Precursor proteins are intermediates in vivo in the synthesis of two major outer membrane proteins, the OmpA and OmpF proteins, of Escherichia coli K12

Reduced ATP-dependent proteolysis of functional proteins during nutrient limitation speeds the return of microbes to a growth state

When cells run out of nutrients, the growth rate greatly decreases. Here, we report that microorganisms, such as the bacterium Salmonella enterica serovar Typhimurium, speed up the return to a rapid growth state by preventing the proteolysis of functional proteins by ATP-dependent proteases while in the slow-growth state or stationary phase. This reduction in functional protein degradation resulted from a decrease in the intracellular concentration of ATP that was nonetheless sufficient to allow the continued degradation of nonfunctional proteins by the same proteases. Protein preservation occurred under limiting magnesium, carbon, or nitrogen conditions, indicating that this response was not specific to low availability of a particular nutrient. Nevertheless, the return to rapid growth required proteins that mediate responses to the specific nutrient limitation conditions, because the transcriptional regulator PhoP was necessary for rapid recovery only after magnesium starvation. Reductions in intracellular ATP and in ATP-dependent proteolysis also enabled the yeast Saccharomyces cerevisiae to recover faster from stationary phase. Our findings suggest that protein preservation during a slow-growth state is a conserved microbial strategy that facilitates the return to a growth state once nutrients become available.

LamB as a carrier molecule for the functional exposition of IgG-binding domains of the Staphylococcus aureus protein A at the surface of Escherichia coli K12

One, two or four IgG-binding domains of the Staphylococcus aureus Protein A (SPA) were inserted into the LamB protein which was expressed under control of the tac promoter. The chimeric proteins were shown to be exposed at the cell surface by analysis of isolated outer membranes and also by testing their functional interaction with IgG molecules. We hereby show that the LamB protein can accept as many as 232 amino acids (four SPA domains) and still be incorporated into the Escherichia coli outer membrane, while maintaining the functional conformation of the inserted SPA polypeptides.

SDS-soluble and peptidoglycan-bound proteins in the outer membrane-peptidoglycan complex of Brucella abortus

Outer membrane-peptidoglycan complex from Brucella abortus was separated from cytoplasmic membrane and cytosol by either sucrose density gradient fractionation or differential (rate) centrifugation of surface labeled cells disrupted by sonication without the use of detergents. The outer membrane-peptidoglycan complex had a buoyant density of 1.22 gm/ml and contained 67 labeled SDS-soluble proteins when examined by SDS-PAGE. Included were four major bands exhibiting molecular masses of 88k, 40k, 35.7k and 26k daltons corresponding to previously described group 1, 2 and 3 outer membrane proteins. Lysozyme treatment of outer membrane-peptidoglycan complex increased its buoyant density to 1.25 gm/ml and released eight additional peptidoglycan-linked proteins.

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.

Immunological approach of assembly and topology of OmpF, an outer membrane protein of Escherichia coli

Various monoclonal antibodies (MoF) directed against cell-surface-exposed epitopes of OmpF, one major outer membrane pore protein of Escherichia coli B and K-12, have been used to study the assembly and the topology of the protein. This paper firstly describes the characterization of the OmpF epitopes recognized by the various monoclonal antibodies. A comparison between OmpC, OmpF and PhoE porins with respect to their primary amino acid sequence and their cell-surface exposed regions allows us to propose a rough model including 2 antigenic sites. The second part is focused on the assembly of the OmpF protein in the outer membrane. Various forms, precursor, unassembled monomer, metastable oligomer (pre-trimer) and trimer are detected with immunological probes directed against OmpF during a kinetic analysis of the process. The requirement for a concomitant lipid synthesis during the trimerization has been demonstrated by investigating the presence of a specific native epitope. The role of lipopolysaccharide during the stabilization of the conformation is discussed with regard to the various steps of assembly.

