The signal sequence suffices to direct export of outer membrane protein OmpA of Escherichia coli K-12

Evolutionary Engineering a Larger Porin Using a Loop-to-Hairpin Mechanism

In protein evolution, diversification is generally driven by genetic duplication. The hallmarks of this mechanism are visible in the repeating topology of various proteins. In outer membrane β-barrels, duplication is visible with β-hairpins as the repeating unit of the barrel. In contrast to the overall use of duplication in diversification, a computational study hypothesized evolutionary mechanisms other than hairpin duplications leading to increases in the number of strands in outer membrane β-barrels. Specifically, the topology of some 16- and 18-stranded β-barrels appear to have evolved through a loop to β-hairpin transition. Here we test this novel evolutionary mechanism by creating a chimeric protein from an 18-stranded β-barrel and an evolutionarily related 16-stranded β-barrel. The chimeric combination of the two was created by replacing loop L3 of the 16-stranded barrel with the sequentially matched transmembrane β-hairpin region of the 18-stranded barrel. We find the resulting chimeric protein is stable and has characteristics of increased strand number. This study provides the first experimental evidence supporting the evolution through a loop to β-hairpin transition.

Evolutionary engineering a larger porin using a loop-to-hairpin mechanism

In protein evolution, diversification is generally driven by genetic duplication. The hallmarks of this mechanism are visible in the repeating topology of various proteins. In outer membrane β-barrels, duplication is visible with β-hairpins as the repeating unit of the barrel. In contrast to the overall use of duplication in diversification, a computational study hypothesized evolutionary mechanisms other than hairpin duplications leading to increases in the number of strands in outer membrane β-barrels. Specifically, the topology of some 16- and 18-stranded β-barrels appear to have evolved through a loop to β-hairpin transition. Here we test this novel evolutionary mechanism by creating a chimeric protein from an 18-stranded β-barrel and an evolutionarily related 16-stranded β-barrel. The chimeric combination of the two was created by replacing loop L3 of the 16-stranded barrel with the sequentially matched transmembrane β-hairpin region of the 18-stranded barrel. We find the resulting chimeric protein is stable and has characteristics of increased strand number. This study provides the first experimental evidence supporting the evolution through a loop to β-hairpin transition.

Highlights

We find evidence supporting a novel diversification mechanism in membrane β-barrelsThe mechanism is the conversion of an extracellular loop to transmembrane β-hairpinA chimeric protein modeling this mechanism folds stably in the membraneThe chimera has more β-structure and a larger pore, consistent with a loop-to-hairpin transition.

Specificity of signal peptide recognition in tat-dependent bacterial protein translocation

The bacterial twin arginine translocation (Tat) pathway translocates across the cytoplasmic membrane folded proteins which, in most cases, contain a tightly bound cofactor. Specific amino-terminal signal peptides that exhibit a conserved amino acid consensus motif, S/T-R-R-X-F-L-K, direct these proteins to the Tat translocon. The glucose-fructose oxidoreductase (GFOR) of Zymomonas mobilis is a periplasmic enzyme with tightly bound NADP as a cofactor. It is synthesized as a cytoplasmic precursor with an amino-terminal signal peptide that shows all of the characteristics of a typical twin arginine signal peptide. However, GFOR is not exported to the periplasm when expressed in the heterologous host Escherichia coli, and enzymatically active pre-GFOR is found in the cytoplasm. A precise replacement of the pre-GFOR signal peptide by an authentic E. coli Tat signal peptide, which is derived from pre-trimethylamine N-oxide (TMAO) reductase (TorA), allowed export of GFOR, together with its bound cofactor, to the E. coli periplasm. This export was inhibited by carbonyl cyanide m-chlorophenylhydrazone, but not by sodium azide, and was blocked in E. coli tatC and tatAE mutant strains, showing that membrane translocation of the TorA-GFOR fusion protein occurred via the Tat pathway and not via the Sec pathway. Furthermore, tight cofactor binding (and therefore correct folding) was found to be a prerequisite for proper translocation of the fusion protein. These results strongly suggest that Tat signal peptides are not universally recognized by different Tat translocases, implying that the signal peptides of Tat-dependent precursor proteins are optimally adapted only to their cognate export apparatus. Such a situation is in marked contrast to the situation that is known to exist for Sec-dependent protein translocation.

