Regulation of the synthesis of surface protein in the cell cycle of E. coli B/r.

We have studied the biogenesis of the envelope of E. coli B/r by measuring the synthesis of protein in separated inner and outer membranes during the cell cycle. While total protein and bulk inner membrane protein were synthesized continuously and at an exponentially increasing rate throughout the cycle, bulk outer membrane protein was synthesized at a constant rate throughout the cycle with an abrupt doubling in rate occurring 10–15 min before division. A similar pattern was observed when the rate of synthesis of an individual protein, the 36.5K outer membrane protein, was measured directly in total cell lysates. Neither thymine starvation nor changes in gene dosage of exponential cultures affected the synthesis of outer membrane protein, indicating that the doubling in rate is not controlled by a gene duplication mechanism. Other findings, however, further indicate that outer membrane protein synthesis is regulated in some way. Thus the concentration of 36.5K porin per unit surface area remained constant as the surface area/volume ratio varied widely with growth rate. We also obtained direct evidence for an overall limitation on the rate of synthesis of bulk outer membrane proteins; when a new class of outer membrane proteins was induced, the rate of synthesis of other surface proteins was correspondingly reduced. On the basis of these results, we discuss a model in which the linear growth of outer membrane protein results from a limitation of outer membrane polypeptide synthesis at the translational level, reflecting the linear expansion of the underlying peptidoglycan layer in the envelope.     

Effects of secA mutations on the synthesis and secretion of proteins in Escherichia coli. Evidence for a major export system for cell envelope proteins

We have followed the synthesis and secretion of a number of periplasmic and outer membrane proteins in three strains of Escherichia coli, a secA amber mutant, a secA temperature-sensitive mutant, and a strain that blocks protein secretion due to a high level of expression of an export-defective hybrid protein between maltose-binding protein and beta-galactosidase (MalE-LacZ). Our results show that after several hours under nonpermissive conditions the specificity and extent of the export blocks in the secA temperature-sensitive mutant and the strain producing the MalE-LacZ hybrid protein are identical, affecting at least four major outer membrane proteins and most but not all periplasmic proteins. The secA gene product, therefore, appears to be an essential component of the major export pathway in E. coli which is used by many envelope proteins independent of whether they are cotranslationally or post-translationally secreted. In contrast, the synthesis of only a subset of these envelope proteins is reduced in the secA amber mutant after shift to the nonpermissive condition. These results indicate that the SecA protein serves roles both in the synthesis and the secretion of certain cell envelope proteins.     

Envelope membrane proteins that interact with chloroplastic precursor proteins.

The post-translational transport of cytoplasmically synthesized precursor proteins into chloroplasts requires proteins in the envelope membranes. To identify some of these proteins, label transfer cross-linking was performed using precursor to the small subunit of ribulose-1,5-bisphosphate carboxylase (prSSU) that was blocked at an early stage of the transport process. Two envelope proteins were identified: an 86-kD protein and a 75-kD protein, both present in the outer membrane. Labeling of both proteins required prSSU and could not be accomplished with SSU lacking a transit peptide. Labeling of the 75-kD protein occurred only when low levels of ATP were present, whereas labeling of the 86-kD protein occurred in the absence of exogenous ATP. Although both labeled proteins were identified as proteins of the outer envelope membrane, the labeled form of the 75-kD protein could only be detected in fractions containing mixed envelope membranes. Based on these observations, we propose that prSSU first binds in an ATP-independent fashion to the 86-kD protein. The energy-requiring step is association with the 75-kD protein and assembly of a translocation contact site between the inner and outer membrane of the chloroplastic envelope.     

Involvement of Neisseria meningitidis Lipoprotein GNA2091 in the Assembly of a Subset of Outer Membrane Proteins

GNA2091 of Neisseria meningitidis is a lipoprotein of unknown function that is included in the novel 4CMenB vaccine. Here, we investigated the biological function and the subcellular localization of the protein. We demonstrate that GNA2091 functions in the assembly of outer membrane proteins (OMPs) because its absence resulted in the accumulation of misassembled OMPs. Cell fractionation and protease accessibility experiments showed that the protein is localized at the periplasmic side of the outer membrane. Pulldown experiments revealed that it is not stably associated with the β-barrel assembly machinery, the previously identified complex for OMP assembly. Thus, GNA2091 constitutes a novel outer membrane-based lipoprotein required for OMP assembly. Furthermore, its location at the inner side of the outer membrane indicates that protective immunity elicited by this antigen cannot be due to bactericidal or opsonic activity of antibodies.     

