An artificial hydrophobic sequence functions as either an anchor or a signal sequence at only one of two positions within the Escherichia coli outer membrane protein OmpA

The 325-residue outer membrane protein, OmpA, of Escherichia coli, like most other outer membrane proteins with known sequence, contains no long stretch of hydrophobic amino acids. A synthetic oligonucleotide, encoding the sequence Leu-Ala-Leu-Val, was inserted four times between the codons for amino acid residues 153 and 154 and two, three, or four times between the codons for residues 228 and 229, resulting in the OmpA153-4, OmpA-228-2, -3, and -4 proteins, respectively. In the first case, the lipophilic sequence anchored the protein in the plasma membrane. In the OmpA228 proteins, 16 but not 12 or 8 lipophilic residues most likely also acted as an anchor. By removal of the NH2-terminal signal peptide, the function of the insert in OmpA153-4 was converted to that of a signal-anchor sequence. Possibly due to differences in amino acid sequences surrounding the insert, no signal function was observed with the insert in OmpA228-4. Production of the OmpA153-4 protein, with or without the NH2-terminal signal sequence, resulted in a block of export of chromosomally encoded OmpA. Clearly, long hydrophobic regions are not permitted within proteins destined for the bacterial outer membrane, and these proteins, therefore, have had to evolve another mechanism of membrane assembly.     

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.     

In vivo membrane assembly of split variants of the E.coli outer membrane protein OmpA.

The two-domain, 325 residue outer membrane protein OmpA of Escherichia coli is a well-established model for the study of membrane assembly. The N-terminal domain, consisting of approximately 170 amino acid residues, is embedded in the membrane, presumably in the form of a beta-barrel consisting of eight antiparallel transmembrane beta-strands. A set of 16 gene variants carrying deletions in the membrane-embedded domain of OmpA was constructed. When pairs of these mutant genes were co-expressed in E.coli, it was found that a functional OmpA protein could be assembled efficiently from two complementary protein fragments. Assembly was found when the polypeptide chain was split at the second or third periplasmic turn. All four protein termini were located in the periplasmic space. Interestingly, duplication of transmembrane strands five and six led to a variant with an unusual topology: the N-terminus of one fragment and the C-terminus of the other fragment were exposed at the cell surface. This is the first demonstration of correct membrane assembly of split beta-structured membrane proteins. These findings are important for a better understanding of their folding/assembly pathway and may have implications for the development of artificial outer membrane proteins and for the cell surface display of heterologous peptides or proteins.     

A unique amino acid substitution in the outer membrane protein OmpA causes conjugation deficiency in Escherichia coli K-12

The outer membrane protein OmpA of E. coli K-12 can serve as a receptor for phages and is required for stabilizing mating aggregates during F'-mediated conjugation. Selection for resistance to OmpA-specific phages yields mutants with alterations in the protein at four cell surface exposed sites. It is shown that conjugation deficiency can be caused by apparently only one type of amino acid substitution at one of these sites, the replacement of glycine-154 by aspartic acid. This suggests that, in contrast to binding of phages, a ligand of the donor cell recognizes only a very small area of the protein.     

The signal sequence of an Escherichia coli outer membrane protein can mediate translocation of a not normally secreted protein across the plasma membrane

The distal part of the long tail fibers of the Escherichia coli phage T4 consists of a dimer of protein 37. A fragment of the corresponding gene, encoding 253 amino acids, was inserted into several different sites within the cloned gene for the 325-residue outer membrane protein OmpA. In plasmid pTU T4-5 the fragment was inserted once and in pTU T4-10 tandemly twice between the codons for residues 153 and 154 of the OmpA protein. In pTU T4-22 two fragments were present, in tandem, between the codons for residues 45 and 46 of this protein. In pIN T4-6 one fragment was inserted into the ompA gene immediately following the part encoding the signal sequence. The corresponding mature proteins consist, in this order, of 605, 860, 835, and 279 amino acid residues. All precursor proteins were processed and translocated across the plasma membrane. Hence, not only can the OmpA protein serve as a vehicle for export of a nonsecretory protein, but the signal sequence alone can also mediate export of such a protein. Export of the pro-OmpA protein depends on the SecA protein. Export of the tail fiber fragment expressed from pIN T4-6 remained SecA dependent. Thus, the secA pathway in this case is chosen by the signal peptide. It is proposed that a signal peptide can mediate translocation of nonsecretory proteins as long as they are export-compatible. The inability of a signal sequence to mediate export of some proteins appears to be due to export incompatibility of the protein rather than to the absence of information, within the mature part of the polypeptide, which would be required for translocation.     