Channel formation by FhaC, the outer membrane protein involved in the secretion of the Bordetella pertussis filamentous hemagglutinin

Many virulence factors of pathogenic microorganisms are presented at the cell surface. However, protein secretion across the outer membrane of Gram-negative bacteria remains poorly understood. Here we used the extremely efficient secretion of the Bordetella pertussis filamentous hemagglutinin (FHA) to decipher this process. FHA secretion requires a single specific accessory protein, FhaC, the prototype of a family of proteins necessary for the extracellular localization of various virulence proteins in Gram-negative bacteria. We show that FhaC is heat-modifiable and localized in the outer membrane. Circular dichroism spectra indicated that FhaC is rich in beta-strands, in agreement with structural predictions for this protein. We further demonstrated that FhaC forms pores in artificial membranes, as evidenced by single-channel conductance measurements through planar lipid bilayers, as well as by liposome swelling assays and patch-clamp experiments using proteoliposomes. Single-channel conductance appeared to fluctuate very fast, suggesting that the FhaC channels frequently assume a closed conformation. We thus propose that FhaC forms a specific beta-barrel channel in the outer membrane for the outward translocation of FHA.

The major outer membrane protein of Haemophilus ducreyi consists of two OmpA homologs

The major outer membrane protein (MOMP) of Haemophilus ducreyi is an OmpA homolog that migrates on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) gels as three species with apparent molecular weights ranging from 37,000 to 43,000. Monoclonal antibodies directed against this macromolecule were used to identify recombinant clones containing fragments of the gene encoding this protein. Nucleotide sequence analysis of these fragments confirmed that the MOMP encoded by the intact gene (momp) was a member of the OmpA family of outer membrane proteins. Construction of an isogenic H. ducreyi mutant unable to express the MOMP led to the discovery of a second outer membrane protein which migrated at the same rate on SDS-PAGE gels as the MOMP. N-terminal amino acid sequence analysis of this second protein revealed that its N terminus was nearly identical to that of the MOMP and also had homology with members of the OmpA family. Nucleotide sequence analysis of the region downstream from the momp gene revealed the presence of a partial open reading frame encoding a predicted OmpA-like protein. A modification of anchored PCR technology was used to obtain the nucleotide sequence of this downstream gene which was shown to encode a second OmpA homolog (OmpA2). The N-terminal amino acid sequence of OmpA2 was identical to that of the OmpA-like protein detected in the momp mutant. The H. ducreyi MOMP and OmpA2 proteins, which comigrated on SDS-PAGE gels and which were encoded by the tandem arranged momp and ompA2 genes, were 72% identical.

A periplasmic protein (Skp) of Escherichia coli selectively binds a class of outer membrane proteins

A search was performed for a periplasmic molecular chaperone which may assist outer membrane proteins of Escherichia coli on their way from the cytoplasmic to the outer membrane. Proteins of the periplasmic space were fractionated on an affinity column with sepharose-bound outer membrane porin OmpF. A 17 kDa polypeptide was the predominant protein retained by this column. The corresponding gene was found in a gene bank; it encodes the periplasmic protein Skp. The protein was isolated and it could be demonstrated that it bound outer membrane proteins, following SDS-PAGE, with high selectivity. Among these were OmpA, OmpC, OmpF and the maltoporin LamB. The chromosomal skp gene was inactivated by a deletion causing removal of most of the signal peptide plus 107 residues of the 141-residue mature protein. The mutant was viable but possessed much-reduced concentrations of outer membrane proteins. This defect was fully restored by a plasmid-borne skp gene which may serve as a periplasmic chaperone.

