A defined mutation in the protein export gene within the spc ribosomal protein operon of Escherichia coli: isolation and characterization of a new temperature-sensitive secY mutant.

We describe the properties of a temperature-sensitive mutant, ts24, of Escherichia coli. The mutant has a conditional defect in export of periplasmic and outer membrane proteins. At 42 degrees C, precursor forms of these proteins accumulate within the cell where they are protected from digestion by externally added trypsin. The accumulated precursors are secreted and processed very slowly at 42 degrees C. The mutation is complemented by expression of the wild-type secY (or prlA) gene, which has been cloned into a plasmid vector from the promoter-distal part of the spc ribosomal protein operon. The mutant has a single base change in the middle of the secY gene, which would result in the replacement of a glycine residue by aspartic acid in the protein product. These results demonstrate that the gene secY (prlA) is essential for protein translocation across the E. coli cytoplasmic membrane.     

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.     

An outer membrane protein (OmpA) of Escherichia coli K-12 undergoes a conformational change during export

Pulse-chase experiments were performed to follow the export of the Escherichia coli outer membrane protein OmpA. Besides the pro-OmpA protein, which carries a 21-residue signal sequence, three species of ompA gene products were distinguishable. One probably represented an incomplete nascent chain, another the mature protein in the outer membrane, and the third, designated imp-OmpA (immature processed), a protein which was already processed but apparently was still associated with the plasma membrane. The pro- and imp-OmpA proteins could be characterized more fully by using a strain overproducing the ompA gene products; pro- and imp-OmpA accumulated in large amounts. It could be shown that the imp- and pro-OmpA proteins differ markedly in conformation from the OmpA protein. The imp-OmpA, but not the pro-OmpA, underwent a conformational change and gained phage receptor activity upon addition of lipopolysaccharide. Utilizing a difference in detergent solubility between the two polypeptides and employing immunoelectron microscopy, it could be demonstrated that the pro-OmpA protein accumulated in the cytoplasm while the imp-OmpA was present in the periplasmic space. The results suggest that the pro-OmpA protein, bound to the plasma membrane, is processed, and the resulting imp-OmpA, still associated with the plasma membrane, recognizes the lipid A moiety of the lipopolysaccharide. The resulting conformational change may then force the protein into the outer membrane.     

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.     

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.     

Alterations to the signal peptide of an outer membrane protein (OmpA) of Escherichia coli K-12 can promote either the cotranslational or the posttranslational mode of processing

The signal sequence of the precursor of the Escherichia coli outer membrane protein OmpA was altered by oligonucleotide insertions into the corresponding gene. In one case, OmpA-S1, the hydrophobic core of the signal peptide, is reduced from 12 to 10 residues, and one positive charge is added near the NH2-terminus. In another case, OmpA-P1, the hydrophobic core is extended from 12 to 16 residues. The pro-OmpA protein is normally processed partially co- and partially posttranslationally. Processing of the pro-OmpA-S1 protein was entirely posttranslational and that of the pro-OmpA-P1 protein strictly cotranslational. Evidence is presented which strongly suggests that posttranslational processing reflects posttranslational translocation across the plasma membrane. The generation times of cells expressing pro-OmpA-P1 or pro-OmpA-S1 were identical and the pro-OmpA-S1 polypeptide could be chased into the mature protein in the absence of protein synthesis. Hence, it does not matter which mode of processing, or rather translocation, is used. The same oligonucleotides were inserted into the ompA gene of plasmid pRD87; a plasmid which leads to overproduction of the protein and to massive accumulation of both the mature protein and the precursor. In the OmpA signal sequence encoded by pRD87-P2 the hydrophobic core is extended from 12 to 20 residues. This peptide was also rapidly removed. Therefore, regardless of whether the hydrophobic core contains 12, 16, or 20 lipophilic residues, not only does the signal sequence always function correctly to mediate export, but in each case, the cleavage site is always accessible to the signal peptidase.     

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.     

