Precursors of major outer membrane proteins of Escherichia coli

The Sec System: Protein Export in Escherichia coli

In Escherichia coli, proteins found in the periplasm or the outer membrane are exported from the cytoplasm by the general secretory, Sec, system before they acquire stably folded structure. This dynamic process involves intricate interactions among cytoplasmic and membrane proteins, both peripheral and integral, as well as lipids. In vivo, both ATP hydrolysis and proton motive force are required. Here, we review the Sec system from the inception of the field through early 2016, including biochemical, genetic, and structural data.

The Sec-dependent pathway

The Sec pathway for export of proteins across the cytoplasmic membrane to the bacterial periplasm and outer membrane was the first secretion pathway to be discovered in bacteria. A combination of bacterial genetics, development of an in vitro membrane vesicle system and the concurrent elaboration of the signal hypothesis from studies on eukaryotes led to the identification and characterization of two pathways leading to protein export through the SecYEG cytoplasmic membrane translocon. The Sec pathway is also required for assembly of proteins into the cytoplasmic membrane. Since the membrane translocon for Sec pathways is conserved across the three domains of life, the history of research progress in eukaryotes and bacteria was facilitated by the close interaction between those studying both classes of organisms.

Mechanisms of activation and secretion of a cell-associated precursor of an exocellular protease of Pseudomonas aeruginosa 34362A

An inactive precursor to the active exocellular protease 1 of Pseudomonas aeruginosa is cell-associated and located primarily in the periplasmic space. We have studied factors that bring about activation of the precursor in vitro in order to shed some light on the process of its activation and secretion in vivo. A variety of diverse procedures were shown to effect irreversible activation. Several mild non-enzymatic procedures were effective, such as dialysis of an ammonium sulfate precipitate against neutral buffers, gel filtration (Sephadex G-100), and ion-exchange chromatography (DEAE-cellulose). Activation also resulted following treatment with anionic detergents (sodium dodecyl sulfate, N-lauroyl sarcosine) and deoxycholate. Limited exposure to any of several proteases with different specificities also resulted in activation. The kinetics of detergent-catalyzed activation reveals a long lag followed by rapid activation, suggesting at least a two-stage process. The precursor and the mature protease 1 have indistinguishable molecular masses (33 kDa), as measured by sodium dodecyl sulfate/polyacrylamide gel electrophoresis of these proteins purified by immunoabsorbance chromatography under denaturing conditions. Further, both precursor and protease have identical N-terminal alanine. Our results suggest that it is improbable that activation is the result of proteolytic processing of the precursor itself, but rather that it may involve the removal of a non-covalently associated inhibitor molecule. Hydrophobic interaction chromatography on octyl-Sepharose revealed that activation was accompanied by a significant change in the hydrophobicity, pointing to a significant change in the conformation of the precursor and the mature protease. A mutant has been studied which accumulates activatable precursor in the periplasm but releases no active enzyme into the culture medium, supporting the hypothesis that secretion through the inner and outer membranes proceed by different mechanisms. Comparison of outer membranes of protease-secreting strains (34362A and PAKS 1) and a protease-negative mutant (PAKS 18) which accumulates precursor has shown that there is a change in the outer membrane protein profile in the latter.

In vitro synthesis of the delta-lysin of Staphylococcus aureus

The stability of mRNA for the delta-lysin of Staphylococcus aureus was determined by measuring the residual lysin synthesis after inhibition of DNA-dependent RNA polymerase activity with rifampin. At the late logarithmic-early stationary phase of growth the delta-lysin mRNA was very stable, with a half-life of ca. 20 min. Total cellular RNA was extracted from S. aureus and translated with a modified Escherichia coli S-30 system; delta-lysin was identified amongst the translation products by immunoprecipitation and immunoabsorption. The delta-lysin synthesized in vitro was of a size similar to mature delta-lysin and did not require a signal sequence for secretion from the cell.