Acyl-CoA Synthetase Is Located in the Outer Membrane and Acyl-CoA Thioesterase in the Inner Membrane of Pea Chloroplast Envelopes

Both acyl-CoA synthetase and acyl-CoA thioesterase activities are present in chloroplast envelope membranes. The functions of these enzymes in lipid metabolism remains unresolved, although the synthetase has been proposed to be involved in either plastid galactolipid synthesis or the export of plastid-synthesized fatty acids to the cytoplasm. We have examined the locations of both enzymes within the two envelope membranes of pea (Pisum sativum var Laxton's Progress No. 9) chloroplasts. Inner and outer envelope membranes were purified from unfractionated envelope preparations by linear density sucrose gradient centrifugation. Acyl-CoA synthetase was located in the outer envelope membrane while acyl-CoA thioesterase was located in the inner envelope membrane. Thus, it seems unlikely that the synthetase is directly involved in galactolipid assembly. Instead, its localization supports the hypothesis that it functions in the transport of plastid-synthesized fatty acids to the endoplasmic reticulum.     

Differential effects of yfgL mutation on Escherichia coli outer membrane proteins and lipopolysaccharide

YfgL together with NlpB, YfiO, and YaeT form a protein complex to facilitate the insertion of proteins into the outer membrane of Escherichia coli. Without YfgL, the levels of OmpA, OmpF, and LamB are significantly reduced, while OmpC levels are slightly reduced. In contrast, the level of TolC significantly increases in a yfgL mutant. When cells are depleted of YaeT or YfiO, levels of all outer membrane proteins examined, including OmpC and TolC, are severely reduced. Thus, while the assembly pathways of various nonlipoprotein outer membrane proteins may vary through the step involving YfgL, all assembly pathways in Escherichia coli converge at the step involving the YaeT/YfiO complex. The negative effect of yfgL mutation on outer membrane proteins may in part be due to elevated sigma E activity, which has been shown to downregulate the synthesis of various outer membrane proteins while upregulating the synthesis of periplasmic chaperones, foldases, and lipopolysaccharide. The data presented here suggest that the yfgL effect on outer membrane proteins also stems from a defective assembly apparatus, leading to aberrant outer membrane protein assembly, except for TolC, which assembles independent of YfgL. Consistent with this view, the simultaneous absence of YfgL and the major periplasmic protease DegP confers a synthetic lethal phenotype, presumably due to the toxic accumulation of unfolded outer membrane proteins. The results support the hypothesis that TolC and major outer membrane proteins compete for the YaeT/YfiO complex, since mutations that adversely affect synthesis or assembly of major outer membrane proteins lead to elevated TolC levels.     

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.     

Production in Escherichia coli and one-step purification of bifunctional hybrid proteins which bind maltose. Export of the Klenow polymerase into the periplasmic space

Two enzymes, the secreted Staphylococcus aureus nuclease A and the Klenow fragment of the cytoplasmic Escherichia coli DNA polymerase I, were fused, at the genetic level, to MalE, the periplasmic maltose-binding protein of E. coli, or to a signal-sequence mutant. The hybrid proteins were synthesized in large amounts by E. coli under control of promoter malEp. The synthesis was repressed with glucose and could be totally switched off in a malT mutant strain. The hybrid between MalE and the nuclease was exported into the periplasmic space. Several criteria demonstrated that a fraction of the hybrid chains with the Klenow polymerase was exported to the periplasm in a signal-sequence-specific manner and ruled out the possibility of a membrane leakage. The hybrid with the Klenow polymerase was not exported and remained in the cytoplasm when carrying a tight signal-sequence mutation in its MalE portion. The hybrid proteins were purified in one step by affinity chromatography on cross-linked amylose. Most of the hybrid chains in the periplasm but only a fraction of those in the other cell compartments had their MalE portion correctly folded. The nuclease and the Klenow polymerase had their full specific activities in the purified hybrids. The potential of MalE as a vector for the production, export and purification of desirable proteins in E. coli is discussed.     

