OmpD porins. Immunological cross-reaction showed that S. typhimurium OmpD was very closely related to Escherichia coli NmpC and to the Lc porin of bacteriophage PA-2. Immunologically, E. coli OmpG and protein K also appear to belong to the family of closely related porins including E. coli OmpF, OmpC, PhoE, and NmpC and S. typhimurium OmpF, OmpC, and OmpD. It appears, however, that S. typhimurium "PhoE" is not closely related to this group. Finally, about one-third of the MAbs that presumably recognize buried epitopes reacted with porin domains that are widely conserved in 13 species of the family Enterobacteriaceae, but apparently not in the seven nonenterobacterial species tested. These data are evaluated in relation to host immune response to infection by gram-negative bacteria.     

Crystal structure and functional characterization of OmpK36, the osmoporin of Klebsiella pneumoniae

BACKGROUND: Porins are channel-forming membrane proteins that confer solute permeability to the outer membrane of Gram-negative bacteria. In Escherichia coli, major nonspecific porins are matrix porin (OmpF) and osmoporin (OmpC), which show high sequence homology. In response to high osmolarity of the medium, OmpC is expressed at the expense of OmpF porin. Here, we study osmoporin of the pathogenic Klebsiella pneumoniae (OmpK36), which shares 87% sequence identity with E. coliOmpC in an attempt to establish why osmoporin is best suited to function at high osmotic pressure. RESULTS: The crystal structure of OmpK36 has been determined to a resolution of 3.2 A by molecular replacement with the model of OmpF. The structure of OmpK36 closely resembles that of the search model. The homotrimeric structure is composed of three hollow 16-stranded antiparallel beta barrels, each delimiting a separate pore. Most insertions and deletions with respect to OmpF are found in the loops that protrude towards the cell exterior. A characteristic ten-residue insertion in loop 4 contributes to the subunit interface. At the pore constriction, the replacement of an alanine by a tyrosine residue does not alter the pore profile of OmpK36 in comparison with OmpF because of the different course of the mainchain. Functionally, as characterized in lipid bilayers and liposomes, OmpK36 resembles OmpC with decreased conductance and increased cation selectivity in comparison with OmpF. CONCLUSIONS: The osmoporin structure suggests that not an altered pore size but an increase in charge density is the basis for the distinct physico-chemical properties of this porin that are relevant for its preferential expression at high osmotic strength.     

New pore protein produced in cells lysogenic for Escherichia coli phage HK253hrk

Outer membrane pore protein OmpC was identified as the receptor for the temperate Escherichia coli phage HK253hrk. The part of OmpC protein recognized by the phage was identified by using hybrid proteins in which parts of OmpC protein are replaced by the corresponding parts of the related PhoE protein. In contrast to other OmpC-specific phages, HK253hrk recognizes a part of OmpC within the C-terminal 50 amino acids of the protein. E. coli strains lysogenic for HK253hrk produce reduced amounts of OmpC protein, and produce a new pore protein instead. Expression of this new protein was temperature-dependent, i.e. low at 30 degrees C. The functioning of this new pore protein was characterized both in vivo by studying the uptake of beta-lactam antibodies and in vitro after reconstitution of the protein in black lipid films. Its effective pore size was larger than that of the OmpF pores of E. coli B. The new porin appears to be cation-selective. A comparison with the selectivity of the known OmpC and OmpF pores of E. coli showed that the new pore has a higher selectivity than OmpF but is less selective than OmpC. The new pore protein appears to function in E. coli K12 lysogens as the receptor for the phages HK187, HK189 and HK332.     

Expression of outer membrane proteins in Escherichia coli growing at acid pH

It is generally accepted for Escherichia coli that (i) the level of OmpC increases with increased osmolarity when cells are growing in neutral and alkaline media, whereas the level of OmpF decreases at high osmolarity, and that (ii) the two-component system composed of OmpR (regulator) and EnvZ (sensor) regulates porin expression. In this study, we found that OmpC was expressed at low osmolarity in medium of pH below 6 and that the expression was repressed when medium osmolarity was increased. In contrast, the expression of ompF at acidic pH was essentially the same as that at alkaline pH. Neither OmpC nor OmpF was detectable in an ompR mutant at both acid and alkaline pH values. However, OmpC and OmpF were well expressed at acid pH in a mutant envZ strain, and their expression was regulated by medium osmolarity. Thus, it appears that E. coli has a different mechanism for porin expression at acid pH. A mutant deficient in ompR grew slower than its parent strain in low-osmolarity medium at acid pH (below 5.5). The same growth diminution was observed when ompC and ompF were deleted, suggesting that both OmpF and OmpC are required for optimal growth under hypoosmosis at acid pH.     