Heterologous protein export in Escherichia coli: influence of bacterial signal peptides on the export of human interleukin 1 beta

Expression plasmids carrying the coding sequence of mature human interleukin 1 beta (IL 1 beta) linked either to a Met start codon, or fused to different efficient Escherichia coli secretion signal sequences, have been constructed. In the latter case, we used signal peptides derived either from an outer membrane protein (OmpA) or from a periplasmic protein (PhoA). The synthesis of IL1 beta from these fusions was investigated in an otherwise strictly isogenic context using identical conditions of derepression and culture media. The Met-IL1 beta fusion produced a soluble cytoplasmic protein which could be released from the cells by osmotic shock whereas the OmpA and PhoA fusions were always insoluble. The extent of sOmpA-IL1 beta maturation was found to vary from 50 to 100%, mainly depending on the medium used, whereas no significant maturation of the signal peptide could be detected in the case of the sPhoA-IL1 beta fusion. Immuno-electron microscopy revealed that the sOmpA-IL1 beta fusion was targeted to the inner membrane, whereas the sPhoA-IL1 beta fusion remained within the cytoplasm and thus did not appear to enter the secretion pathway. Amplifying the E. coli signal peptidase lep gene on a multicopy plasmid did not improve signal peptide removal from sOmpA-IL1 beta. Moreover, these E. coli secretion vectors allowed us to produce, in high levels, IL1 beta fragments which otherwise could not be stably accumulated within the cytoplasmic compartment.

Assembly of the OmpF porin of Escherichia coli B. Immunological and kinetic studies of the integration pathway

The different conformations of the outer membrane protein OmpF of Escherichia coli B were studied with immunological probes. The antigenic determinants recognized by one monoclonal (MoF3) and two polyclonal antibodies were investigated under various conditions of solubilization which modify the association of OmpF with other membrane components, such as lipopolysaccharide. Several polymeric forms of the protein could be detected after extraction at 37 degrees C or 56 degrees C. The monoclonal antibody, which is specific to an exposed region of native OmpF, recognized various trimeric forms in an immunoprecipitation assay. Under the same conditions, the binding of polyclonal antibodies apparently induced strong conformational rearrangements, since the pattern of trimeric forms detected was greatly modified. The conversion of newly synthesized monomers of OmpF to the various trimer forms was investigated using these antibodies. The trimerization occurred rapidly but the appearance of the native conformation of OmpF was delayed. Some additional step was required to expose the MoF3-specific antigenic site at the surface of the trimeric form. These results are discussed in relation to the structure of OmpF and its association with lipopolysaccharide in the outer membrane.

The fadL gene product of Escherichia coli is an outer membrane protein required for uptake of long-chain fatty acids and involved in sensitivity to bacteriophage T2

The fadL+ gene of Escherichia coli encodes an outer membrane protein (FadL) essential for the uptake of long-chain fatty acids (C12 to C18). The present study shows that in addition to being required for uptake of and growth on the long-chain fatty acid oleate (C18:1), FadL acts as a receptor of bacteriophage T2. Bacteriophage T2-resistant (T2r) strains lacked FadL and were unable to take up and grow on long-chain fatty acids. Upon transformation with the fadL+ clone pN103, T2r strains became sensitive to bacteriophage T2 (T2s), became able to take up long-chain fatty acids at wild-type levels, and contained FadL in the outer membrane.

Nucleotide sequencing and expression of the fadL gene involved in long-chain fatty acid transport in Escherichia coli

The fadL gene of Escherichia coli codes for an outer membrane protein involved in long-chain fatty acid transport. Its product was purified from outer membrane proteins. We determined the nucleotide sequence of a 2.8-kb chromosomal DNA segment that contains the fadL gene. The fadL gene consists of a 1149-nucleotide coding region and contains a highly hydrophobic polypeptide of 383 amino acids with a calculated molecular weight of 42,380. We have used S1-mapping analysis to identify the transcription initiation site. A region exhibiting extensive dyad symmetry and perfect homology to the catabolite activator protein binding site was detected.

