Host range mutants of bacteriophage Ox2 can use two different outer membrane proteins of Escherichia coli K-12 as receptors.

The Escherichia coli K-12 outer membrane protein OmpA functions as the receptor for bacteriophage Ox2. We isolated a host range mutant of this phage which was able to grow on an Ox2-resistant ompA mutant producing an altered OmpA protein. From this mutant, Ox2h5, a second-step host range mutant was recovered which formed turbid plaques on a strain completely lacking the OmpA protein. From one of these mutants, Ox2h10, a third-step host range mutant, Ox2h12, was isolated which formed clear plaques on a strain missing the OmpA protein. Ox2h10 and Ox2h12 apparently were able to use both outer membrane proteins OmpA and OmpC as receptors. Whereas there two proteins are very different with respect to primary structures and functions, the OmpC protein is very closely related to another outer membrane protein, OmpF, which was not recognized by Ox2h10 or Ox2h12. An examination of the OmpC amino acid sequence, in the regions where it differs from that of OmpF, revealed that one region shares considerable homology with a region of the OmpA protein which most likely is required for phage Ox2 receptor activity.     

Single mutations in a gene for a tail fiber component of an Escherichia coli phage can cause an extension from a protein to a carbohydrate as a receptor

The T-even type Escherichia coli phage Ox2 recognizes the outer membrane protein OmpA as a receptor. This recognition is accomplished by the 266 residue protein 38, which is located at the free ends of the virion's long tail fibers. Host-range mutants had been isolated in three consecutive steps: Ox2----Ox2h5----Ox2h10----Ox2h12, with Ox2h12 recognizing the outer membrane protein OmpC efficiently and having lost some affinity for OmpA. Protein 38 consists, in comparison with these proteins of other phages, of two constant and one contiguous array of four hypervariable regions; the alterations leading to Ox2h12 were all found within the latter area. Starting with Ox2h12, further host-range mutants could be isolated on strains resistant to the respective phage: Ox2h12----h12h1----h12h1.1----h12h1.11----h12 h1.111. It was found that Ox2h12h1.1 (and a derivative of Ox2h10, h10h4) probably uses, instead of OmpA or OmpC, yet another outer membrane protein, designated OmpX. Ox2h12h1.11 was obtained on a strain lacking OmpA, -C and -X. This phage could not grow on a mutant of E. coli B, possessing a lipopolysaccharide (LPS) with a defective core oligosaccharide; Ox2h12h1.111 was obtained from this strain. It turned out that the latter two mutants used LPS as a receptor, most likely via its glucose residues. Selection for resistance to them in E. coli B (ompA+, ompC-, ompX-) yielded exclusively LPS mutants, and in another strain, possessing OmpA, C and X, the majority of resistant mutants were of this type. Isolated LPS inactivated the mutant phages very well and was inactive towards Ox2h12. By recombining the genes of mutant phages into the genome of parental phages it could be shown that the phenotypes were associated with gene 38. All mutant alterations (mostly single amino acid substitutions) were found within the hypervariable regions of protein 38. In particular, a substitution leading to Ox2h12h1.11 (Arg170----Ser) had occurred at the same site that led to Ox2h10 (His170----Arg), which binds to OmpC in addition to OmpA. It is concluded that not only can protein 38 gain the ability to switch from a protein to a carbohydrate as a receptor but can do so using the same domain of the polypeptide.     

TolA central domain interacts with Escherichia coli porins.

TolA is an inner membrane protein with three domains: a transmembrane N-terminus and periplasmic central and C-terminal domains. The interaction of TolA with outer membrane porins of Escherichia coli was investigated. Western blot analyses of cell extracts with anti-TolA antibodies indicated that TolA forms high molecular weight complexes specifically with trimeric OmpF, OmpC, PhoE and LamB, but not with OmpA. The interaction of purified TolA domains with purified porins was also studied. TolA interacted with OmpF, PhoE and LamB porins via its central domain, but not with either their denatured monomeric forms or OmpA. Moreover, the presence or absence of lipopolysaccharides associated with trimeric porins did not modify the interactions. These results suggest that the specific interaction of TolA with outer membrane porins might be relevant to the function of Tol proteins.     