Effects of the resistance plasmid R124 on the level of the OmpF outer membrane protein and on the response of Escherichia coli to environmental agents

The introduction of the F-like resistance plasmid R124 into an ompC mutant of Escherichia coli K12 conferred altered sensitivity to a wide range of inhibitory agents. Sensitivity to ampicillin, chloramphenicol, ethionine, copper ions, deoxycholate, two fatty acids and colicins L and M was decreased by the plasmid. In contrast the plasmid-bearing ompC derivatives were more sensitive than the plasmid-free ompC mutant to erythromycin, cetyltrimethylammonium bromide and phenol. Introduction of R124 into the ompC strain also decreased the level of the OmpF protein and some (but not all) of the changed sensitivities listed above clearly resulted from this outer membrane protein deficiency. The presence in the ompC mutant of R124 (rather than the more efficient introduction of the plasmid into variants of the ompC strain) led to at least most of the changes described above because those tested were accentuated by the presence of a copy mutant of R124 and reversed by plasmid curing.

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.

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.

A new major outer membrane protein in derivatives of Escherichia coli carrying the virulence plasmid ColV-K94

Strains of Escherichia coli K12 harbouring ColV-K94 contain a new major outer membrane protein of molecular weight ca. 33,000. The new protein resembles the Omp A protein in that (1) it is trypsin-sensitive in membrane preparations and (2) it is not murein-associated. The new protein cannot, however, replace the Omp A protein as a functional receptor for the phages K3 and TuII*, for colicin L or for efficient conjugation with F-like donors. The new protein is apparently not a transfer component and is produced by cells unable to produce colicin. Labelling experiments with minicells suggest that the new protein is one of two major plasmid-encoded membrane proteins.

Purification and partial characterization of a putative precursor to staphylococcal enterotoxin B

A putative precursor to staphylococcal enterotoxin B (SEB) has been identified as a component of purified membranes from Staphylococcus aureus S6. Agarose gel immunodiffusion analysis of the solubilized membranes demonstrated an immunoreactive protein that formed complete lines of identity with purified extracellular SEB. This putative precursor (pSEB) also had a different electrophoretic mobility from that of extracellular SEB when analyzed by immunoelectrophoresis. When membrane proteins from S6 were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and then transferred to nitrocellulose sheets and probed with I-125 labeled, affinity-purified anti-SEB, the pSEB band was identified. The pSEB was approximately 3,500 daltons larger than extracellular SEB. This component was purified by immunoprecipitation and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Two-dimensional peptide maps of the putative SEB precursor revealed that most of the tryptic peptides were identical to those of mature extracellular SEB. When purified membranes of other SEB+ (DU4916 and 10-275) and SEB- (RN450, RN451, S6R, and FR1100) S. aureus strains were analyzed by the nitrocellulose blot procedure, only the SEB+ strains contained this putative SEB precursor on their membranes.

Specialized transducing bacteriophage lambda carrying the structural gene for a major outer membrane matrix protein of Escherichia coli K-12

A specialized transducing phage lambda carrying the structural gene for the OmpF protein, an outer membrane matrix protein, was isolated. The phage carries the 20.5--21-min region of the Escherichia coli K-12 chromosome and carries asnS, ompF, and aspC genes.

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

The OmpA and OmpF proteins are major outer membrane proteins of Escherichia coli K12. Their precursors, the pro-OmpA and pro-OmpF proteins, have been detected in vivo in pulse-labelling experiments carried out with [35S]methionine at 25 degrees C. Wehn the pulse was at 37 degrees C, however, no precursors were detected. The pulse-labelled precursors were processed rapidly and quantitatively into mature protein at 25 degrees C. The apparent half-life of the pro-OmpF protein was estimated to be 30 s, and the pro-OmpA protein may be processed even faster. In short pulses (10 s) the precursors of both proteins were the predominant labelled species, indicating that at 25 degrees C processing does not start until chain elongation of the precursor is almost, if not entirely, complete. When French press lysates of cells pulse-labelled for 10 s were subjected to sucrose gradient centrifugation to separate the inner and outer membranes, both precursors comigrated with the inner membrane.