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

We studied whether information required for export is present within the mature form of the Escherichia coli 325-residue outer membrane protein OmpA. We had previously analyzed overlapping internal deletions in the ompA gene, and the results allowed us to conclude that if such information exists it must be present repeatedly within the membrane part of the protein encompassing amino acid residues 1 to 177 (R. Freudl, H. Schwarz, M. Klose, N. R. Movva, and U. Henning, EMBO J. 4:3593-3598, 1985). A deletion which removed the codons for amino acid residues 1 to 229 of the OmpA protein was constructed. In this construct the signal sequence was fused to the periplasmic part of the protein. The resulting protein, designated Pro-OmpA delta 1-229, was processed, and the mature 95-residue protein accumulated in the periplasm. Hence, information required for export does not exist within the OmpA protein.     

Effects of antibiotics and other inhibitors on ATP-dependent protein translocation into membrane vesicles.

The effects of several membrane antibiotics and other agents on ATP-dependent protein translocation were examined in membrane vesicles under conditions where no significant proton motive force was present. The membrane perturbants ethanol and procaine abolished ATP-dependent protein translocation. Phenethyl alcohol at low concentrations abolished translocation, whereas at high concentrations it allowed precursors to be translocated but inhibited their processing. Translocation of precursors promoted by phenethyl alcohol was temperature dependent and occurred without an added energy source but was enhanced by ATP. However, such precursors could not be further processed to mature forms upon removal of the alcohol. The membrane-active antibiotics polymyxin B and gramicidin S were strong inhibitors of translocation, whereas gramicidin D, cerulenin, and mycobacillin had no effect even at higher concentrations, indicating some specificity in interference with protein translocation. Duramycin, an antibiotic previously shown to affect protein-lipid interaction, severely impaired protein translocation. These results showed that membrane structures play important roles, either directly or indirectly, in protein translocation. Chelating agents 1,10-phenanthroline and EDTA, but not EGTA [ethylene glycol-bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid], also abolished protein translocation.     

Protein Secretion and Membrane Insertion Systems in Gram-Negative Bacteria

In contrast to other organisms, gram-negative bacteria have evolved numerous systems for protein export. Eight types are known that mediate export across or insertion into the cytoplasmic membrane, while eight specifically mediate export across or insertion into the outer membrane. Three of the former secretory pathway (SP) systems, type I SP (ISP, ABC), IIISP (Fla/Path) and IVSP (Conj/Vir), can export proteins across both membranes in a single energy-coupled step. A fourth generalized mechanism for exporting proteins across the two-membrane envelope in two distinct steps (which we here refer to as type II secretory pathways [IISP]) utilizes either the general secretory pathway (GSP or Sec) or the twin-arginine targeting translocase for translocation across the inner membrane, and either the main terminal branch or one of several protein-specific export systems for translocation across the outer membrane. We here survey the various well-characterized protein translocation systems found in living organisms and then focus on the systems present in gram-negative bacteria. Comparisons between these systems suggest specific biogenic, mechanistic and evolutionary similarities as well as major differences.     

Protein secretion and membrane insertion systems in gram-negative bacteria

In contrast to other organisms, gram-negative bacteria have evolved numerous systems for protein export. Eight types are known that mediate export across or insertion into the cytoplasmic membrane, while eight specifically mediate export across or insertion into the outer membrane. Three of the former secretory pathway (SP) systems, type I SP (ISP, ABC), IIISP (Fla/Path) and IVSP (Conj/Vir), can export proteins across both membranes in a single energy-coupled step. A fourth generalized mechanism for exporting proteins across the two-membrane envelope in two distinct steps (which we here refer to as type II secretory pathways [IISP]) utilizes either the general secretory pathway (GSP or Sec) or the twin-arginine targeting translocase for translocation across the inner membrane, and either the main terminal branch or one of several protein-specific export systems for translocation across the outer membrane. We here survey the various well-characterized protein translocation systems found in living organisms and then focus on the systems present in gram-negative bacteria. Comparisons between these systems suggest specific biogenic, mechanistic and evolutionary similarities as well as major differences.     

Export and sorting of theEscherichia 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 ofEscherichia 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 importantin 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 -sheet conformation. At least the structure of the last -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 -strand initiates folding and assembly in the outer membrane.     

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.     

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.     

