Outer Membrane Proteins OmpC Research Articles

Structure and expression of the ompB operon, the regulatory locus for the outer membrane porin regulon in Salmonella typhimurium LT-2

The ompB operon of Salmonella typhimurium encodes a positive transcriptional regulator OmpR and an inner membrane protein EnvZ. Both proteins are needed for the proper expression of the outer membrane proteins OmpC and OmpF. We have determined the nucleotide sequence of the ompB locus and its adjacent regions. A comparison between the S. typhimurium and Escherichia coli sequences revealed that the ompB locus is highly conserved. The sequence data also showed that ompR and envZ form an operon, where the coding regions overlap by four base-pairs. Utilizing ompR- lacZ and envZ- lacZ gene fusions, the translational levels of expression of these two genes were measured, showing that ompR is considerably more efficiently expressed than envZ. Analysis of ompR frameshift mutations showed that translation of envZ is almost totally dependent on the translation of the upstream gene ompR. The mechanism of this translational coupling appears to be a reinitiation of the ribosome at the overlapping region of the two genes. The characteristics of the OmpR and EnvZ proteins were in agreement with the known functions and cellular locations of these proteins. OmpR was found to contain a putative DNA binding site, while EnvZ contained two hydrophobic stretches typical of transmembrane regions. Both OmpR and EnvZ show extensive homologies with many proteins from a number of different origins, all of which function in pairs and through which environmental signals modulate gene expression. Hence, the tightly coupled synthesis of these proteins seems to be essential in eliciting a proper response in the transmembrane regulation of gene expression.

Interaction of OmpR, a positive regulator, with the osmoregulated ompC and ompF genes of Escherichia coli. Studies with wild-type and mutant OmpR proteins.

The OmpR protein is a positive regulator involved in osmoregulatory expression of the ompC and ompF genes that specify the major outer membrane proteins OmpC and OmpF, respectively. We purified the OmpR protein not only from wild-type cells but also from two ompR mutants (ompR2 and ompR3) exhibiting quite different phenotypes as to osmoregulation of the ompC and ompF genes. The OmpR2 protein has an amino acid conversion in the C-terminal portion of the OmpR polypeptide, whereas the OmpR3 protein has one in the N-terminal portion. Comparative studies on these purified OmpR proteins were carried out in terms of their interaction with the ompC and ompF promoters. The nucleotide sequences involved in OmpR-binding were determined in individual promoter regions by deoxyribonuclease I footprinting. The OmpR3 protein as well as the wild-type OmpR protein appeared to bind, to similar extents, to both the ompC and ompF promoters. In contrast, the OmpR2 protein bound preferentially to the ompF promoter and failed to protect the ompC promoter against DNAse I digestion. These results support the view that the C-terminal portion of the OmpR protein is responsible for the binding of the OmpR protein to the ompC and ompF promoter DNAs. Based on these results, the structure and function of the OmpR protein are discussed in relation to the mechanism of osmoregulation.

Isolation and characterization of deletion mutants of ompR and envZ, regulatory genes for expression of the outer membrane proteins OmpC and OmpF in Escherichia coli.

Expression of the ompC and ompF genes coding for the major outer membrane proteins, OmpC and OmpF, respectively, is known to be controlled by at least two regulatory genes, ompR and envZ, which together comprise a single ompB operon. We constructed chromosomal mutants with either ompR-envZ deletion or envZ deletion. Characterization of these deletion strains showed that the OmpR protein is necessary for transcription of the ompC and ompF genes, and the EnvZ protein is essential for normal regulation of the ompC and ompF expression, which is affected by the medium osmolarity. We also constructed several plasmids carrying different portions of the ompB operon. Characterization of these plasmids allowed us to identify the OmpR protein with an apparent molecular weight of 29 kilodaltons (kDa) and the EnvZ protein with an apparent molecular weight of 50 kDa. The initiation codon for EnvZ translation appeared to overlap with the termination codon for OmpR translation. It was also found that a truncated EnvZ polypeptide (44 kDa) which lacks the N-terminal 55 amino acid residues can complement the envZ deletion mutant. Based on these results, the structure and function of the ompB operon are discussed in relation to the regulation of ompC and ompF expression.

Purification and characterization of the OmpR protein, a positive regulator involved in osmoregulatory expression of the ompF and ompC genes in Escherichia coli.