Synthesis and secretion of hemolysin by Escherichia coli

Hemolytic Escherichia coli cells were found to synthesize and secrete significant amounts of hemolysin into a mineral salt-glucose medium containing hemoglobin. The release of de novo-synthesized hemolysin was stopped in the presence of energy metabolism inhibitors such as 2,4-dinitrophenol, sodium azide, or potassium cyanide, resulting in an accumulation of intracellular hemolysin. A similar effect was observed in the presence of procaine, a neuroactive drug which inhibits the processing of exoproteins. Small amounts of hemolysin were secreted into the medium within approximately 10 min of inhibition of protein synthesis by chloramphenicol. This represented the final release of preformed periplasmic hemolysin en route to secretion through the outer membrane and was not caused by adsorption of external hemolysin to the cell surface. This secretion was not energy dependent but was inhibited above pH 8 and at low temperatures (10 to 20 degrees C). We concluded that two transport processes are involved in hemolysin secretion. De novo-synthesized hemolysin is extruded by an energy-dependent process through the cytoplasmic membrane and probably requires processing. In the periplasmic space a small internal pool of preformed hemolysin is accumulated temporarily before being transported through the outer membrane. Release of hemolysin through the outer membrane does not require energy or de novo protein synthesis.

Intermediate location in the assembly of the matrix protein or porin into the outer membrane of Escherichia coli

Evidence from pulse-chase experiments indicates that the outer membrane matrix protein or porin of Escherichia coli B/r passes through a Sarkosyl-soluble membrane pool on the way to its eventual Sarkosyl-insoluble state in the outer membrane.

Cellular distribution of beta-lactamase RP4 is mediated by an outer membrane protease

RP4 beta-lactamase extracted from the outer membrane of wild-type Escherichia coli can be resolved into several interconvertible forms that differ in their stabilities, substrate profiles and apparent molecular weights. beta-Lactamase isolated from outer membrane of strains which are lacking a protease that is involved in the cleavage of colicins differs from the beta-lactamase of parental cells in substrate profile, apparent molecular weight and the ability to interconvert. The cellular distribution of beta-lactamase also differs between wild-type and protease-deficient mutants. Both strains have equivalent amounts of beta-lactamase in their outer membranes, however the parental strain also has considerable beta-lactamase in the cytoplasmic membrane while the mutant does not. In addition the mutant contains only 30% of the parental level of enzyme in the periplasm. It is proposed that the reduced level of periplasmic enzyme is the result of a defect in processing of membrane-associated beta-lactamase. This conclusion is supported by the observation that the beta-lactamase isolated from the mutant can be converted to forms resembling those found in the parent by incubation with extracts or outer membrane isolated from the parent.

Primary structure of major outer membrane protein II (ompA protein) of Escherichia coli K-12

The amino acid sequence of major outer membrane protein II (ompA protein) from Escherichia coli K-12 has been determined. The transmembrane polypeptide consists of 325 residues, resulting in a molecular weight of 35,159. The transmembrane part of the protein is located between residues 1 and 177. In this part of the protein a predominantly lipophilic 27-residue segment exists that perhaps spans the membrane in a mostly alpha-helical conformation, or a 19-residue stretch of this segment might traverse the membrane linearly. Inside the outer membrane a sequence -Ala-Pro-Ala-Pro-Ala-Pro-Ala-Pro- exists that, analogous to the -Cys-Pro-Pro-Cys-Pro- sequence in the hinge region of immunoglobulin, could assume the conformation of a polyproline helix. Computer analysis did not reveal a clear overall pattern of internal homology in the protein; besides the -Ala-Pro- repeat, only one local area (two adjacent dodecapeptide segments) shows some repetitiveness. The same analysis did not produce evidence for internal homology in the previously determined sequence of outer membrane protein I (porin) nor was any marked resemblance detected between transmembrane proteins I and II.