Insertion of peptides into cell-surface-exposed areas of the Escherichia coli OmpA protein does not interfere with export and membrane assembly

Peptides, 21 amino acids (aa) in length, were inserted into cell-surface-exposed areas of the Escherichia coli outer membrane protein, OmpA, corresponding to aa positions 70 or 154 or at both sites simultaneously. The corresponding hybrid proteins were exported and normally assembled in the outer membrane. The results of protease-accessibility experiments are compatible with the presence of the peptides at the cell surface.     

The influence of amino substitutions within the mature part of an Escherichia coli outer membrane protein (OmpA) on assembly of the polypeptide into its membrane

The membrane part of the 325-residue outer membrane protein OmpA of Escherichia coli encompasses residues 1-177. This part is thought to cross the membrane eight times in antiparallel beta-strands, forming four loops of an amphipathic beta-barrel. With the aim of gaining some insight into the mechanism of sorting, i.e. the way the protein recognizes and assembles into its membrane, a set of point mutants in the ompA gene has been generated. Selection for toxicity of ompA expression following mutagenesis with sodium bisulfite yielded genes with multiple base pair substitutions, the majority of which resulted in amino acid substitutions in the membrane moiety of the protein. None of the altered proteins was blocked in membrane incorporation. A proline residue exists at or near each of the presumed turns at the inner side of the outer membrane. Using oligonucleotide-directed mutagenesis, each of them was replaced by a leucine residue which is thought to be a turn blocking residue. None of these proteins had lost the ability to be incorporated into the membrane. Apparently, leucine residues are tolerated at turns in this protein. To interfere with the formation of antiparallel beta-strands, four double mutants were prepared: ompA-ON3 (Ala11----Pro, Leu13----Pro), -ON4 (Ala11----Asp, Leu13----Pro), -ON5 (Gly160----Val, Leu162----Arg), and -ON6 (Leu164----Pro, Val166----Asp). The former three proteins and even quadruple mutants consisting of a combination of ompA-ON2 or -ON4 with -ON5 were not defective in membrane assembly. In contrast, the OmpA-ON6 protein was translocated across the plasma membrane but could not be incorporated into the outer membrane. It is concluded that at least one rather small area of the polypeptide is of crucial importance for the assembly of OmpA into the outer membrane.     

Internal deletions in the gene for an Escherichia coli outer membrane protein define an area possibly important for recognition of the outer membrane by this polypeptide

A series of overlapping deletions has been constructed in the ompA gene which encodes the 325-residue Escherichia coli outer membrane protein OmpA. Immunoelectron microscopy showed that the OmpA fragments were either located in the periplasmic space or were associated with the outer membrane. Apparently an area between residues 154 and 180 is required for this association; all proteins missing this area were found to be periplasmic. The nature of this association remained unknown; no membrane-protected tryptic fragments could be identified for any of these polypeptides. Hybrid genes were constructed encoding parts of the periplasmic maltose binding protein and an area of the ompA gene coding for residues 154-274. The corresponding proteins were not localized to the outer membrane but remained attached to the outer face of the plasma membrane, possibly because the normal mechanism of release from this membrane was impaired. In the OmpA protein the conspicuous sequence Ala180-Pro-Ala-Pro-Ala-Pro-Ala-Pro187 exists. Frameshift mutants were constructed to eliminate this sequence. There was no effect on the incorporation of the mutant proteins into the outer membrane. Thus, this "hinge" region is not involved in sorting. A proposal suggesting the existence of a sorting signal common to several outer membrane proteins (Benson, S. A., Bremer, E., and Silhavy, T. J. (1984) Proc. Natl. Acad. Sci. U. S. A. 81, 3830-3834) was subsequently rejected (Bosch, D., Leunissen, J., Verbakel, J., de Jong, M., van Erp, H., and Tommassen, J. (1986) J. Mol. Biol. 189, 449-455; Freudl, R., Schwarz, H., Klose, M., Movva, N. R., and Henning, U. (1985) EMBO J. 4, 3593-3598). Although it is not known whether or not the outer membrane association observed represents a step in the normal sorting mechanism, it is concluded that it remains an open question whether or not a sorting signal, as proposed originally, exists in outer membrane proteins.     