An inner membrane protein N-terminal signal sequence is able to promote efficient localisation of an outer membrane protein in Escherichia coli

To test the importance of N-terminal pre-sequences in translocation of different classes of membrane proteins, we exchanged the normal signal sequence of an Escherichia coli outer membrane protein, OmpF, for the pre-sequence of the inner membrane protein, DacA. The DacA-OmpF hybrid was efficiently assembled into the outer membrane in a functionally active form. Thus the pre-sequence of DacA, despite its relatively low hydrophobicity compared with that of OmpF, contains all the essential information necessary to initiate the translocation of OmpF to the outer membrane. Since processing of DacA was also shown to be dependent upon SecA we conclude that the initiation of translocation of this inner membrane polypeptide across the envelope occurs by the same mechanism as outer membrane and periplasmic proteins. The N-terminal 11 amino acids of mature OmpF, which in the hybrid are replaced by the N-terminal nine amino acids of DacA, carry no essential assembly signals since the hybrid protein is apparently assembled with equal efficiency to OmpF.     

Effects of two sec genes on protein assembly into the plasma membrane of Escherichia coli

We have examined the effects of thermosensitive mutations in secA and secY (prlA) genes on the export of proteins to the three layers of the Escherichia coli cell surface. After several hours at the nonpermissive temperature, the export of two major outer membrane proteins, lipoprotein and OmpA, is delayed, then essentially blocked, in either a secA or secY strain. These mutations also have a strong effect on the export of several proteins, such as maltose binding protein, to the periplasm, though the export of many periplasmic proteins is not affected. secA and secY block the assembly of leader peptidase, which is made without a leader sequence, into the inner membrane. However, the membrane assembly of M13 coat protein (an inner membrane protein made with an amino-terminal leader sequence) is not affected. Thus, the requirement for sec function for export does not correlate with the presence or absence of leader peptide or with a particular subcellular compartment, but rather is specific to each particular protein.     

Translational control of exported proteins that results from OmpC porin overexpression.

The regulation of synthesis and export of outer membrane proteins of Escherichia coli was examined by overexpressing ompC in multicopy either from its own promoter or from an inducible promoter in an expression vector. Overexpression of OmpC protein resulted in a nearly complete inhibition of synthesis of the OmpA and LamB outer membrane proteins but had no effect on synthesis of the periplasmic maltose-binding protein. Immunoprecipitation of labeled proteins showed no evidence of accumulation of uncleaved precursor forms of OmpA or maltose-binding protein following induction of OmpC overexpression. The inhibition of OmpA and LamB was tightly coupled to OmpC overexpression and occurred very rapidly, reaching a high level within 2 min after induction. OmpC overexpression did not cause a significant decrease in expression of a LamB-LacZ hybrid protein produced from a lamB-lacZ fusion in which the fusion joint was at the second amino acid of the LamB signal sequence. There was no significant decrease in rate of synthesis of ompA mRNA as measured by filter hybridization of pulse-labeled RNA. These results indicate that the inhibition is at the level of translation. We propose that cells are able to monitor expression of exported proteins by sensing occupancy of some limiting component in the export machinery and use this to regulate translation of these proteins.     

Effect of OmpA signal peptide mutations on OmpA secretion, synthesis, and assembly.

In previous investigations, we have examined the effect of OmpA signal peptide mutations on the secretion of the two heterologous proteins TEM beta-lactamase and nuclease A. During these studies, we observed that a given signal peptide mutation could affect differentially the processing of precursor OmpA-nuclease or precursor OmpA-lactamase. This observation led us to further investigate the influence of the mature region of a precursor protein on protein export. Preexisting OmpA signal peptide mutations of known secretion phenotype when directing heterologous protein export (nuclease A or beta-lactamase) were fused to the homologous mature OmpA protein. Four signal peptide mutations that have previously been shown to prevent export of nuclease A and beta-lactamase were found to support OmpA protein export, albeit at reduced rates. This remarkable retention of export activity by severely defective precursor OmpA signal peptide mutants may be due to the ability of mature OmpA to interact with the cytoplasmic membrane. In addition, these same signal peptide mutations can affect the level of OmpA synthesis as well as its proper assembly in the outer membrane of Escherichia coli. Two signal peptide mutations dramatically stimulate the rate of precursor OmpA synthesis three- to fivefold above the level observed when a wild-type signal peptide is directing export. The complete removal of the OmpA signal peptide does not result in increased OmpA synthesis. This finding suggests that the signal peptide mutations function positively to stimulate OmpA synthesis, rather than bypass a down-regulatory mechanism effected by a wild-type signal peptide. Overproduction of wild-type precursor OmpA or precursors containing signal peptide mutations which lead to relatively minor kinetic processing defects results in accumulation of an improperly assembled OmpA species (imp-OmpA). In contrast, signal peptide mutations which cause relatively severe processing defects accumulate no or only small quantities of imp-OmpA. All mutations result in equivalent levels of properly assembled OmpA. Thus, a strong correlation between imp-OmpA accumulation and cell toxicity was observed. A mutation in the mature region of OmpA which prevents the proper outer membrane assembly of OmpA was suppressed when export was directed by a severely defective signal peptide. These findings suggest that signal peptide mutations indirectly influence OmpA assembly in the outer membrane by altering both the level and rate of OmpA secretion across the cytoplasmic membrane.     