Treponema pallidum in gel microdroplets: a novel strategy for investigation of treponemal molecular architecture

Controversy exists regarding the constituents and antigenic properties of the Treponema pallidum outer membrane; a major point of contention concerns the cellular location(s) of the spirochaete's lipoprotein immunogens. To address these issues and circumvent problems associated with prior efforts to localize treponemal surface antigens, we developed a novel strategy for investigating T. pallidum molecular architecture. Virulent treponemes were encapsulated in porous agarose beads (gel microdroplets) and then probed in the presence or absence of Triton X-100. Intact, encapsulated treponemes were not labelled by monospecific antisera directed against four major T. pallidum lipoproteins or a candidate T. pallidum outer membrane protein (TpN50) with C-terminal sequence homology to Escherichia coli OmpA or by human or rabbit syphilitic serum. Each of these immunologic reagents, however, labelled encapsulated treponemes co-incubated with detergent. In contrast, antibodies generated against isolated T. pallidum outer membranes labelled intact organisms and the pattern of fluorescence was consistent with the distribution of rare outer membrane proteins visualized by freeze-fracture electron microscopy. In addition to providing strong evidence that the protein portions of treponemal lipoproteins are located within the periplasmic space, these studies have extended our understanding of the topographical relationships among T. pallidum cell envelope constituents. They also demonstrate the feasibility of generating antibodies against rare outer membrane proteins and detecting them on the surfaces of virulent treponemes.

The mutL repair gene of Escherichia coli K-12 forms a superoperon with a gene encoding a new cell-wall amidase

We report a molecular genetic analysis of the region immediately upstream from the Escherichia coli mutL DNA repair gene at 94.8 min. An open reading frame ending 9 bp upstream from the start of mutL corresponds to a 48 kDa polypeptide detected previously in minicells. The predicted amino acid sequence of this 48 kDa polypeptide shows homology to the major N-acetylmuramoyl-L-alanine amidase autolysin of Bacillus subtilis, a known amidase of Bacillus licheniformis, and the product of a Salmonella typhimurium gene that maps near 50 min. Insertions in this upstream gene, which we named amiB, or in mutL did not affect cell shape or viability; however, overexpression of the AmiB polypeptide caused cell lysis, hypersensitivity to osmotic shock and treatment with water, and temporary autolysis by low levels of antibiotics, which are all consistent with AmiB acting as a cell-wall hydrolase. Analysis of chromosomal transcription demonstrated that amiB forms a complex operon with mutL and two additional upstream genes. mutL transcripts also originated from an internal promoter, designated PmutL, located in amiB 312 bp upstream from the translational start of mutL. Together, these results suggest that E. coli contains a second amidase possibly involved in cell-wall hydrolysis, septation, or recycling, and that transcription of this amidase is directly linked to a gene central for DNA repair.

Location and unusual membrane topology of the immunity protein of the Escherichia coli phage T4

The immunity protein (Imm) encoded by the Escherichia coli phage T4 effects exclusion of phage superinfecting cells already infected with T4. The 83-residue polypeptide possesses two long lipophilic areas (from residues 3 to 32 and 37 to 65) interrupted by a hydrophilic stretch including two positively charged residues. The charge distribution of the protein very strongly suggested that it is a plasma membrane protein with the C terminus facing the periplasm. While it could be shown that the expected location was correct, fusions of Imm to alkaline phosphatase or beta-galactosidase showed that the C terminus was at the cytosolic side of the membrane. Also, concerning function, there was almost no structural specificity to this part of the protein. Even removal of the two positively charged residues did not completely abolish function. Evidence suggesting that Imm is associated with the membrane at specific sites is presented. It is proposed that Imm is localized to the membrane with the help of a receptor and that, therefore, it does not follow the established rules for the topology of other membrane proteins. The results also suggest that Imm acts indirectly, possibly by altering the conformation of a component of a phage DNA injection site.

Differentiation of lactococci by rRNA gene restriction analysis

Strains of the subspecies of Lactococcus lactis could be differentiated by rRNA gene restriction fragment length polymorphisms (RFLP). 16S rRNA-specific oligonucleotide as well as polynucleotide DNA probes were used for the detection of restriction fragments. In addition, a site-specific probe was designed for the intergenic spacer region of 23S and 5S rRNA genes. For all lactococcal strains the putative presence of six rRNA operons was confirmed. A non-radioactive hybridization assay was used based on hybrid detection by chemiluminescence. Specific patterns were found for any of the strains investigated. Subspecies-specific restriction fragments could be identified in addition to the strain-specific patterns.