Intermediates in the assembly of the TonA polypeptide into the outer membrane of Escherichia coli K12

The tonA gene of Escherichia coli K12 was cloned into a multicopy plasmid, leading to substantial overproduction of the corresponding 78,000 Mr polypeptide in the outer membrane. The approximate size of the tonA gene and its direction of transcription were established by Tn1000 mutagenesis. A family of tonA deletions was constructed in vitro by Bal31 exonuclease digestion, followed by splicing of an "oligo stop" sequence to each 3' terminus in order to ensure prompt termination of translation of the truncated polypeptides in vivo. All these polypeptides proved to be extremely unstable in exponentially growing cultures but were relatively stable in maxicells. Under these conditions the truncated polypeptides, unlike wild-type TonA, fractionated with the Sarkosyl-soluble fraction of the cell envelope, indicating that these proteins are blocked in assembly as inner membrane (translocation) intermediates or as outer membrane (maturation) intermediates unable to form Sarkosyl-resistant complexes. We have also examined the kinetics of assembly of wild-type TonA into the outer membrane and the results indicate that, following cleavage of the N-terminal signal peptide, the protein passes through an apparently membrane-free intermediate form and only appears in the outer membrane after a delay of at least 50 seconds, following the completion of synthesis. From these results, we propose that the assembly of TonA involves translocation (with concomitant cleavage of the signal sequence) directly into the periplasm, followed by partitioning into the outer membrane. We further propose that the C terminus of TonA is essential for final maturation in the outer membrane in Sarkosyl-resistant form but that the C-terminal half of the molecule probably does not contain any topogenic sequences required for partitioning to the outer membrane.

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.

Selection for mutants altered in the expression or export of outer membrane porin OmpF

Strains in which the lacZ gene (which specifies beta-galactosidase) is fused to a gene encoding an envelope protein often exhibit a phenotype termed overproduction lethality. In such strains, high-level synthesis of the cognate hybrid protein interferes with the process of protein export, and this leads ultimately to cell death. A variation of this phenomenon has been discovered with lacZ fusions to the gene specifying the major outer membrane porin protein OmpF. In this case, we find that lambda transducing phage carrying an ompF-lacZ fusion will not grow on a host strain that constitutively overexpresses ompF. We have exploited this observation to develop a selection for ompF mutants. Using this protocol, we have isolated mutants altered in ompF expression and have identified mutations that block OmpF export. Our results suggest that it should be possible to adapt this selection for use with other genes specifying exported proteins.

Porin from bacterial and mitochondrial outer membranes

The outer membrane of gram-negative bacteria acts as a molecular filter with defined exclusion limit for hydrophilic substances. The exclusion limit is dependent on the type of bacteria and has for enteric bacteria like Escherichia coli and Salmonella typhimurium a value between 600 and 800 Daltons, whereas molecules with molecular weights up to 6000 can penetrate the outer membrane of Pseudomonas aeruginosa. The molecular sieving properties result from the presence of a class of major proteins called porins which form trimers of identical subunits in the outer membrane. The porin trimers most likely contain only one large but well-defined pore with a diameter between 1.2 and 2 nm. Mitochondria are presumably descendents of gram-negative bacteria. The outer membrane of mitochondria contains in agreement with this hypothesis large pores which are permeable for hydrophilic substances with molecular weights up to 6000. The mitochondrial porins are processed by the cell and have molecular weights around 30,000 Daltons. There exists some evidence that the pore is controlled by electric fields and metabolic processes.

In vitro translocation of bacterial proteins across the plasma membrane of Escherichia coli

Precursors to two periplasmic proteins and one outer membrane protein were synthesized in a membrane-free extract from Escherichia coli programmed with plasmid DNA. In the presence of inverted plasma membrane vesicles from E. coli up to 25% of the precursor molecules were converted into their mature forms. Using externally added proteinase K as a probe, we found the processed proteins segregated within the membrane vesicles. By the same criteria, a small amount of each precursor also proved to be translocated, indicating that translocation and signal sequence cleavage are not necessarily coupled processes. Furthermore, we present conclusive evidence that the translocation step can occur post-translationally even as late as 60 min after the beginning of translation.