Receptor specificity of the Escherichia coli T-even type phage Ox2. Mutational alterations in host range mutants

The T-even type Escherichia coli phage Ox2 uses the outer membrane protein OmpA as a receptor. The protein is recognized with the ends of the virion's long tail fibers. The 266 residue protein 38 is located at this site and acts as an adhesin. Host-range mutants had previously been isolated from Ox2. Mutant Ox2h5 is able to infect cells possessing an altered OmpA protein, which renders the cell resistant to Ox2. Ox2h10 was selected from Ox2h5. This phage recognizes the OmpC protein in addition to the OmpA protein. Ox2h12, which stems from Ox2h10, binds to OmpC with high affinity, but has lost efficient binding to OmpA. The mutational alterations caused in genes 38 are: Asp231----Asn(h5) and His170----Arg(h10). The triple mutant Ox2h12 possesses an insertion of a Gly residue next to Gly121. The three mutants have additionally acquired mutations affecting their base plate, making them "trigger-happy". When protein 38 was compared with the same protein derived from other E. coli phages, it was found to contain two constant and one variable domains, the latter harboring four hypervariable regions flanked by a largely conserved glycine-rich sequence. The h5 and h10 mutations occurred within two hypervariable areas, while the additional Gly residue was present in one of the flanking conserved sequences. On the basis of these results, as well as those obtained from host-range mutants analyzed previously, a model for such adhesins is proposed. Receptor recognition is most likely performed via the hypervariable regions, which may form loops held together in close proximity by the oligoglycine sequences. The latter may achieve this by being part of highly compact omega loops.     

PhoE protein pore of the outer membrane of Escherichia coli K12 is a particularly efficient channel for organic and inorganic phosphate

This study was undertaken to investigate the proposed in vivo pore function of PhoE protein, an Escherichia coli K12 outer membrane protein induced by growth under phosphate limitation and to compare it with those of the constitutive pore proteins OmpF and OmpC. Appropriate mutant strains were constructed containing only one of the proteins PhoE, OmpF or OmpC, or none of these proteins at all. By measuring rates of nutrient uptake at low solute concentrations, the proposed pore function of PhoE protein was confirmed as the presence of the protein facilitates the diffusion of Pi through the outer membrane, such as a pore protein deficient strain behaves as a Km mutant. Comparison of the rates of permeation of Pi, glycerol 3-phosphate and glucose 6-phosphate through pores formed by PhoE, OmpF and OmpC proteins shows that PhoE protein is the most effective pore in facilitating the diffusion of Pi and phosphorus-containing compounds. The three types of pores were about equally effective in facilitating the permeation of glucose and arsenate. Possible reasons for the preference for Pi and Pi-containing solutes are discussed.     

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.     

Acquisition of Escherichia coli outer membrane proteins by Bdellovibrio sp. strain 109D

The ability of Bdellovibrio sp. to acquire the OmpF major outer membrane protein from its Escherichia coli prey was examined to determine if there were other outer membrane proteins which could or could not be acquired. Growth of bdellovibrios on mutant prey which were defective in the expression of outer membrane proteins revealed that Bdellovibrio sp. could acquire the OmpC protein in the absence of the OmpF protein. However, the OmpA, LamB, and protein 2 proteins could not be found in the Bdellovibrio Triton-insoluble outer membrane. The disappearance of the OmpF and OmpC proteins from the bdelloplast surface was measured, and it was determined that Bdellovibrio sp. exhibited a kinetic and temporal preference for the OmpF protein. Bdellovibrios could be grown on porin-deficient prey, and the progeny bdellovibrios possessed outer membranes with a protein mass deficiency.     

Escherichia coli phage receptors. Minor porins and proteins participating in the specific transport as phage receptors

Except for the main porin proteins OmpC and OmpF there exist the membrane proteins participating in the transport of specific substrates: phosphates, nucleosides, iron, vitamin B12, maltose and maltodextrins, that also play the role of phage receptors. Some phages use as receptors the porins determined by the genes of lambdoid prophages. LamB protein that serves receptor for phage lambda exposes the amino acids sequence on the outer surface of membranes that participates in phage adsorption. The sequence is similar to tetrapeptide of fibronectin responsible for binding with the surface of cellular receptor in eucaryotes.     