Surface expression of malarial antigens in Salmonella typhimurium: induction of serum antibody response upon oral vaccination of mice

The Escherichia coli OmpA protein can serve as a carrier for the expression of foreign antigens on the surface of gram-negative bacteria. Employing OmpA vectors, immunogenic moieties of the Plasmodium falciparum blood stage antigens SERP and HRPII have been expressed in the attenuated Salmonella typhimurium SR-11 strain. Upon induction, the malaria specific sequences of 189 (HRPII) and 451 (SERP) amino acids, fused into the OmpA protein, have been expressed. By indirect immunofluorescence studies, live bacteria expressing the fusion proteins react anti-SERP and anti-HRPII sera, respectively, indicating that the hybrid OmpA proteins become integrated into the bacterial outer membrane and expose the malarial antigens at the exterior surface. Mice that were immunized orally with S. typhimurium cells expressing HRPII and SERP on their surface show a humoral immune response as determined by the anti-SERP and anti-HRPII IgG and IgM titres. From these experiments it can be concluded that the OmpA surface expression system in combination with established Salmonella vaccine strains can be used to efficiently deliver large antigens to the mucosal immune system.

Requirement of the SecB chaperone for export of a non-secretory polypeptide in Escherichia coli

The SecB protein of Escherichia coli is a cytosolic component of the export machinery which can prevent some precursors from prematurely folding into export-incompatible conformations by binding to the newly synthesised polypeptide. The feature(s) of target proteins recognised by SecB, however, are unclear and have been a matter of controversy. Also, it has not been asked if binding of SecB is specific for secretory proteins. We demonstrate here that a non-secretory polypeptide, a fragment of a tail fiber protein of phage T4, fused to the signal peptide of the outer membrane protein OmpA has a very strong SecB requirement for export and that the signal peptide itself cannot, at least not alone, be responsible for this action of SecB. The data reported, together with those of the literature, suggest that SecB recognizes the polypeptide backbone of the target protein.

Carboxy-terminal phenylalanine is essential for the correct assembly of a bacterial outer membrane protein

Bacterial outer membrane proteins are supposed to span the membrane repeatedly, mostly in the form of amphipathic beta-sheets. The last ten C-terminal amino acid residues of PhoE protein are supposed to form such a membrane-spanning segment. Deletion of this segment completely prevents incorporation into the outer membrane. Comparison of the last ten amino acid residues of other outer membrane proteins from different Gram-negative bacteria revealed the presence of a potential amphipathic beta-sheet with hydrophobic residues at positions 1 (Phe), 3 (preferentially Tyr), 5, 7 and 9 from the C terminus, in the vast majority of these proteins. Since such sequences were not detected at the C termini of periplasmic proteins, it appears to be possible to discriminate between the majority of outer membrane proteins and periplasmic proteins on the basis of sequence data. The highly conserved phenylalanine at the C termini of outer membrane proteins suggests an important function for this amino acid in assembly into the outer membrane. Site-directed mutagenesis was applied to study the role of the C-terminal Phe in PhoE protein assembly. All mutant proteins were correctly incorporated into the outer membrane to some extent, but the efficiency of the process was severely affected. It appears that both the hydrophobicity and the aromatic nature of Phe are of importance.

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.

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.

Lipid and peptide specificities in signal peptide--lipid interactions in model membranes

The present data show the critical importance of the anionic lipid content in monomolecular layers for the interaction with PhoE signal peptide. At 37 degrees C and 100 mM NaCl the interaction is maximal at 30-40 mol% anionic lipid. The results correlate with the reduced translocation competence of Escherichia coli strain HD3122, which has a much lower anionic lipid content as compared to the wild-type strain SD12 (De Vrije et al. (1988) Nature 334, 173-175). PhoE signal peptide analogs as N-formyl PhoE signal peptide, PhoE signal peptide +(1-7) and PhoE signal peptide Val-8----Trp-8 show the same lipid preference as PhoE signal peptide. On the other hand the affinity for an anionic lipid interface is strongly reduced for PhoE signal peptide Lys-19,-20----Asp-19,-20, which correlates with the less efficient translocation of PhoE protein carrying this signal sequence. At limiting anionic lipid concentrations there is a temperature and salt effect on the observed interaction, which is related to a conformational change of the peptide. Signal sequences show clearly conformational flexibility in responds to environmental conditions. Under the conditions used in this study FTIR spectra of PhoE signal peptide-DOPG monolayers show a high content of beta-structure and beta-turn.