Gene fusions using the ompA gene coding for a major outer-membrane protein of Escherichia coli K12

It has been shown previously that fragments of the Escherichia coli major outer membrane protein OmpA lacking CO2H-terminal parts can be incorporated into this membrane in vivo [Bremer et al. (1982) Eur. J. Biochem. 122, 223-231]. The possibility that these fragments can be used, via gene fusions, as vehicles to transport other proteins to the outer membrane has been investigated. To test whether fragments of a certain size were optimal for this purpose a set of plasmids was prepared encoding 160, 193, 228, 274, and 280 NH2-terminal amino acids of the 325-residue OmpA protein. The 160-residue fragment was not assembled into the outer membrane whereas the others were all incorporated with equal efficiencies. Thus, if any kind of OmpA-associated stop transfer is required during export the corresponding signal might be present between residues 160 and 193 but not CO2H-terminal to 193. The ompA gene was fused to the gene (tet) specifying tetracycline resistance and the gene for the major antigen (vp1) of foot-and-mouth disease virus. In the former case a 584-residue chimeric protein is encoded consisting NH2-terminally of 228 OmpA residues followed by 356 CO2H-terminal residues of the 396-residue 'tetracycline resistance protein'. In the other case the same part of OmpA is followed by 250 CO2H-terminal residues of the 213-residue Vp1 plus 107 residues partly derived from another viral protein and from the vector. Full expression of both hybrids proved to be lethal. Lipophilic sequences bordered by basic residues, present in the non-OmpA parts of both hybrids were considered as candidates for the lethal effect. A plasmid was constructed which codes for 280 OmpA residues followed by a 31-residue tail containing the sequence: -Phe-Val-Ile-Met-Val-Ile-Ala-Val-Ser-Cys-Lys-. Expression of this hybrid gene was lethal but by changing the reading frame for the tail to encode another, 30-residue sequence the deleterious effect was abolished. It is possible that the sequence incriminated acts as a stop signal for transfer through the plasma membrane thereby jamming export sites for other proteins and causing lethality. If so, OmpA appears to cross the plasma membrane completely during export.     

Export of altered forms of an Escherichia coli K-12 outer membrane protein (OmpA) can inhibit synthesis of unrelated outer membrane proteins

Expression of mutant ompA genes, encoding the 325 residue Escherichia coli outer membrane protein OmpA, caused an inhibition of synthesis of the structurally unrelated outer membrane porins OmpC and OmpF and of wild-type OmpA, but not of the periplasmic beta-lactamase. There was no accumulation of precursors of the target proteins and the inhibitory mechanism operated at the level of translation. So far only alterations around residue 45 of OmpA have been found to affect this phenomenon. Linkers were inserted between the codons for residues 45 and 46. A correlation between size and sequence of the resulting proteins and presence or absence of the inhibitory effect was not found, indicating that the added residues acted indirectly by altering the conformation of other parts of the mutant OmpA. To be effective, the altered polypeptides had to be channelled into the export pathway. Internal deletions in effector proteins, preventing incorporation into the membrane, abolished effector activity. The results suggest the existence of a periplasmic component that binds to OmpA prior to membrane assembly; impaired release of this factor from mutant OmpA proteins may trigger inhibition of translation. The factor could be a See B-type protein, keeping outer membrane proteins in a form compatible with membrane assembly.     