The OmpR protein is a positive regulator involved in osmoregulatory expression of the ompF and ompC genes, which respectively code for major outer membrane proteins OmpF and OmpC of Escherichia coli. The OmpR protein has been purified to homogeneity from an overproducing strain harboring an ompR gene-carrying plasmid. Throughout the purification the OmpR protein behaved as a single entity. The molecular weight determined on sodium dodecyl sulfate-polyacrylamide gel, the total amino acid composition, and the NH2-terminal amino acid sequence of the purified protein were essentially the same as those deduced from the nucleotide sequence of the ompR gene. Molecular weight determination and cross-linking study on the native protein revealed that the purified protein exists as a monomer. The purified OmpR protein was specifically bound to the promoter regions of the ompC and ompF genes. Experiments with a series of upstream deletions of the ompC and ompF promoters revealed that the region upstream from the -35 region was indispensable for OmpR binding to both the ompC and the ompF promoters. Although it has been proposed that depending on the medium osmolarity the OmpR protein may exist in two alternative structures, which respectively regulate functioning of the ompC and the ompF promoters, the purified OmpR protein appeared to be homogeneous and interacted with both promoters to the same extent.

In vivo cloning ad characterization of mutations of the regulatory locus ompR of Escherichia coli K12.

The product of the ompR gene of E. coli K12 is a positive regulatory protein, which is needed for the expression of the major outer membrane proteins OmpC and OmpF in E. coli K12. A simple in vivo technique was used to transfer three ompR mutations (ompR101, ompR472, ompR4) onto a multicopy plasmid carrying the wild-type ompR gene. The resulting clones were transformed into wild type and corresponding mutant backgrounds to analyze their effects on ompC and ompF expression. All of the cloned ompR mutant alleles exhibited a dominant OmpC- phenotype in an ompR+ background. In addition negative complementation of ompF expression was observed between chromosomal ompR4 and multicopy ompR101 alleles. The results suggest an interaction between different OmpR molecules and thereby support the idea that OmpR can exist as a multimeric protein.

Preparation of the FhuA (TonA) receptor protein from cell envelopes of an overproducing strain of Escherichia coli K-12.

A rapid and simple method for purification of the FhuA receptor protein from cell envelopes of a FhuA-overproducing strain of Escherichia coli K-12 was developed. The overproduction of FhuA was programmed by the thermoamplifiable plasmid pHK232, which carried the fhuACD genes of pLC19-19 of the Clarke and Carbon collection. At low temperature (27 degrees C), pHK232 specified the overproduction of FhuA to levels comparable to those of major outer membrane proteins OmpF, OmpC, and OmpA. The amount of these proteins in the outer membrane was reduced along with overproduction of FhuA. Upon runaway replication of pHK232 at 37 degrees C, the precursor of the FhuA protein, proFhuA, was also accumulated in the cell envelope in amounts similar to FhuA. For extraction of the FhuA protein, crude cell envelopes were washed with 2% Triton X-100-6 M urea to remove less tightly bound proteins. Then FhuA but not proFhuA was solubilized by treating Triton X-100-urea-washed membranes with 1% octylglucoside-1 mM EDTA. This procedure yielded FhuA protein free from other membrane proteins. The amount of lipopolysaccharide and phospholipids was low and ranged from 5 to 15% and 10 to 25% of the weight of the FhuA protein, respectively. As shown by direct inactivation and by competition assays, the isolated FhuA protein retained receptor activity for ferrichrome, albomycin, colicin M, and phages T5 and T1.

Evidence for RecA protein association with the cell membrane and for changes in the levels of major outer membrane proteins in SOS-induced Escherichia coli cells.

Membrane fractions from Escherichia coli cells expressing DNA damage-inducible (SOS) functions contain elevated quantities of RecA protein (L. J. Gudas and A. B. Pardee, J. Mol. Biol. 101:459-477, 1976). We used two-dimensional polyacrylamide gel electrophoresis to separate membrane proteins from several strains to determine whether this effect is an artifact due to contamination of membranes during preparation by the large amount of cytoplasmic RecA present in SOS-induced cells. We found that amplification of RecA+ protein without a DNA-damaging treatment does not result in increased RecA-membrane association, whether recA is depressed specifically by an operator-constitutive recA allele or coordinately with other SOS genes by a lexA mutation that inactivates their common repressor. In contrast, large amounts of RecA appear in membrane fractions from undamaged cells of an SOS-constitutive strain carrying recA730, which encodes a spontaneously SOS-activated RecA. We conclude that the increased association of RecA with the membrane fraction requires the presence of the activated form of RecA, and that this association may contribute significantly to the SOS response. We describe also striking effects of SOS expression on the levels of the outer membrane proteins OmpA, OmpC, and OmpF.

Demonstration of a bacteriophage receptor site on the Escherichia coli K12 outer-membrane protein OmpC by the use of a protease.