Translational control of exported proteins in Escherichia coli

We recently described the suppression of export of a class of periplasmic proteins of Escherichia coli caused by overproduction of a C-terminal truncated periplasmic enzyme (GlpQ'). This truncated protein was not released into the periplasm but remained attached to the inner membrane and was accessible from the periplasm. The presence of GlpQ' in the membrane strongly reduced the appearance in the periplasm of some periplasmic proteins, including the maltose-binding protein (MBP), but did not affect outer membrane proteins, including the lambda receptor (LamB) (R. Hengge and W. Boos, J. Bacteriol., 162:972-978, 1985). To investigate this phenomenon further we examined the fate of MBP in comparison with the outer membrane protein LamB. We found that not only localization but also synthesis of MBP was impaired, indicating a coupling of translation and export. Synthesis and secretion of LamB were not affected. The possibility that this influence was exerted via the level of cyclic AMP could be excluded. Synthesis of MBP with altered signal sequences was also reduced, demonstrating that export-defective MBP which ultimately remains in the cytoplasm abortively enters the export pathway. When GlpQ' was expressed in a secA51(Ts) strain, the inhibition of MBP synthesis caused by GlpQ' was dominant over the precursor accumulation usually caused by secA51(Ts) at 41 degrees C. Therefore, GlpQ' acts before or at the level of recognition by SecA. For LamB the usual secA51(Ts) phenotype was observed. We propose a mechanism by which GlpQ' blocks an yet unknown membrane protein, the function of which is to couple translation and export of a subclass of periplasmic proteins.     

Two regions of mature periplasmic maltose-binding protein of Escherichia coli involved in secretion.

Six mutations in malE, the structural gene for the periplasmic maltose-binding protein (MBP) from Escherichia coli, prevent growth on maltose as a carbon source, as well as release of the mutant proteins by the cold osmotic-shock procedure. These mutations correspond to insertion of an oligonucleotide linker, concomitant with a deletion. One of the mutations (malE127) affects the N-terminal extension (the signal peptide), whereas the five others lie within the mature protein. As expected, the export of protein MalE127 is blocked at an early stage. This protein is neither processed to maturity nor sensitive to proteinase K in spheroplasts. In contrast, in the five other mutants, the signal peptide is cleaved and the protein is accessible to proteinase K added to spheroplasts. This indicates that the five mutant proteins are, at least in part, exported through the inner membrane. We propose that the corresponding mutations define two regions of the mature protein (between residues 18 and 42 and between residues 280 and 306), which are important for release of the protein from the inner membrane into the periplasm. We discuss the results in terms of possible conformational changes at this late step of export to the periplasm.     

Membrane localization and topology of leukotriene C4 synthase

Leukotriene C(4) (LTC(4)) synthase conjugates LTA(4) with GSH to form LTC(4). Determining the site of LTC(4) synthesis and the topology of LTC(4) synthase may uncover unappreciated intracellular roles for LTC(4), as well as how LTC(4) is transferred to its export carrier, the multidrug resistance protein-1. We have determined the membrane localization of LTC(4) synthase by immunoelectron microscopy. In contrast to the closely related five-lipoxygenase-activating protein, LTC(4) synthase is distributed in the outer nuclear membrane and peripheral endoplasmic reticulum but is excluded from the inner nuclear membrane. We have combined immunofluorescence with differential membrane permeabilization to determine the topology of LTC(4) synthase. The active site of LTC(4) synthase is localized in the lumen of the nuclear envelope and endoplasmic reticulum. These results indicate that the synthesis of LTB(4) and LTC(4) occurs in different subcellular locations and suggests that LTC(4) must be returned to the cytoplasmic side of the membrane for export by multidrug resistance protein-1. The differential localization of two very similar integral membrane proteins suggests that mechanisms other than size-dependent exclusion regulate their passage to the inner nuclear membrane.     