Creation of targets for proteolytic cleavage in the LamB protein of E coli K12 by genetic insertion of foreign sequences: implications for topological studies

LamB, an integral outer membrane protein of E coli K12, is highly resistant to protease digestion. We had previously genetically inserted a foreign sequence corresponding to an epitope from the poliovirus next to amino acids 146, 153, 189, and 374 of LamB. In 3 cases (sites 146, 153, 374), insertion of the foreign peptide did not extensively affect the functions of LamB (and therefore folding). In 2 cases (sites 146 and 374) the polio virus epitope was detectable on the bacterial surface with a specific monoclonal antibody. We show here that the 4 modified proteins are sensitive to trypsin, including on intact cells. The sizes of the major cleavage products is that expected for proteolysis at or near the sequences inserted. In 1 case (site 153), this was directly demonstrated by protein sequencing. The results confirm the cell surface exposure of the regions of residues 153 and 374 and provide information on the regions around residues 146 and 189. Perspectives and limitations of this approach for fine studies on the mode of insertion of membrane proteins are briefly discussed.     

Restoration of membrane incorporation of an Escherichia coli outer membrane protein (OmpA) defective in membrane insertion

The mechanism of sorting, to the outer membrane, of the 325-residue Escherichia coli protein OmpA has been investigated. It is thought to traverse the membrane eight times in antiparallel beta-strands, forming an amphiphilic beta-barrel which encompasses residues 1 to about 170; the COOH-terminal moiety is periplasmic. A mutant, carrying the substitutions Leu164----Pro and Val166----Asp within the last beta-strand (residues 160-170), has been described which was unable to assemble in the membrane (Klose, M., MacIntyre, S., Schwarz, H., and Henning, U. (1988) J. Biol. Chem. 263, 13297-13302). Linkers were inserted between the codons for residues 164 and 165 of the mutant protein. Of 13 different genes recovered, five encoded proteins which had regained the ability to assemble in the membrane. The properties of the mutant proteins, together with a structure prediction method, indicate the following rules for the final beta-strand to be compatible with, or possibly initiate, membrane insertion: (i) it must be amphiphilic or hydrophobic while its primary structure as such is fairly unimportant, (ii) it must extend over at least 9 residues, and (iii) it must not contain a proline residue around its center. One of the genes recovered coded for OmpA up to residue 164 and then followed by 10 linker-encoded residues. This 174-residue polypeptide was assembled in the membrane but did not, in contrast to all other proteins, expose sites sensitive to trypsin at the inner face of the membrane. This behavior agrees perfectly well with the OmpA model.     

Molecular characterization of the gene coding for major outer membrane protein OmpA from Enterobacter aerogenes

The ompA gene from Enterobacter aerogenes was subcloned into a low-copy-number plasmid vector and the resultant plasmid, pTU7En, used to study its expression in Escherichia coli K12. Although the gene was strongly expressed and large amounts of OmpA protein were present in the outer membrane its product was not functionally identical to the E. coli polypeptide. In particular, the E. aerogenes OmpA protein was unable to confer sensitivity to OmpA-specific phages of E. coli. When the primary structure of the protein was deduced from the nucleotide sequence of its gene it was found that three domains differed extensively from the corresponding regions of the E. coli protein. As two of these are known to be exposed on the cell surface we inferred that these alterations are responsible for differences in the biological activity of the two proteins.     

A naturally occurring novel allele of Escherichia coli outer membrane protein A reduces sensitivity to bacteriophage

A novel Escherichia coli outer membrane protein A (OmpA) was discovered through a proteomic investigation of cell surface proteins. DNA polymorphisms were localized to regions encoding the protein's surface-exposed loops which are known phage receptor sites. Bacteriophage sensitivity testing indicated an association between bacteriophage resistance and isolates having the novel ompA allele.     

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.     

A Naturally Occurring Novel Allele of Escherichia coli Outer Membrane Protein A Reduces Sensitivity to Bacteriophage

A novel Escherichia coli outer membrane protein A (OmpA) was discovered through a proteomic investigation of cell surface proteins. DNA polymorphisms were localized to regions encoding the protein's surface-exposed loops which are known phage receptor sites. Bacteriophage sensitivity testing indicated an association between bacteriophage resistance and isolates having the novel ompA allele.     

