Cell surface exposure of the outer membrane protein OmpA of Escherichia coli K-12

The 325-residue OmpA protein is one of the major outer membrane proteins of Escherichia coli K-12. A model, in which this protein crosses the membrane eight times in an antiparallel beta-sheet conformation and in which regions around amino acids 25, 70, 110 and 154 are exposed at the cell surface, had been proposed. Linkers were inserted into the ompA gene with the result that OmpA proteins, carrying non-OmpA sequences between residues 153 and 154 or 160 and 162, were synthesized. Intact cells possessing these proteins were treated with proteases. Insertion of 15 residues between residues 153 and 154 made the protein sensitive to proteinase K and the sizes of the two cleavage products were those expected following proteolysis at the area of the insertion. Addition of at least 17 residues between residues 160 and 162 left the protein completely refractory to protease action. Thus, the former area is cell surface exposed while the latter area appears not to be. The insertions did not cause a decrease in the concentration of the hybrid proteins as compared to that of the OmpA protein, and in neither case was synthesis of the protein deleterious to cell growth. It is suggested that this method may serve to carry peptides of practical interest to the cell surface and that it can be used to probe surface-located regions of other membrane proteins.     

Apparent bacteriophage-binding region of an Escherichia coli K-12 outer membrane protein.

The 325-residue OmpA protein is one of the major outer membrane proteins of Escherichia coli. It serves as the receptor for several T-even-like phages and is required for the action of certain colicins and for the stabilization of mating aggregates in conjugation. We have isolated two mutant alleles of the cloned ompA gene which produce a protein that no longer functions as a phage receptor. Bacteria possessing the mutant proteins were unable to bind the phages, either reversibly or irreversibly. However, both proteins still functioned in conjugation, and one of them conferred colicin L sensitivity. DNA sequence analysis showed that the phage-resistant, colicin-sensitive phenotype exhibited by one mutant was due to the amino acid substitution Gly leads to Arg at position 70. The second mutant, which contained a tandem duplication, encodes a larger product with 8 additional amino acid residues, 7 of which are a repeat of the sequence between residues 57 and 63. In contrast to the wild-type OmpA protein, this derivative was partially digested by pronase when intact cells were treated with the enzyme. The protease removed 64 NH2-terminal residues, thereby indicating that this part of the protein is exposed to the outside. It is argued that the phage receptor site is most likely situated around residues 60 to 70 of the OmpA protein and that the alterations characterized have directly affected this site.     

Isolation and characterization of outer membrane permeability mutants in Escherichia coli K-12.

Escherichia coli normally requires the lamB gene for the uptake of maltodextrins. We have identified and characterized three independent mutations that allow E. coli to grow on maltodextrin in the absence of a functional lamB gene by allowing maltodextrins with a molecular weight greater than 1,000 to cross the outer membrane barrier. Two of the mutations map to the structural gene for the outer membrane porin OmpF, and the remaining mutation maps to the structural gene for the second major outer membrane porin, OmpC. These mutations increase the permeability of the outer membrane to small hydrophilic substances, antibiotics, and detergents. These mutations alter the electrophoretic mobility of the respective porin proteins.     

Bacteriophage receptor area of outer membrane protein OmpA of Escherichia coli K-12.

A number of T-even-like bacteriophages use the outer membrane protein OmpA of Escherichia coli as a receptor. We had previously analyzed a series of ompA mutants which are resistant to such phages and which still produce the OmpA protein (R. Morona, M. Klose, and U. Henning, J. Bacteriol. 159:570-578, 1984). Mutational alterations were found near or at residues 70, 110 and 154. Based on these and other results a model was proposed showing the amino-terminal half of the 325-residue protein crossing the outer membrane repeatedly and being cell surface exposed near residues 25, 70, 110, and 154. We characterized, by DNA sequence analysis, an additional 14 independently isolated phage-resistant ompA mutants which still synthesize the protein. Six of the mutants had alterations identical to the ones described before. The other eight mutants possessed seven new alterations: Ile-24----Asn, Gly-28----Val, deletion of Glu-68, Gly-70----Cys, Ser-108----Phe, Ser-108----Pro, and Gly-154----Asp (two isolates). Only the latter alteration resulted in a conjugation-deficient phenotype. The substitutions at Ile-24 and Gly-28 confirmed the expectation that this area of the protein also participates in its phage receptor region. It is unlikely that still other such sites of the protein are involved in the binding of phage, and it appears that the phage receptor area of the protein has now been characterized completely.     