Synthesis of OmpA protein of Escherichia coli K12 in Bacillus subtilis

We have inserted a C-terminally truncated gene of the major outer membrane protein OmpA of Escherichia coli downstream from the promoter and signal sequence of the secretory alpha-amylase of Bacillus amyloliquefaciens in a secretion vector of Bacillus subtilis. B. subtilis transformed with the hybrid plasmid synthesized a protein that was immunologically identified as OmpA. All the protein was present in the particulate fraction. The size of the protein compared to the peptide synthesized in vitro from the same template indicated that the alpha-amylase derived signal peptide was not removed; this was verified by N-terminal amino acid sequence determination. The lack of cleavage suggests that there was little or no translocation of OmpA protein across the cytoplasmic membrane. This is an unexpected difference compared with periplasmic proteins, which were both secreted and processed when fused to the same signal peptide. A requirement of a specific component for the export of outer membrane proteins is suggested.     

ΔμH+ dependency of in vitro protein translocation into Escherichia coli inner-membrane vesicles varies with the signal-sequence core-region composition

Signal sequences frequently contain α-helix-destabilizing amino acids in the hydrophobic core. Nuclear magnetic resonance studies on the conformation of signal sequences in membrane mimetic environments revealed that these residues cause a break in the α-helix. In the precursor of the Escherichia coli outer membrane protein PhoE (pre-PhoE), a glycine residue at position -10 (Gly^?10) is thought to be responsible for the break in the α-helix. We investigated the role of this glycine residue in the translocation process by employing site-directed mutagenesis. SDS-PAGE analysis showed drastic variations in the electrophoretic mobilities of the mutant precursor proteins, suggesting an important role of the glycine residue in determining the conformation of the signal sequence. In vivo, no drastic differences in the translocation kinetics were observed as compared with wild-type PhoE, except when a charged residue (Arg) was substituted for Gly^?10. However, the in vitro translocation of all mutant proteins into inverted inner-membrane vesicles was affected. Two classes of precursors could be distinguished. Translocation of one class of mutant proteins (Ala, Cys and Leu for Gly^?10) was almost independent of the presence of a ΔμH⁺, whereas translocation of the other class of precursors (wild type or Ser) was strongly decreased in the absence of the ΔμH⁺. Apparently, the ΔμH⁺ dependency of in vitro protein translocation varies with the signal-sequence core-region composition. Furthermore, a proline residue at position -10 resulted in a signal sequence that did not prevent the folding of the precursor in an in vitro trimerization assay.     

Protein transport into mitochondria is conserved between plant and yeast species

Protein targeting into plant mitochondria was investigated by in vitro translocation experiments. The precursor of the mitochondrial F1-ATPase beta subunit from Nicotiana plumbaginifolia was synthesized in vitro, translocated to, processed, and assembled in purified Vicia faba mitochondria. Transport (but not binding) required a membrane potential and external nucleotides and was conserved among plant species. beta subunit precursors from the yeasts Saccharomyces cerevisiae and Schizosaccharomyces pombe were imported and correctly processed in plant mitochondria. This translocation used protease-sensitive components of the outer membrane. Conversely, the N. plumbaginifolia beta subunit precursor was efficiently translocated and cleaved in yeast mitochondria. However, a precursor for a chloroplast protein was not targeted to plant or yeast mitochondria. We conclude that the machinery for protein import into mitochondria is specific and conserved in plant and yeast organisms. These results are discussed in the context of a poly- or monophyletic origin of mitochondria.     

Expression of the pspA gene stimulates efficient protein export in Escherichia coli

Expression of several mutant forms of outer membrane protein PhoE of Escherichia coli, which are disturbed in normal biogenesis, resulted in high expression of a 26kDa protein. This 26kDa protein fractionated as a peripherally bound inner membrane protein. It appeared to be identical to a previously identified protein (PspA = phage shock protein A) of unknown function that is induced upon infection of E. coli with filamentous phages. PspA was not expressed upon synthesis of mutant PhoE proteins in a secB mutant, nor upon expression of a PhoE mutant that lacks the signal sequence, suggesting that entrance into the export pathway of prePhoE is essential for induction. PspA synthesis was also induced under other conditions that are known to block the export apparatus, i.e. in secA, secD and secF mutants when grown at their non-permissive temperature or upon induction of the synthesis of MalE-LacZ or LamB-LacZ hybrid proteins. The inducing conditions for PspA synthesis suggested a rote for this protein in export. In vivo pulse-chase experiments showed that the translocation of (mutant) prePhoE and of the precursors of other exported proteins was retarded in a pspA mutant strain. Also, in in vitro translocation assays, a role for PspA in protein transport could be demonstrated.