Export and sorting of the Escherichia coli outer membrane protein OmpA

Results of studies, mostly using the outer membrane, 325 residue protein OmpA, are reviewed which concern its translocation across the plasma membrane and incorporation into the outer membrane of Escherichia coli. For translocation, neither a unique export signal, acting in a positive fashion within the mature part of the precursor, nor a unique conformation of the precursor is required. Rather, the mature part of a secretory protein has to be export-compatible. Export-incompatibility can be caused by a stretch of 16 (but not 8 or 12) hydrophobic residues, too low a size of the polypeptide (smaller than 75 residue precursors), net positive charge at the N-terminus, or lack of a turn potential at the same site. It is not yet clear whether binding sites for chaperonins (SecB, trigger factor, GroEL) within OmpA are important in vivo. The mechanism of sorting of outer membrane proteins is not yet understood. The membrane part of OmpA, encompassing residues 1 to about 170, it thought to traverse the membrane eight times in antiparallel beta-sheet conformation. At least the structure of the last beta-strand (residues 160-170) is of crucial importance for membrane assembly. It must be amphiphilic or hydrophobic, these properties must extend over at least nine residues, and it must not contain a proline residue at or near its center. Membrane incorporation of OmpA involves a conformational change of the protein and it could be that the last beta-strand initiates folding and assembly in the outer membrane.

Export incompatibility of N-terminal basic residues in a mature polypeptide of Escherichia coli can be alleviated by optimising the signal peptide

Export of the outer membrane protein, OmpA, across the cytoplasmic membrane of Escherichia coli was severely inhibited by the presence of two, three, four or six additional basic residues at the N-terminus of the mature polypeptide, but not by three similarly positioned acidic residues. Because a few bacterial proteins do possess basic residues close to the leader peptidase cleavage site and because the type of inhibition described here could pose problems in the construction of hybrid secretory proteins, we also studied means of alleviating this form of export incompatibility. Inhibition was abolished when basic residues were preceded by acidic ones. Also, the processing rates of the mutants with two or six basic residues could be partially restored by increasing the length of the hydrophobic core of the signal peptide. Taking this as a precedent, it is suggested that the structure of the signal peptide is an important feature for maintenance of a reasonable rate of translocation of those exported proteins which possess basic residue(s) at the N-terminus of the mature polypeptide.

The role of the mature part of secretory proteins in translocation across the plasma membrane and in regulation of their synthesis in Escherichia coli

Presently available data are reviewed which concern the role of the mature parts of secretory precursor proteins in translocation across the plasma membrane of Escherichia coli. The following conclusions can be drawn; i) signals, acting in a positive fashion and required for translocation do not appear to exist in the mature polypeptides; ii) a number of features have been identified which either affect the efficiency of translocation or cause export incompatibility. These are: alpha) protein folding prior to translocation; beta) restrictions regarding the structure of N-terminus; gamma) presence of lipophilic anchors; delta) too low a size of the precursor. Efficiency of translocation is also enhanced by binding of chaperonins (SecB, trigger factor, GroEL) to precursors. Binding sites for chaperonins appear to exist within the mature parts of the precursors but the nature of these sites has remained rather mysterious. Mutant periplasmic proteins with a block in release from the plasma membrane have been described, the mechanism of this block is not known. The mature parts of secretory proteins can also be involved in the regulation of their synthesis. It appears that exported proteins are already recognized as such before they are channelled into the export pathway and that their synthesis can be feed-back inhibited at the translational level.