Intragenic regions required for LamB export

Escherichia coli strains containing a series of lamB-lacZ fusions have been isolated and characterized. Each of these fusions specifies a hybrid protein with LamB sequences at the NH2 terminus and a large functional COOH-terminal fragment of beta-galactosidase. The amount of LamB present in the various hybrid proteins ranges from as few as 4 amino acids to a complete signal sequence (25 amino acids) plus 49 amino acids of the mature protein. With respect to hybrid protein export these fusions fall into three classes. Hybrid proteins with an incomplete LamB signal sequence or those that have a complete signal sequence plus 27 or fewer amino acids of the mature LamB protein are not exported and remain in the cytoplasm. In contrast, fusion strains attempt to export hybrid proteins that contain a complete signal sequence plus 39 or 43 amino acids of mature LamB. However, these proteins are not localized to the outer membrane. Finally, a hybrid protein that is slightly larger, containing 49 amino acids of mature LamB, is found in the outer membrane in appreciable amounts. These fusions, together with previously described lamB-lacZ fusions, have enabled us to define more precisely the minimal amount of lamB required to initiate the process of protein export. Moreover, they genetically locate a signal that appears to guide LamB to the outer membrane. This signal is within a region of amino acid homology shared by other major outer membrane proteins [ Nikaido , H. & Wu, H. C. P. (1984) Proc. Natl. Acad. Sci. USA 81, 1048-1052].

Characterization of the ush gene of Escherichia coli and its protein products

The Escherichia coli ush gene has been subcloned and the coding sequence delineated using BAL31 nuclease digestion. Synthesis of proteins encoded by the ush gene have been examined in "maxicells"; two proteins are made, one of which corresponds in Mr (61000) to purified uridine diphosphoglucose hydrolase and the other, less abundant, has an Mr of 43 000. A deletion at the 3' end of the gene introduced by restriction endonuclease digestion, results in the synthesis of a truncated protein of the expected Mr of about 43 000. Precursors of all these proteins are observed in maxicells under conditions known to inhibit processing of secreted proteins. Whereas the precursor of the major ush-encoded protein is retained in the cytoplasm-plus-membrane fraction, unexpectedly the precursor of the truncated protein is secreted. The mature forms of both the normal and truncated proteins are secreted.

[Biosynthesis and transport of envelope proteins of Escherichia coli]

Bacterial protein synthesis takes place in the cytoplasm, thus periplasmic and outer membrane proteins pass through the cytoplasmic membrane during their dispatch to the cell envelope. The exported proteins are synthesized as precursor that contains an extra amino-terminal sequence of amino-acids. This sequence, termed "signal sequence", is essential for transport of the envelope proteins through the inner membrane and is cleaved during the exportation process. Various hypotheses for the mechanism have been presented, and it is likely that no signal model will be suitable to the export of all cell envelope proteins. This review is focused on the relationship between the cytoplasmic membrane and the precursor form. The physiological state of the membrane - fluidity, membrane potential for instance - is the strategic requirement of exportation process. Precursors can be accumulated in whole cells with various treatments which alter the cytoplasmic membrane. This inhibition of processing is obtained by modification of unsaturated to saturated fatty acids ratio or with phenylethyl alcohol which perturbs the membrane fluidity, with uncoupler agents such as carbonyl cyanide m-chlorophenyl hydrazone which dissipate the proton motive force, or with hybrid proteins which get jamming in the membrane. However, little is known about the early steps of translocation process across the cytoplasmic membrane ; for instance, it is not clear yet whether energy is required for either or both of the first interaction membrane-precursor and the crossing through the membrane. Several studies have recently shown the presence of exportation sites and of proteins which might play a prominent role in the export process, but the mechanism of discrimination between outer membrane proteins and periplasmic proteins is unknown. Considerable work has been done by genetic or biochemical methods and we have now the first lights of the expert mechanism.

M13 procoat and a pre-immunoglobulin share processing specificity but use different membrane receptor mechanisms

Bacteriophage M13 procoat is accurately processed to transmembrane coat protein by salt-washed or N-ethylmaleimide-treated rough microsomes from dog pancreas. These treatments inhibit the processing of eukaryotic secreted protein precursors. M13 procoat can assemble into dog pancreas microsomes post-translationally. Thus, the microsomal proteins needed for assembly may be determined by the nature of the precursor protein itself. These results, and our finding that the mouse IgG kappa chain fragment precursor is processed by Escherichia coli leader peptidase, also suggest that the cleavage specificity of leader (signal) peptidases and the properties of preproteins that render them suitable for cleavage have been conserved during evolution.