PhoE protein pore of the outer membrane of Escherichia coli K12 is a particularly efficient channel for organic and inorganic phosphate

This study was undertaken to investigate the proposed in vivo pore function of PhoE protein, an Escherichia coli K12 outer membrane protein induced by growth under phosphate limitation, and to compare it with those of the constitutive pore proteins OmpF and OmpC. Appropriate mutant strains were constructed containing only one of the proteins PhoE, OmpF or OmpC, or none of these proteins at all. By measuring rates of nutrient uptake at low solute concentrations, the proposed pore function of PhoE protein was confirmed as the presence of the protein facilitates the diffusion of P_i through the outer membrane, such that a pore protein deficient strain behaves as a K_m mutant. Comparison of the rates of permeation of P_i, glycerol 3-phosphate and glucose 6-phosphate through pores formed by PhoE, OmpF and OmpC proteins shows that PhoE protein is the most effective pore in facilitating the diffusion of P_i and phosphorus-containing compounds. The three types of pores were about equally effective in facilitating the permeation of glucose and arsenate. Possible reasons for the preference for P_i and P_i-containing solutes are discussed.     

Role of the cell surface-exposed regions of outer membrane protein PhoE of Escherichia coli K12 in the biogenesis of the protein

To investigate the role of the cell surface-exposed regions of outer membrane protein PhoE of Escherichia coli K12 in the biogenesis of the protein, deletions were generated in two presumed cell surface-exposed regions of the protein. Intact cells expressing these mutant proteins were recognized by PhoE-specific monoclonal antibodies, which recognize conformational epitopes on the cell surface-exposed parts of the protein and/or were sensitive to a PhoE-specific phage. This shows that the polypeptides were normally incorporated into the outer membrane. When the deletions extended four amino acid residues into the seventh presumed membrane-spanning segment, the polypeptides accumulated in the periplasm. In conclusion, exposed regions of PhoE protein apparently do not play an essential role in outer membrane localization, which is consistent with the observation that these regions are hypervariable when PhoE is compared to the related proteins OmpF and OmpC. In contrast, the membrane-spanning segments are essential for the assembly process.     

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.     

Production of Escherichia coli LamB protein in Yersinia enterocolitica

Abstract Plasmid pBCP 68 carrying the lamB gene of Escherichia coli was introduced and expressed in Yersinia enterocolitica cells. The presence of LamB protein in the outer membrane of the wild-type strain of Y. enterocolitica coincided with the loss of the OmpC and OmpF porins. Western blot analysis showed that LamB in Y. enterocolitica cells co-migrated with authentic monomeric LamB, indicating that its signal peptide was recognized and cleaved by Y. enterocolitica and properly integrated into the outer membrane. The expression of LamB made Y. enterocolitica sensitive to phage λ.     

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.     

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.     

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.     

Role of lipopolysaccharide in assembly of Escherichia coli outer membrane proteins OmpA, OmpC, and OmpF.

Selection was performed for resistance to a phage, Ox2, specific for the Escherichia coli outer membrane protein OmpA, under conditions which excluded recovery of ompA mutants. All mutants analyzed produced normal quantities of OmpA, which was also normally assembled in the outer membrane. They had become essentially resistant to OmpC and OmpF-specific phages and synthesized these outer membrane porins at much reduced rates. The inhibition of synthesis acted at the level of translation. This was due to the presence of lipopolysaccharides (LPS) with defective core oligosaccharides. Cerulenin blocks fatty acid synthesis and therefore that of LPS. It also inhibits synthesis of OmpC and OmpF but not of OmpA (C. Bocquet-Pagès, C. Lazdunski, and A. Lazdunski, Eur. J. Biochem. 118:105-111, 1981). In the presence of the antibiotic, OmpA synthesis and membrane incorporation remained unaffected at a time when OmpC and OmpF synthesis had almost ceased. The similarity of these results with those obtained with the mutants suggests that normal porin synthesis is not only interfered with by production of mutant LPS but also requires de novo synthesis of LPS. Since synthesis and assembly of OmpA into the outer membrane was not affected in the mutants or in the presence of cerulenin, association of this protein with LPS appears to occur with outer membrane-located LPS.     

Interaction of plant extracts of <Emphasis Type="Italic">Ungernia victoris,Rhodiola rosea</Emphasis>, and <Emphasis Type="Italic">Polyscias filicifolia</Emphasis> with a bacterial cell

Components of three investigated plant extracts from the biomass of cultivated cells of Ungernia victoris, Rhodiola rosea, and Polyscias filicifolia interact with porin proteins OmpC and OmpF and reduce their receptor activity towards OmpC- and OmpF-dependent bacteriophages. The influx of these components into cells optimizes the synthesis of a lipopolysaccharide (LPS) complex and contributes to the enhancement of receptor activity of not only LPS but also OmpA and LamB proteins closely associated with the latter.     

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.