Nucleotide sequence of the gene ompA coding the outer membrane protein II of Escherichia coli K-12

A nucleotide sequence of 2271 basepairs has been determined from cloned E. coli DNA which contains ompA. Withing that sequence, starting at nucleotide 1037, an open translational reading frame encodes a protein of 367 amino acids which starting with amino acid 22 agrees with the primary structure of protein II. The preceeding 21 amino acids constitute a typical signal sequence. There is a non-translated region of 360 nucleotides in front of the translational start. The insertion point of an IS1 element 110 nucleotides upstream from the start codon and an amber codon at the position of amino acid residue 28 have been localized in the DNA from two ompA mutants.

Regulatory region of the gene for the ompA protein, a major outer membrane protein of Escherichia coli

The ompA protein, an outer membrane protein required for conjugation, is one of the most abundant proteins in Escherichia coli. The structural gene for the ompA protein cloned in a plasmid vector, pMF21, conferred sensitivity to ompA protein-specific phages. We have determined the DNA sequence of a fragment of 533 base pairs encompassing the regulatory region of the ompA gene: the promoter region, the 5'-untranslated region, and the region corresponding to the signal peptide for this secretory protein. The promoter region has a sequence that is remarkably homologous with the lac and gal promoters. Particularly, both the ompA and gal promoters have the same octanucleotide sequence, T-C-A-C-A-C-T-T, in their RNA polymerase recognition site, which has been shown to be involved in the binding of cyclic AMP receptor protein to the gal promoter. Analogous with the observations in the gal operon, a specific RNA transcript was produced only when glycerol, a DNA-destabilizing agent, was added to a cell-free system directed by a DNA fragment of the ompA gene. These data indicate that the ompA mRNA has an untranslated region at the 5' end of about 140 nucleotides. In this region there are two additional initiation codons (II and III) besides the initiation codon (I) for the pro-ompA protein. AUG-III is located 30 bases upstream from AUG-I and accompanies a ribosome-binding site. Therefore, AUG-III is likely to begin the synthesis of a pentapeptide. The termination codon for the peptide overlaps with AUG-II, so that the ribosomes could reinitiate from AUG-II without being released from the mRNA. This reinitiation leads to the synthesis of a heptapeptide. The termination codon for this peptide also overlaps with AUG-I, which initiates the production of the pro-ompA protein. Because AUG-I also has an adjacent ribosome-binding site, the tandem repeat of initiation codons and ribosome-binding sites may be an important mechanism for facilitating the rate of initiation of translation. Extensive secondary structures exist in the 5' end as well as in the coding region of the ompA mRNA, which may also play a role in the function of the mRNA.

Correlation between the expression of an Escherichia coli cell surface protein and the ability of the protein to bind to lipopolysaccharide

The ompA gene of Escherichia coli codes for a major protein of the outer membrane. When this gene was moved between various unrelated strains (E. coli K-12 and two clinical isolates of E. coli) by transduction, the gene was expressed very poorly. Recombinants carrying "foreign" genes produced no OmpA protein which could be detected on polyacrylamide gels and became resistant to bacteriophage K3, which uses this protein as receptor. The recombinants were sensitive to host-range mutants of K3, indicating a very low level of OmpA protein was produced. When an E. coli K-12 recombinant carrying an unexpressed foreign ompA allele was subjected to two cycles of selection for an OmpA(+) phenotype, a mutant strain was obtained which was sensitive to K3 and which expressed nearly normal levels of OmpA protein in the outer membrane. This strain carried mutations in the foreign ompA gene, as indicated both by genetic mapping and the alteration of a peptide in the mutant OmpA protein. The ability of the OmpA protein to bind to lipopolysaccharide (LPS) showed similar strain specificity, and the mutant OmpA protein which was expressed in an unrelated host showed enhanced ability to bind LPS from its new host. Thus, cell surface expression of the ompA gene appears to depend upon the ability of the gene product to bind LPS, suggesting that an interaction between the protein and LPS plays an essential role in biosynthesis of this outer membrane protein.