Escherichia coli K-12 tolF mutants: alterations in protein composition of the outer membrane.

Outer membrane materials prepared from three independently isolated spontaneous Escherichia coli tolF mutants contained no detectable protein Ia. The loss of this protein was nearly completely compensated for by an increase in other major outer membrane proteins, Ib and II. Thus, the major outer membrane proteins accounted for 40% of the total cell envelope protein in both tol+ and tolF strains. No changes were found in the levels of inner membrane proteins prepared from tolF strains when compared with similar preparations from the tol+ strain. Phage-resistant mutants were selected starting with a tolF strain by using either phage TuIb or phage PA2. These phage-resistant tolF strains contained neither protein Ia nor protein Ib. The mutation leading to the loss of protein Ib in these strains is independent of the tolF mutation and is located near malP on the E. coli genetic map.     

Inhibition of the cytochrome bd-terminated NADH oxidase system in Escherichia coli K-12 by divalent metal cations

Abstract Co(II), Zn(II) and Cd(II) ions inhibited NADH oxidase activity in membranes prepared from two cytochrome bo' -deficient mutants of Escherichia coli K-12 with the following order of potency: Zn ( II ) > Cd ( II ) > > Co ( II ). The degree of inhibition exhibited by these metal ions was not diminished in membranes which contained elevated levels of the cytochrome bd complex, suggesting that the most sensitive site precedes this complex in the aerobic respiratory chain. For each of the metal ions studied, inhibition was determined to be of the non-competitive type. Based upon the efficacy with which EDTA alleviated inhibition, Co(II), Zn(II) and Cd(II) ions are proposed to inhibit NADH oxidase activity by binding to at least two sites in the respiratory chain with significantly different affinities.     

Cloned DNA fragment specifying major outer membrane protein a in Escherichia coli K-12.

Plasmid pMC44 is a recombinant plasmid that contains a 2-megadalton EcoRI fragment of Escherichia coli K-12 DNA joined to the cloning vehicle, pSC101. The polypeptides specified by plasmid pMC44 were identified and compared with those specified by pSC101 to determine those that are unique to pMC44. Three polypeptides specified by plasmid pMC44 were localized in the cell envelope fraction of minicells: a Sarkosyl-insoluble outer membrane polypeptide (designated M2), specified by the cloned 2-megadalton DNA fragment, and two Sarkosyl-soluble membrane polypeptides specified by the cloning plasmid pSC101. Bacteria containing plasmid pMC44 synthesized quantities of M2 approximately equal to the most abundant E. coli K-12 outer membrane protein. Evidence is presented that outer membrane polypeptide M2, specified by the recombinant plasmid pMC44, is the normal E. coli outer membrane protein designated protein a by Lugtenberg and 3b by Schnaitman.     

Two mutations which affect the barrier function of the Escherichia coli K-12 outer membrane.

Two genetically distinct classes of novobiocin-supersensitive mutants were isolated from Escherichia coli K-12. One class, given the phenotypic name NbsA, lies at 10 min on the E. coli chromosome. The order of the genes in this region, based on transductional analyses, is proC NbsA plsA purE. The second, NbsB, lies at 80 min. The order of the genes in this region, based on transduction analyses, is xyl cysE NbsB pyrE. Both classes of mutants show increased sensitivity to hydrophobic drugs but are different: NbsA cells tend to be more sensitive to cationic agents, whereas NbsB cells show the opposite tendency. The sole detectable biochemical alteration in NbsA strain is greater than 90% reduction in the phosphate content of the lipid A region of the lipopolysaccharide. The NbsB mutation results in lipopolysaccharide that contains primarily the stereoisomer D-glycero-D-mannoheptose, rather than L-glycero-D-mannoheptose, and which contains very little of the distal sugars. Since NbsA strains have apparently normal outer membrane proteins and total cellular phospholipids, changes solely in lipopolysaccharide can increase permeability to certain hydrophobic antibiotics. Complementation studies indicate that the NbsA marker is probably allelic with acrA. In addition, the NbsB marker is genetically and phenotypically similar to the rfaD locus of Salmonella typhimurium. For this reason, the phenotypic designations NbsA and NbsB have been changed to the genotypic designations acrA and rfaD, respectively.     