A lower size limit exists for export of fragments of an outer membrane protein (OmpA) of Escherichia coli K-12

The ompA gene codes for a 346 residue precursor of a 325 residue protein of the outer membrane of Escherichia coli K-12. Internally and/or COOH-terminally deleted genes were constructed that encode 123, 116, 88, 72 or 68 residue precursors. The former three were processed and localized to the periplasmic space; the latter two were not processed and remained cytosolic. These data suggest that the signal sequence has to interact with a component of the export apparatus (the Sec pathway) before translation is finished. Comparison of these results with others obtained for prokaryotic and eukaryotic systems shows that: (1) a very similar lower size limit exists for membrane translocation of the 147 residue chicken prelysozyme or the 229 residue bovine preprolactin; (2) precursors smaller than those reported here can be translocated in both systems; (3) the latter translocation, in contrast to, for example, the ompA gene products, does not depend on the cellular export machinery but most likely requires folding of the precursors into an export-competent conformation. In general, at least two quite different, not necessarily mutually exclusive, mechanisms for translocation of a protein across or assembly into a membrane appear to exist.

On the role of the mature part of an Escherichia coli outer membrane protein (OmpA) in translocation across the plasma membrane

The 325-residue OmpA protein, which is synthesized as a precursor with a 21-residue signal sequence, is a polypeptide of the outer membrane of Escherichia coli K-12. The signal peptide is able to direct translocation across the plasma membrane of virtually any fragment of this protein. It had, therefore, been concluded that information required for this translocation does not exist within the mature part of the protein. This view has been criticized and it was suggested that our data showed that both the signal sequence and residues within the first 44 amino acid residues of the mature protein contributed to an optimal translocation mechanism. It is shown that, at least as far as is detectable, this is not so. The apparent rates of processing of various pro-OmpA constructs were measured. It was found that these rates did not depend on the presence of amino acid residues 4 through 45 but on the size of the polypeptides; the processing rate decreased with decreasing size. A possible explanation for this phenomenon is offered. While the results do not exclude the possibility that a defined area of the mature protein is involved in optimizing translocation, there is so far no evidence for it.

Export of protein in Escherichia coli: a novel mutation in ompC affects expression of other major outer membrane proteins

A mutation within the ompC structural gene of Escherichia coli K-12 which affects expression of outer membrane proteins was characterized. The mutation consisted of a 6-base-pair deletion near the 3' end of the gene which removed the amino acids Val-300 and Gly-301 of the mature coding sequence but otherwise left the reading frame intact. The deletion occurred within a region highly conserved among the porins. No protein product was detected from a single copy of the mutant gene. The mutation caused a trans-dominant decrease in the expression of a wild-type ompC allele. The mutation caused a similar decrease in the amounts of OmpA, OmpF, LamB, and Lc proteins, yet it did not appear to affect the minor outer membrane proteins. It had no significant effect on transcription from either ompF or ompC promoters as measured with lacZ operon fusions. The effects of the mutation on other proteins were completely eliminated when the signal sequence was disrupted so that the mutant protein no longer interacted with the secretion machinery of the cell but instead accumulated as precursor in the cytoplasm. A model is proposed involving the translocation of proteins to the outer membrane and the importance of protein conformation in this process.

The first 28 amino acids of mature LamB are required for rapid and efficient export from the cytoplasm

Our laboratory has been utilizing the Escherichia coli outer membrane protein LamB to study the mechanism of protein localization. Various lines of evidence suggest that, in addition to a signal sequence, regions within the mature protein are required for efficient localization. In particular, studies using LamB-LacZ hybrid proteins have identified regions between amino acids 27 and 49 of mature LamB, which may play an important role in localization. To elucidate further the function of these regions, a series of in-frame deletions that remove varying lengths of early lamB sequences was constructed. The effects of these deletions on export of a large LamB-LacZ hybrid protein, 42-1, and on export of an otherwise wild-type LamB protein were determined. We find a strong correlation between the sequences deleted and the export phenotypes these deletions impart to both LamB and the LamB-LacZ42-1 hybrid protein. On the basis of these findings, the deletions can be divided into several distinct classes that define a region within mature LamB that participates in localization. This region extends amino terminally from amino acid 28 of the mature protein and functions in the rapid and efficient localization of LamB from the cytoplasm.