DNA sequence analysis of the Serratia marcescens ompA gene: implications for the organisation of an enterobacterial outer membrane protein

Summary The cloned ompA gene from Serratia marcescens was fully expressed in Escherichia coli and its product correctly assembled into the outer membrane. The S. marcescens polypeptide was not functionally equivalent to the E. coli OmpA protein, which serves as a phage receptor and as a component of several colincin uptake systems. DNA sequence analysis of the gene showed that three regions of the protein likely to be exposed on the cell surface not only differed extensively from the corresponding regions of the E. coli polypeptide but also from all other sequenced OmpA proteins. It is suggested that this sequence polymorphism represents a safety mechanism by which the various enterobacterial species can avoid cross-infection by noxious agents such as phages or colicins.     

The nature of information, required for export and sorting, present within the outer membrane protein OmpA of Escherichia coli K-12.

Information, in addition to that provided by signal sequences, for translocation across the plasma membrane is thought to be present in exported proteins of Escherichia coli. Such information must also exist for the localization of such proteins. To determine the nature of this information, overlapping inframe deletions have been constructed in the ompA gene which codes for a 325-residue major outer membrane protein. In addition, one deletion, encoding only the NH2-terminal part of the protein up to residue 160, was prepared. The location of each product was determined by immunoelectron microscopy. Proteins missing residues 4-45, 43-84, 46-227, 86-227 or 160-325 of the mature protein were all efficiently translocated across the plasma membrane. The first two proteins were found in the outer membrane, the others in the periplasmic space. It has been proposed that export and sorting signals consist of relatively small amino acid sequences near the NH2 terminus of an outer membrane protein. On the basis of sequence homologies it has also been suggested that such proteins possess a common sorting signal. The locations of the partially deleted proteins described here show that a unique export signal does not exist in the OmpA protein. The proposed common sorting signal spans residues 1-14 of OmpA. Since this region is not essential for routing the protein, the existence of a common sorting signal is doubtful. It is suggested that information both for export (if existent) and localization lies within protein conformation which for the former process should be present repeatedly in the polypeptide.     

Dihydrofolate reductase (mouse) and beta-galactosidase (Escherichia coli) can be translocated across the plasma membrane of E. coli

Hybrid genes were constructed. One, ompA153-dfr, encoded the precursor of the 325 residue Escherichia coli outer membrane protein OmpA up to residue 153 which was fused to the complete 186-residue dihydrofolate reductase of the mouse. The other, ompA219-lacZ, coded for the same precursor up to residue 219 which was fused to 1017 COOH-terminal residues of the 1023-residue subunit of the beta-galactosidase of E. coli. Full expression of the ompA153-dfr gene caused accumulation of its precursor and of that of the chromosomally encoded OmpA protein. When the amount of product was reduced, no pro-OmpA and very little pro-hybrid protein accumulated. The precursor was processed and the mature protein was fully accessible to trypsin in permeabilized cells. Expression of the ompA219-lacZ gene led to the presence of the hybrid protein at only 20-30% of the amount expected. About 20% of it appeared to be incorporated in the outer membrane. All of the hybrid was quantitatively accessible to trypsin in permeabilized cells. When the hybrid gene was overexpressed, the protein was found associated with the plasma membrane in the cytosol. It is concluded that both beta-galactosidase and dihydrofolate reductase could quantitatively traverse the plasma membrane, provided the amounts synthesized were sufficiently small.     

Immunochemical characterization of the outer membrane complex of Serratia marcescens and identification of the antigens accessible to antibodies on the cell surface

Serratia marcescens New CDC O14:H12 contains major outer membrane proteins of 43.5 kDal, 42 kDal (the porins) and 38 kDal (the OmpA protein) which can be separated by sodium dodecyl sulphate-polyacrylamide gel electrophoresis. Immunoblotting of whole cell or outer membrane preparations using antiserum raised against the whole cells revealed similar complex patterns of antigens. The OmpA protein was the major immunogen, although six other outer membrane proteins were also detected; the porins reacted only weakly with antibodies in this system. Immunoabsorption of antisera with whole cells showed that only the O antigenic chains of lipopolysaccharide and the H (flagella) antigens were accessible to antibody on the cell surface. Failure to detect the OmpA protein and other envelope antigens in this way suggests that their antigenic sites are not able to react with antibodies and are possibly masked by the O antigen.