The Escherichia coli K12 outer-membrane proteins OmpA, OmpC, OmpF, PhoE, and LamB (all of transmembrane nature) can serve as phage receptors. We have shown previously that one OmpA-specific phage, Ox2, can give rise to the host range mutants Ox2h10 and Ox2h12, with the latter being derived from the former [Morona, R. & Henning, U. (1984) J. Bacteriol. 159, 579-582]. Unlike Ox2, both host range phages can use the OmpA and OmpC proteins as receptors and Ox2h12 is better adapted to the OmpC protein than Ox2h10. In a search for the site(s) of OmpC protein involved in phage recognition, it was found that proteinase K is able to cleave all of the proteins mentioned above. OmpC protein (Mr = 38306) could be cleaved from outside the cell by proteinase K resulting in two fragments of Mr approximately equal to 21000 and Mr approximately equal to 17500. The use of OmpC-PhoE hybrid proteins allowed us to assign the approximately equal to 21000-Mr fragment to the CO2H-terminal moiety of the protein. Proteinase K treatment of intact cells abolished their activity to neutralize the OmpC-specific phage Tulb and reduced this ability towards phage Ox2h12. The OmpA, OmpF, PhoE and LamB proteins were cleaved by the protease not in intact cells but only when acting on cell envelopes. The sizes of the OmpC protein fragments and the results obtained with the hybrid proteins very strongly suggest that the protein is cleaved from outside the cell at a region involving amino acid residues 150-178 of the 346-residue protein, which shows homology to two regions of the OmpA protein which are involved in its phage receptor site (loc. cit.). These areas also exhibit some homology to a region of the LamB protein which is thought to be part of this protein's receptor site [Charbit et al. (1984) J. Mol. Biol. 175, 395-401]. This suggests that there is a common denominator for proteinaceous phage receptor site because the LamB-specific phage lambda and phage Tulb are of completely different nature. We conclude that the region of the OmpC protein in question is cell-surface-exposed and acts as a phage receptor site.

DNA sequence analysis of the dye gene of Escherichia coli reveals amino acid homology between the dye and OmpR proteins.

Mutation of the dye gene of Escherichia coli results in sensitivity of dyes, envelope protein changes, loss of expression of alkaline phosphatase, and reduced transcription of sex factor F genes. We have determined the DNA sequence of a 1.4-kilobase pair fragment encompassing the dye gene. The coding sequence of dye was identified as an open reading frame coding for a protein of Mr 27,346. A sequence of 54 residues at the amino terminus was extremely acidic, with 12 aspartic plus glutamic acid residues and only 2 lysine plus arginine residues. A sequence of 19 adjacent residues near the center of the protein was identical, except for one mismatch, with a sequence in the OmpR protein, involved in controlling the amounts of the major outer membrane proteins OmpF and OmpC at the level of transcription. 28% of the Dye protein was homologous with OmpR. The positions of dye and ompR on the genetic map were indicative of a gene duplication. It seems likely, therefore, that the Dye and OmpR proteins are related, and Dye may thus be involved in the osmoregulation of envelope protein genes as well as being required for sex factor gene expression. The Dye protein itself, like OmpR, was shown not to be an envelope protein. A second open reading frame on the other DNA strand may use the same transcription termination site as dye.

Promoter exchange between ompF and ompC, genes for osmoregulated major outer membrane proteins of Escherichia coli K-12

Expression of the ompF and ompC genes coding for major outer membrane proteins OmpF and OmpC is regulated in opposite directions by medium osmolarity. Chimera genes were constructed by a reciprocal exchange of the promoter-signal sequence region between the two genes. The chimera gene construction was designed so that the proteins synthesized by these genes were essentially the same as the OmpC and OmpF proteins. Studies with the chimera genes demonstrated that the osmoregulation of the OmpF-OmpC synthesis was promoter dependent. They also showed that cells grew normally even when the osmoregulation took place in opposite directions. The effects of the ompR2 and envZ mutations, which suppress ompC and ompF expression, respectively, also became reversed. The reduced expression was still subject to the promoter-controlled osmoregulation. Based on these observations, the mechanism of regulation of the ompF-ompC gene expression and its physiological importance are discussed.

A unique mechanism regulating gene expression: translational inhibition by a complementary RNA transcript (micRNA).

The expression of the genes for the major outer membrane proteins OmpF and OmpC are osmoregulated. The ompC locus was found to be transcribed bidirectionally under conditions of high osmolarity and a 174-base transcript encoded upstream of ompC was found to inhibit the OmpF production and to substantially reduce the amount of the ompF mRNA. This RNA [mRNA-interfering complementary RNA (micRNA)] has a long sequence that is complementary to the 5' end region of the ompF mRNA. We propose that the micRNA inhibits the translation of the ompF mRNA by hybridizing with it. This RNA interaction may cause premature termination of the transcription of the ompF gene or destabilization of the ompF mRNA or both.