Secretion and membrane localization of proteins in Escherichia coli

The envelope of Escherichia coli consists of two distinct membranes, the outer membrane and the cytoplasmic membrane. The space between the two membranes is called the periplasmic space, and each fraction contains its own specific proteins. In this review, it is discussed how proteins are localized in their final locations in the envelope. Proteins localized in the outer membrane and the periplasmic space as well as transmembranous proteins in the cytoplasmic membranes appear to be produced from their precursors which have peptide extensions of about 20 amino acid residues at the amino terminal ends. General features for the peptide extension are deduced from the known sequences of the peptide extensions, and, based on their known properties, a hypothesis (loop model) is proposed to explain the possible functions of the peptide extension during the mechanism of secretion across the cytoplasmic membrane.

Variant forms of matrix protein in Escherichia coli B/r bearing N plasmids

Plasmids of the N incompatibility group have been found to decrease or virtually eliminate the synthesis of the 36,500 dalton outer membrane matrix protein of their Escherichia coli B/r hosts (Iyer, R. (1977) Biochim. Biophys. Acta 470, 258--272 and Iyer, R., Darby, V. and Holland, I.B. (1978) FEBS Lett. 85, 127--132) or modify its composition. Although the 34,000 dalton tol G protein is slightly increased in some strains, it is identical in composition to the homologous protein from the plasmidless host. In three of five N+ strains the synthesis of the modified matrix proteins depends on the temperature of cultivation of the strains in which they occur. The alterations to the matrix proteins are non-identical and do not affect the expression of several plasmid-coded functions including those of sensitivity to the N plasmid-specific filamentous bacteriophage IKe (Khatoon, H. and Iyer, R. (1971) Can. J. Microbiol. 17, 669--675), or their interbacterial transfer via conjugation to appropriate recipient strains. Thus, although the significance of the variant matrix proteins in N+ strains with respect to plasmid-mediated functions remains unclear, N plasmids nevertheless provide a convenient system which might be used to elucidate the events that precede the insertion of this protein into the outer membrane of E. coli B/r hosts.

Membranes of Rhodopseudomonas sphaeroides. VI. Isolation of a fraction enriched in newly synthesized bacteriochlorophyll alpha-protein complexes

Radioactivity eventually destined for the chromatophore membrane of Rhodopseudomonas sphaeroides was shown in pulse-chase studies to appear first in a distinct pigmented fraction. The material formed an upper pigmented band which sedimented more slowly than chromatophores when cell-free extracts were subjected directly to rate-zone sedimentation on sucrose density gradients. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis indicated that the purified fraction contained polypeptide bands of the same mobility as light-harvesting bacteriochlorophyll alpha and reaction center-associated protein components of chromatophores; these were superimposed upon cytoplasmic membrane polypeptides. The pulse-chase relation was confined mainly to the polypeptide components of these pigment-protein complexes. It is suggested that the isolated fraction may be derived from sites at which new membrane invagination is initiated.

Chromosomal location and expression of the structural gene for major outer membrane protein Ia of Escherichia coli K-12 and of the homologous gene of Salmonella typhimurium

The gene determining the structure of a major outer membrane protein of Escherichia coli, protein Ia, has been located between serC and pyrD, at the min 21 region of the linkage map. This is based on the isolation and characterization of E. coli-Salmonella typhimurium intergeneric hybrids as well as analyses of a mutation (ompF2) affecting the formation of protein Ia. When the serC region of the S. typhimurium chromosome was transduced by phage P1 into E. coli, two classes of transductants were obtained; one produced protein Ia like the parental strain of E. coli, whereas the other produced not protein Ia but a pair of outer membrane proteins structurally related to 35K protein, one of the major outer membrane proteins of S. typhimurium. Furthermore, a strain of S. typhimurium harboring an F' plasmid which carries the ompF region of the E. coli chromosome was found to produce a protein indistinguishable from protein Ia, beside the outer membrane proteins characteristic to the parental Salmonella strain. These results suggest that the structural genes for protein Ia (E. coli) and for 35K protein (S. typhimurium) are homologous to each other and are located at the ompF region of the respective chromosome. The bearing of these findings on the genetic control of protein Ia formation is discussed.