Synthesis of outer membrane proteins in cpxA cpxB mutants of Escherichia coli K-12

Two major proteins, the murein lipoprotein and the OmpF matrix porin, are deficient in the outer membrane of cpxA cpxB mutants of Escherichia coli K-12. We present evidence that the cpx mutations prevent or retard the translocation of these proteins to the outer membrane. The mutations had no effect on the rate of lipoprotein synthesis. Mutant cells labeled for 5 min with radioactive arginine accumulated as much lipoprotein as otherwise isogenic cpxA+ cpxB+ cells. This lipoprotein accumulated as such; no material synthesized in mutant cells and reactive with antilipoprotein antibodies had the electrophoretic mobility of prolipoprotein. Hence, the initial stages of prolipoprotein insertion into the inner membrane leading to its cleavage to lipoprotein appeared normal. However, after a long labeling interval, mutant cells were deficient in free lipoprotein and lacked lipoprotein covalently bound to peptidoglycan, suggesting that little if any of the lipoprotein synthesized in mutant cells reaches the outer membrane. Immunoreactive OmpF protein could also be detected in extracts of mutant cells labeled for 5 min, but the amount that accumulated was severalfold less in mutant cells than in cpxA+ cpxB+ cells. Analysis of beta-galactosidase synthesis from ompF-lacZ fusion genes showed this difference to be the result of a reduced rate of ompF transcription in mutant cells. Even so, little or none of the ompF protein synthesized in mutant cells was incorporated into the outer membrane.

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.

Assembly in vivo of enterotoxin from Escherichia coli: formation of the B subunit oligomer

An oligomer of the B subunit of heat-labile enterotoxin of Escherichia coli has been observed in minicells and in whole cells. There is a delay after synthesis of the B subunit before it appears in the oligomer. The delay is not due to slow processing of the precursor. A similar delay in oligomerization of the major outer membrane protein OmpF is also described.

Synthesis of Escherichia coli outer membrane ompA protein in yeasts

Saccharomyces cerevisiae was transformed with the Escherichia coli ompA gene coding for an outer membrane protein. Yeast transformants containing the pYTU101 plasmid, consisting of the ompA gene cloned in pSC101 and the HindIII-3 fragment of 2-microns DNA, express the foreign membrane protein. The protein synthesized in yeast has an Mr value very similar if not identical to that of the mature E. coli protein. The expressed protein is present in yeast mitochondrial and plasma membrane fractions. The yeast cell can tolerate about 250 molecules of the foreign membrane protein per cell, although the transformants show altered growth kinetics.

Membrane potential (delta psi) depolarizing agents inhibit maturation

Precursor forms of exported proteins were first accumulated in the envelope of phenethyl alcohol (PEA)-treated cells. After removal of PEA, a complete processing could be obtained in a few minutes. In this work, we demonstrate that colicins A and E1, that act on the electrical gradient in the cytoplasmic membrane, prevent the processing of precursor forms previously accumulated. Concentrations of colicins accounting for approximately 1 killing unit (50--3000 molecules/cell) were found to be sufficient for inhibition of processing. Therefore our results strongly suggest that in intact cells the electrical gradient across the cytoplasmic membrane is required for maturation of exported proteins.

Insertion of a MalE beta-galactosidase fusion protein into the envelope of Escherichia coli disrupts biogenesis of outer membrane proteins and processing of inner membrane proteins