New outer membrane-associated protease of Escherichia coli K-12.

The gene for a new outer membrane-associated protease, designated OmpP, of Escherichia coli has been cloned and sequenced. The gene encodes a 315-residue precursor protein possessing a 23-residue signal sequence. Including conservative substitutions and omitting the signal peptides, OmpP is 87% identical to the outer membrane protease OmpT. OmpP possessed the same enzymatic activity as OmpT. Immuno-electron microscopy demonstrated the exposure of the protein at the cell surface. Digestion of intact cells with proteinase K removed 155 N-terminal residues of OmpP, while the C-terminal half remained protected. It is possible that much of this N-terminal part is cell surface exposed and carries the enzymatic activity. Synthesis of OmpP was found to be thermoregulated, as is the expression of ompT (i.e., there is a low rate of synthesis at low temperatures) and, in addition, was found to be controlled by the cyclic AMP system.     

Overproduction and high-yield purification of phospholipase A from the outer membrane of Escherichia coli K-12

The cloned gene for the outer-membrane-bound phospholipase A from Escherichia coli was placed under control of the strong PL promoter of phage lambda. Induction of PL resulted in a 250-fold overexpression up to about 2% total cellular protein. This overproduced enzyme was indistinguishable from the wild-type enzyme. A homogeneous phospholiphase A preparation was obtained in high yield from overproducing bacteria, using the zwitterionic detergent C12-Sulfobetaine and anion-exchange chromatography. Detergent gradients were found to exert great influence on the elution characteristics. Considerations for the choice of optimal detergent gradients are discussed. The purified enzyme migrated as a single 29-kDa band in SDS/polyacrylamide gels, and required Ca(II) for activity. Maximum activity was displayed by enzyme samples taken from solutions with detergent concentrations near the critical micelle concentration. However, upon switching from high to optimal detergent concentration, maximum activity was restored in several hours, probably reflecting a slow conformational transition of the protein. Because the final pure protein was found to hydrolyze phospholipids in the intact erythrocyte membrane, a densely packed bilayer, we assume that this protein is in its biological native state.     

Strain and temperature-dependent variation in the amount of BtuB polypeptide in the Escherichia coli K-12 outer membrane

Abstract The outer membrane protein BtuB of Escherichia coli K-12 is the receptor for vitamin B₁₂; it is normally present in approx. 200 copies per cell. We describe here the conditions by which BtuB was readily observed in electropherograms of outer membrane preparations. These conditions are as follows. (1) Incorporation of 8 M urea in sodium dodecyl sulfate-polyacrylamide gel systems improved detection of the polypeptide. (2) In most E. coli K-12 strains examined, BtuB was most abundant when cells were grown at 27°C. This thermoregulation of BtuB was independent of envZ and envY , two regulatory genes for outer membrane proteins.     

Insertion mutagenesis on a cell-surface-exposed region of outer membrane protein PhoE of Escherichia coli K-12

Amino acid residue arginine-158 of the outer membrane protein PhoE of Escherichia coli K-12 has been shown to be cell-surface-exposed [Korteland et al. (1985) Eur. J. Biochem. 152, 691-697]. To study the effects of small insertions in this region of the protein on its biogenesis and characteristics, a unique restriction site was created by site-directed mutagenesis in a plasmid carrying the phoE gene and oligonucleotides of 12-74 bp were inserted. The insertions did not interfere with incorporation into the outer membrane since (a) several monoclonal antibodies, directed against the cell-surface-exposed part of PhoE protein, bound to whole cells producing the altered proteins and (b) the proteins formed functional pores for the uptake of beta-lactam antibiotics. The binding of one monoclonal antibody and of the PhoE-specific phages TC45 and TC45hrN3 was disturbed by the insertions, showing that this region of the protein is immunogenic and is involved in the binding of both of these phages. The functioning of the mutant pores was characterized both in vivo by studying the uptake of beta-lactam antibiotics and in vitro after the reconstitution of the proteins in black lipid films. The pore characteristics changed depending on the nature of the inserted amino acids. Addition of a negatively charged amino acid resulted in decreased anion-selectivity, whereas insertion of a positive charge and deletion of a negative charge had only a small influence.     