Use of gene fusion to study secretion of maltose-binding protein into Escherichia coli periplasm

We have employed the technique of gene fusion to fuse the LacZ gene encoding the cytoplasmic enzyme beta-galactosidase with the malE gene encoding the periplasmic maltose binding protein (MBP). Strains were obtained which synthesize malE-lacZ hybrid proteins of various sizes. These proteins have, at their amino terminus, a portion of the MBP and at their carboxyl terminus, enzymatically active beta-galactosidase. When the hybrid protein includes only a small, amino-terminal portion of the MBP, the hybrid protein residues in the cytoplasm. When the hybrid protein contains enough of the MBP to include an intact MBP signal sequence, a significant portion of the hybrid protein is found in the cytoplasmic membrane, suggesting that secretion of the hybrid protein has been initiated. However, in no case is the hybrid protein secreted into the periplasm, even when the hybrid protein includes almost the entire MBP. In the latter case, the synthesis and attempted export of the hybrid protein interferes with the export of at least certain normal envelope proteins, which accumulate in the cell in their precursor forms, and the cell dies. These results suggest that a number of envelope proteins may be exported at a common site, and that there are only a limited number of such sites. Also, these results indicate that it is not sufficient to simply attach an amino-terminal signal sequence to a polypeptide to assure its export.

Nature of the regions involved in the insertion of newly synthesized protein into the outer membrane of Escherichia coli

Outer membrane proteins are synthesized by cytoplasmic membrane-bound polysomes, and inserted at insertion sites which cover about 10% of the total outer membrane when cells grow with a generation time of 1 h. A membrane fraction enriched in outer membrane insertion regions was isolated and partly characterized. The rat at which newly inserted proteins are transferred from such insertion regions into the rest of the outer membrane was found to be very fast; the new protein content of insertion regions and that of the remaining outer membrane equilibrate completely within about 20 s at 25 degrees C. Given the rather rigid structure of the outer membrane and the multiple interactions between outer membrane components and the murein layer, lateral diffusion of newly inserted proteins from insertion sites to the remaining outer membrane is not likely to explain this rapid equilibration. Instead, the data support a model in which insertion regions move along the cell surface, leaving behind stationary, newly inserted outer membrane proteins.

meoA is the structural gene for outer membrane protein c of Escherichia coli K12

The isolation and characterization of two mutants of Escherichia coli K12 with an altered outer membrane protein c is described. The first mutant, strain CE1151, was isolated as a bacteriophage Me1 resistant strain which contains normal levels of protein c. Mutant cells adsorbed the phage with a strongly decreased rate. Complexes of purified nonheat modified wild type protein c and wild type lipopolysaccharide inactivated phage Me1, indicating that these components are required for receptor activity for phage Me1. When wild type protein c was replaced by protein c of strain CE1151, the receptor-complex was far less active, showing that protein c of strain CE1151 is altered. The second mutant produces a protein c with a decreased electrophoretic mobility, designated as protein c. An altered apparent molecular weight was also observed for one or more fragments obtained after fragmentation of the mutant protein with cyanogen bromide, trypsin and chymotrypsin. Alteration of protein c was not accompanied by a detectable alteration in protein b or its fragments. Both mutations are located at minute 48 of the Escherichia coli K12 linkage map. The results strongly suggest that meoA is the structural gene for protein c.