The synthesis of a membrane-bound MalE beta-galactosidase hybrid protein, when induced by growth of Escherichia coli on maltose, leads to inhibition of cell division and eventually a reduced rate of mass increase. In addition, the relative rate of synthesis of outer membrane proteins, but not that of inner membrane proteins, was reduced by about 50%. Kinetic experiments demonstrated that this reduction coincided with the period of maximum synthesis of the hybrid protein (and another maltose-inducible protein, LamB). The accumulation of this abnormal protein in the envelope therefore appeared specifically to inhibit the synthesis, the assembly of outer membrane proteins, or both, indicating that the hybrid protein blocks some export site or causes the sequestration of some limiting factor(s) involved in the export process. Since the MalE protein is normally located in the periplasm, the results also suggest that the synthesis of periplasmic and outer membrane proteins may involve some steps in common. The reduced rate of synthesis of outer membrane proteins was also accompanied by the accumulation in the envelope of at least one outer membrane protein and at least two inner membrane proteins as higher-molecular-weight forms, indicating that processing (removal of the N-terminal signal sequence) was also disrupted by the presence of the hybrid protein. These results may indicate that the assembly of these membrane proteins is blocked at a relatively late step rather than at the level of primary recognition of some site by the signal sequence. In addition, the results suggest that some step common to the biogenesis of quite different kinds of envelope protein is blocked by the presence of the hybrid protein.

Biosynthesis of mitochondrial porin and insertion into the outer mitochondrial membrane of Neurospora crassa

Mitochondrial porin, the major protein of the outer mitochondrial membrane is synthesized by free cytoplasmic polysomes. The apparent molecular weight of the porin synthesized in homologous or heterologous cell-free systems is the same as that of the mature porin. Transfer in vitro of mitochondrial porin from the cytosolic fraction into the outer membrane of mitochondria could be demonstrated. Before membrane insertion, mitochondrial porin is highly sensitive to added proteinase; afterwards it is strongly protected. Binding of the precursor form to mitochondria occurs at 4 degrees C and appears to precede insertion into the membrane. Unlike transfer of many precursor proteins into or across the inner mitochondrial membrane, assembly of the porin is not dependent on an electrical potential across the inner membrane.

Rate of translation and kinetics of processing of newly synthesized molecules of two major outer-membrane proteins, the OmpA and OmpF proteins, of Escherichia coli K12

The rate of synthesis of the OmpA and OmpF proteins, two of the major outer membrane proteins of Escherichia coli K12, was determined. At 25 degrees C both proteins were translated at 6.5 amino acids/s, and the OmpF protein was translated at 15 amino acids/s at 37 degrees C. The former rate corresponded to a synthesis time of just over 50 s for both proteins, which is significantly faster than their reported rates of assembly into the outer membrane at 25 degrees C. The kinetics of processing of the pro-OmpF protein were also investigated in detail, and the pro-OmpF half-life estimated to be 3-5 s at 25 degrees C. However a fraction of the precursor was processed more slowly, which may explain the discrepancy between these data and our earlier published estimate of 30 s. Pro-OmpA protein was processed with similar kinetics. These results demonstrate that the rate-limiting step in the assembly of both proteins into the outer membrane is post-translational and follows the processing step.

Export of a protein into the outer membrane of Escherichia coli K12. Stable incorporation of the OmpA protein requires less than 193 amino-terminal amino-acid residues

The cloned ompA gene encoding the major outer membrane protein OmpA of Escherichia coli has been shortened in vitro by exonuclease digestion from the end corresponding to the CO2H terminus of the protein. Nine derivatives were identified which still possessed substantial parts of the ompA gene and one was constructed which had suffered a small deletion early in the gene. Gene fragments encoding NH2-terminal OmpA sequences of 45, 133, 193, and 227 residues of the 325 amino acids of OmpA were examined in detail at the DNA level and for OmpA protein fragments synthesized. The latter two fragments were incorporated into the outer membrane and all known functions of the OmpA protein were expressed whereas the fragment with 133 OmpA-specific residues was not stably incorporated into this membrane. In all cases where OmpA functions were observed, an OmpA-specific polypeptide of Mr 24 000 was found in cell envelopes, regardless of the size of the residual ompA sequences and of the fused coding sequences in the vector DNA. Pulse-label experiments revealed larger initial translation products, most of which were degraded to the protein of Mr 24000. The 133-residue OmpA fragment was also detected but proved to be entirely unstable. It is argued that the OmpA protein consists of two domains and that the NH2-terminal moiety from residues 1 to about 180 represents the membrane domain of the polypeptide. Therefore, the loss of about 50, possibly less, CO2H-terminal residues from this domain suffices to interfere with stable incorporation into the outer membrane.