Comparison of Escherichia coli K-12 outer membrane protease OmpT and Salmonella typhimurium E protein.

The predicted amino acid sequence of OmpT, an Escherichia coli outer membrane protease, was found to be highly homologous to that predicted for the pgtE gene product of Salmonella typhimurium. In this paper, it is shown that pgtE codes for a protein functionally homologous to OmpT as judged by its ability to proteolyze T7 RNA polymerase and to localize in the outer membrane of E. coli.     

Export and localization of N-terminally truncated derivatives of Escherichia coli K-12 outer membrane protein PhoE

To identify export and sorting information in outer membrane protein PhoE of Escherichia coli K-12, a set of deletions was created, resulting in the removal of N-terminal amino acids of the mature protein. Pulse-chase experiments revealed that some mutant proteins were slowly or not at all processed, but there was not correlation between processing rate and the extent of the deletions. The unprocessed precursors were accessible to trypsin in the periplasm showing that processing by leader peptidase rather than translocation is affected by these deletions. The results show that no specific sequences in the N-terminal part of the mature PhoE protein are required for translocation through the inner membrane. The capability of the processed mutant proteins to assemble into the outer membrane was correlated to the exten of the deletions. Thus, mutants which lack up to amino acid residue 14 are normally incorporated into the outer membrane. Larger deletions which removed the first postulated membrane-spanning fragment of the protein affected the efficiency of assembly: in addition to trimers of the protein in the outer membrane, also monomers were detected in the periplasm. If the deletions extended C-terminally to residue 48, only monomeric forms of the proteins were found in the periplasm.     

Assembly pathway of newly synthesized LamB protein an outer membrane protein of Escherichia coli K-12

The assembly of newly induced LamB protein (phage lambda receptor) was investigated in an operon fusion strain of Escherichia coli, in which the lamB gene is expressed under lac promoter control. The induction kinetics both for total cellular and for cell surface-exposed LamB protein were studied by immunochemical detection methods, using two distinct antisera directed against detergent-solubilized LamB trimers and completely denatured LamB monomers, respectively. Anti-trimer antibodies recognized both monomers and trimers, whereas anti-monomer antibodies only reacted with monomers. Provided appropriate solubilization conditions were used, both antisera were able to immunoprecipitate intracellular mature LamB protein quantitatively. Following induction, the first LamB antigenic determinants were detected after 60 to 80 seconds; detection of the newly synthesized protein by anti-monomer antibodies slightly preceded that by anti-trimer antibodies, a finding that could be partly explained by the observation that anti-monomer antibodies recognized a larger fraction of nascent LamB than did anti-trimer antibodies. Exposure of antigenic determinants at the cell surface was delayed for 30 to 50 seconds with respect to their synthesis. Therefore, either translocation or conformational changes must be rate-limiting in the series of processes that eventually convert the newly synthesized protein into its mature outer membrane state. LamB protein was found to occur in at least three clearly distinguishable states. State I is the LamB monomer, state II corresponds to a metastable trimer that dissociates in sodium dodecyl sulphate above 60 degrees C, and state III is the state LamB trimer that dissociates in sodium dodecyl sulphate only at temperatures above 90 degrees C. The chase kinetics of these states showed that conversion of newly synthesized LamB monomers to stable LamB trimers occurred in two stages: state I monomers were chased into metastable state II trimers rapidly (t 1/2 = 20 s), whereas stabilization of state II trimers to state III trimers was a relatively slow (t 1/2 = 5.7 min) process. Based on our results, a timing sequence in the assembly of outer membrane LamB protein is proposed.