High Salt Concentrations Increase Permeability through OmpC Channels of Escherichia coli

OmpF and OmpC porin channels are responsible for the passage of small hydrophilic solutes across the outer membrane of Escherichia coli. Although these channels are two of the most extensively studied porin channels, what had yet remained elusive was the reason why OmpC shows markedly lower permeability than OmpF, despite having little difference in its channel size. The OmpC channel, however, is known to contain a larger number of ionizable residues than the OmpF channel. In this study, we examined the channel property of OmpF and OmpC using the intact cell of E. coli, and we found that the permeability of several β-lactams and lactose through OmpC became increased to the level comparable with OmpF with up to 0.3 m salt that may increase the Debye-Hückel shielding or with 2% ethanol or 0.3 m urea that may perturb the short range ordering of water molecules. Replacing 10 pore-lining residues that show different ionization behavior between OmpC and OmpF led to substantial conversion of channel property with respect to their permeability and response to external salt concentration. We thus propose that the overall configuration of ionizable residues in the channel that may orient water molecules and the electrostatic profile of the channel play a decisive role in defining the channel property of the OmpC porin rather than its channel size.     

EnvZ functions through OmpR to control porin gene expression in Escherichia coli K-12.

The regulatory proteins OmpR and EnvZ are both required to activate expression of the genes for the major outer membrane porin proteins, OmpF and OmpC, of Escherichia coli K-12. Here we show that OmpR, under certain conditions, could activate porin expression in the complete absence of EnvZ. In addition, the pleiotropic phenotypes conferred by a particular envZ mutation (envZ473) required the presence of functional OmpR protein. These results lead us to conclude that EnvZ and OmpR act in sequential fashion to activate porin gene expression; i.e., EnvZ modifies or in some way directs OmpR, which in turn acts at the appropriate porin gene promoter.     

Gene envY of Escherichia coli K-12 affects thermoregulation of major porin expression.

The temperature-dependent expression of OmpF and OmpC, the major channel-forming proteins of the Escherichia coli K-12 outer membrane, was studied. In wild-type cells, decreasing growth temperatures resulted in increased amounts of OmpF protein and correspondingly decreased quantities of OmpC protein. Bacteria deleted for the 13-min chromosomal region did not exhibit this temperature-dependent fluctuation in porin proteins. Plasmid pML22, which consists of pBR322 containing a 0.5-megadalton E. coli chromosomal DNA insert, complemented the thermoregulatory defect. The regulatory gene was named envY. In minicells, pML22 directed the synthesis of an envelope polypeptide (EnvY) having an apparent molecular weight of 25,000. The EnvY protein was synthesized in minicells in greater amounts at 27 degrees C than at 37 degrees C, and a reducing agent was necessary in the solubilization buffer for its subsequent detection on polyacrylamide gels. The results describe the initial characterization of a regulatory system which, along with proteins of the ompB operon, the cyclic AMP system, and the tolC gene product, is involved in a complex network affecting major porin expression.     

Peptides representing the specific variable regions but not the full porin proteins can be useful for antibody based diagnosis of typhoid fever

Antibody response to major porin proteins of S. Typhi (OmpC and OmpF) was evaluated in sera of typhoid patients (culture positive, n = 28; Widal positive, n = 16). Sera from fever patients (n = 6) having etiology other than Salmonella, and normal healthy human controls (n = 18) were also included. No significant difference between the anti-OmpC and anti-OmpF antibodies (Ab) of typhoid patients and controls was observed. The amino acid sequences of OmpC (and OmpF) porin of enterobacteria was aligned and searched for the variable regions specific to S. Typhi. Two regions, each representing one specific variable region of OmpC and OmpF, were selected (peptides for these regions were custom synthesized). The peptides were evaluated for Ab response of sera. A significantly higher level of Ab to both the peptides was observed in the sera of typhoid patients. The findings suggest that porins of S. Typhi are cross reactive and are not good markers for Ab-based diagnosis of typhoid fever, however, peptides representing the variable regions specific to S. Typhi may have greater diagnostic potential.     

Expression of Outer Membrane Proteins in Escherichia coli Growing at Acid pH

It is generally accepted for Escherichia coli that (i) the level of OmpC increases with increased osmolarity when cells are growing in neutral and alkaline media, whereas the level of OmpF decreases at high osmolarity, and that (ii) the two-component system composed of OmpR (regulator) and EnvZ (sensor) regulates porin expression. In this study, we found that OmpC was expressed at low osmolarity in medium of pH below 6 and that the expression was repressed when medium osmolarity was increased. In contrast, the expression of ompF at acidic pH was essentially the same as that at alkaline pH. Neither OmpC nor OmpF was detectable in an ompR mutant at both acid and alkaline pH values. However, OmpC and OmpF were well expressed at acid pH in a mutant envZ strain, and their expression was regulated by medium osmolarity. Thus, it appears that E. coli has a different mechanism for porin expression at acid pH. A mutant deficient in ompR grew slower than its parent strain in low-osmolarity medium at acid pH (below 5.5). The same growth diminution was observed when ompC and ompF were deleted, suggesting that both OmpF and OmpC are required for optimal growth under hypoosmosis at acid pH.