Localization of proteolytic activity in the outer membrane of Escherichia coli

An enzyme in the cytoplasmic membrane, nitrate reductase, can be solubilized by heating membranes to 60 degrees C for 10 min at alkaline pH. A protease in the cell envelope has been shown to be responsible for this solubilization. The localization of this protease in the outer membrane was demonstrated by separating the outer membrane from the cytoplasmic membrane, adding back various forms of outer membrane protein to the cytoplasmic membrane, and following the increase in nitrate reductase solubilization with increasing amounts of outer membrane proteins. This solubilization is accompanied by the cleavage of one of the subunits of nitrate reductase and is inhibited by the protease inhibitor p-aminobenzamidine. Analysis of membrane proteins synthesized by cells grown in the presence of various amounts of p-aminobenzamidine revealed that p-aminobenzamidine affects the synthesis of the major outer membrane proteins but has little effect on the synthesis of cytoplasmic membrane proteins. When outer membrane is reacted with the protease inhibitor [3H]diisopropylfluorophosphate, a single protein in the outer membrane is labeled. Since the interaction with diisopropylfluorophosphate is inhibited by p-aminobenzamidine, it is suggested that this single outer membrane protein is responsible for the in vitro solubilization of nitrate reductase and the in vivo processing of the major outer membrane proteins.

Two-component nature of bacteriophage T4 receptor activity in Escherichia coli K-12

Escherichia coli bacteriophage T4 uses the lipopolysaccharide of the outer cell envelope membrane as a receptor. Lipopolysaccharide from E. coli K-12 required a major outer membrane protein, polypeptide Ib, for phage inactivation.

Mutants (ompA) affecting a major outer membrane protein of Escherichia coli K12

Seventy independent mutants have been analyzed affecting a major protein, polypeptide II, of the outer cell envelope membrane from Escherichia coli K12. They were classified as nonsense mutants of the amber type (20%), mutants most likely of the missense type possessing the protein at normal concentrations (9%), and mutants either missing the protein or harboring it at much reduced concentrations for unknown reasons (71%). Forty of the mutants were analyzed genetically and all were found to map at or near ompA, the structural gene for protein II. Two-dimensional electrophoretic analyses of envelopes from such mutants revealed an unusual heterogeneity of the protein which on such patterns appeared as at least 12 well separated spots, and the majority of these is due to artifacts of the method but apparently specific for this protein. In no case was a polypeptide fragment found in envelopes from the nonsense mutants. The results are discussed regarding two different phages which use the protein as a receptor and concerning the biosynthetic incorporation of the protein into the outer membrane.

Major proteins of the outer cell envelope membrane of Escherichia coli K12: multiple species of protein I differ in primary structure

Protein I, one of the major outer membrane proteins of E. coli in most K12 strains is represented by two very similar polypeptides Ia and Ib. Sequential mutations (involving selections for phage resistance) can lead to loss of proteins Ia and Ib. Among "revertants" of such Ia-Ib- mutants clones exist that instead of Ia or Ib produce a third species of protein I, polypeptide Ic. Ichihara and Mizushima [J. Biochem. 83, 1095--1100 (1978)] have shown that proteins Ia and Ib exhibit differences in primary structure. Here evidence is presented indicating that protein Ic also is not identical in primary structure with Ia or Ib. Thus, 3 very similar structural genes appear to exist for the protein I species known to date, and that for Ic normally is silent. Introduction of a functional Ic locus into a Ia+ Ib+ strain caused expression of all three proteins with a reduced rate of synthesis of protein Ia.

Insertion of newly synthesized proteins into the outer membrane of Escherichia coli

The insertion of newly synthesized proteins into the outer membrane of Escherichia coli has been examined. The results show that there is no precurser pool of outer membrane proteins in the cytoplasmic membrane because first, the incorporation of a [35S]methionine pulse into outer membrane proteins completely parallels its incorporation into cytoplasmic membrane proteins, and second, under optimal isolation conditions, no outer membrane proteins are found in the cytoplasmic membrane, even when the membranes are analysed after being labeled for only 15 s. The [35S]methionine present in the outer membrane after a pulse of 15 s was found in protein fragments of varying sizes rather than in specific outer membrane proteins. This label could however be chased into specific proteins within 30--120 s, depending on the size of the protein, indicating that although unfinished protein fragments were present in the outer membrane, they were completed by subsequent chain elongation. Thus, outer membrane proteins are inserted into the outer membrane while still attached to ribosomes. Since ribosomes which are linked to the cell envelope by nascent polypeptide chains are stationary, the mRNA which is being translated by these ribosomes moves along the inner cell surface.