Mutation causing overproduction of outer membrane protein OmpF and suppression of OmpC synthesis in Escherichia coli.

A novel mutation affecting the synthesis of major outer membrane proteins OmpF and OmpC in Escherichia coli K-12 is described. The mutation resulted in overproduction of the OmpF protein with concomitant suppression of OmpC synthesis. This mutation, designated as ompFp100, was mapped at 21 min on the E. coli chromosome map with the gene order aroA-aspC-ompF4-ompFp100-asnS-pyrD. This mutation was cis-dominant to the expression of the ompF gene. In addition, the direction of the mRNA transcription of the ompF gene was from asnS to aspC. These results strongly indicate that ompFp100 is a promoter mutation of the ompF gene. Introduction of an ompF mutation, which causes the disappearance of the OmpF protein, into strains carrying the ompFp100 mutation resulted in the reappearance of the OmpC protein in the outer membrane. Addition of a high concentration of sucrose to the medium, which suppresses the OmpF synthesis and stimulates the OmpC synthesis in the wild-type strain, resulted in the reappearance of the OmpC protein in the ompFp100 mutant with concomitant suppression of the overproduction of the OmpF protein. These results suggest that suppression of OmpC synthesis in the ompFp100 mutant is due to overproduction of the OmpF protein.

Transport of aminoglycosides in Escherichia coli

Uptake of nine aminoglycosides was studied in E. coli K12 and mutants being defective in the outer membrane proteins OmpF and OmpC or in ATPase (uncA). OmpF/OmpC as well as uncA mutants did not take up the aminoglycosides; transport in wild type cells was cAMP dependent. The specific binding of phages using the OmpF and OmpC proteins as receptors was strongly reduced by the aminoglycosides or by other polycationic peptides. Thus it may be assumed that the initial step of aminoglycoside transport is their electrostatic binding to the anionic porins, especially to the ompF porin, followed by a facilitated permeation through the outer membrane. As the synthesis of this porin is under cAMP control, aminoglycoside transport is cAMP dependent as well. The fact that the uncA mutant did not take up the aminoglycosides to any appreciable extent indicates that the cytoplasmic membrane is involved in aminoglycoside transport too.

Roles of lipopolysaccharide and outer membrane protein OmpC of Escherichia coli K-12 in the receptor function for bacteriophage T4.

The roles of lipopolysaccharide and OmpC, a major outer membrane protein, in the receptor function for bacteriophage T4 were studied by using Escherichia coli K-12 strains having mutations in the ompC gene or in genes controlling different stages of lipopolysaccharide synthesis. The receptor activity for T4 was monitored by (i) T4 sensitivity of intact cells, (ii) phage inactivation activity of cell envelopes, and (iii) phage inactivation activity of specimens reconstituted from purified OmpC and lipopolysaccharide. It was found that (i) in the presence of the OmpC protein, the essential region of the lipopolysaccharide for the receptor activity was the core-lipid A region that includes the heptose region, whereas the glucose region was not necessarily required for the receptor function; (ii) the OmpC protein was not required at all when the distal end of the lipopolysaccharide was removed to expose a glucose residue at the distal end; and (iii) when cells lacked both the OmpC protein and the glucose region, they became extremely resistant to T4. Based on these findings, the roles of the OmpC protein and lipopolysaccharide in T4 infection are discussed.

Regulatory mutations conferring constitutive synthesis of major outer membrane proteins (OmpC and OmpF) in Escherichia coli.

An ompB strain of Escherichia coli K-12 lacking major outer membrane proteins OmpC and OmpF was used to isolate a pair of mutants that have restored the ability to synthesize either OmpC or OmpF protein. These mutants were found to produce the respective proteins constitutively under the several conditions where the synthesis in the wild-type strain was markedly repressed; namely, in the absence of the ompB gene function, under restrictive medium conditions, or upon lysogenization with phage PA-2. The mutations ompCp1 and ompFp9 responsible for such synthesis were shown to be located in the close vicinity of the corresponding structural genes, ompC and ompF. Moreover, the mutations affect the expression of these genes in a cis-dominant fashion. Taken together with other evidence, it was suggested that ompCp1 and ompFp9 represent regulatory site mutations occurring at the promoter regions of ompC and ompF respectively. Relevance of these findings to the genetic control of outer membrane protein synthesis is discussed.