Filamentous phage assembly: variation on a protein export theme

Biogenesis of both filamentous phage and type-IV pili involves the assembly of many copies of a small, integral inner membrane protein (the phage major coat protein or pilin) into a helical, tubular array that passes through the outer membrane. The occurrence of related proteins required for assembly and export in both systems suggests that there may be similarities at the mechanistic level as well. This report summarizes the properties of filamentous phage and the proteins required for their assembly, with particular emphasis on features they may share with bacterial protein export and pilus biogenesis systems, and it presents evidence that supports the hypothesis that one of the phage proteins functions as an outer membrane export channel.     

Examination of AsmA and its effect on the assembly of Escherichia coli outer membrane proteins

asmA mutations were isolated as extragenic suppressors of an OmpF assembly mutant, OmpF315. This suppressor locus produced a protein that was present in extremely low levels and could only be visualized by Western blotting in cells where AsmA expression was induced from a plasmid. Detailed fractionation analyses showed that AsmA localized with the inner membrane. Curiously, however, the mutant OmpF assembly step influenced by AsmA occurred in the outer membrane, perhaps indicating an indirect involvement of AsmA in the assembly of outer membrane proteins. Biochemical examination of the outer membrane showed that asmA null mutations reduce lipo-polysaccharide (LPS) levels, thereby lowering the ratios of glycerolphospholipids to LPS and envelope proteins to LPS in the outer membrane. Despite these quantitative alterations, no apparent structural changes in LPS or major phospholipids were noted. Reduced LPS levels in asmA mutants indicate a possible role of AsmA in LPS biogenesis. Data presented in this study suggest that asmA-mediated OmpF assembly suppression may have been achieved by altering the outer membrane fluidity, thus making it more amenable for the assembly of mutant proteins.     

Membrane proteins correlated with expression of the polysialic acid capsule in Escherichia coli K1.

Growth of Escherichia coli K1 strains at 15 degrees C results in a defect in the synthesis or assembly of the K1 polysialic acid capsule. Synthesis is reactivated in cells grown at 15 degrees C after upshift to 37 degrees C, and activation requires protein synthesis (Whitfield et al., J. Bacteriol. 159:321-328, 1984). Using this temperature-induced defect, we determined the molecular weights and locations of membrane proteins correlated with the expression of K1 (polysialosyl) capsular antigen. Pulse-labeling experiments demonstrated the presence of 11 proteins whose synthesis was correlated with capsule appearance at the cell surface. Using the differential solubility of inner and outer membranes in the detergent Sarkosyl, we localized five of the proteins in the outer membrane and four in the inner membrane. The subcellular location of two of the proteins was not determined. Five proteins appeared in the membrane simultaneously with the initial expression of the K1 capsule at the cell surface. One of these proteins, a 40,000-dalton protein localized in the outer membrane, was identified as porin protein K, which previously has been shown to be present in the outer membrane of encapsulated E. coli. The possible role of these proteins in the synthesis of the polysialosyl capsule is discussed.     

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.     

The Chloroplast Outer Envelope Membrane： The Edge of Liaht and Excitement

The chloroplast is surrounded by a double-membrane envelope at which proteins, ions, and numerous metabolites including nucleotides, amino acids, fatty acids, and carbohydrates are exchanged between the two aqueous phases, the cytoplasm and the chloroplast stroma. The chloroplast envelope is also the location where the biosynthesis and accumulation of various lipids take place. By contrast to the inner membrane, which contains a number of specific transporters and acts as the permeability barrier, the chloroplast outer membrane has often been considered a passive compartment derived from the phagosomal membrane. However, the presence of galactoglycerolipids and β-barrel membrane proteins support the common origin of the outer membranes of the chloroplast envelope and extant cyanobacteria. Furthermore, recent progress in the field underlines that the chloroplast outer envelope plays important roles not only for translocation of various molecules, but also for regulation of metabolic activities and signaling processes. The chloroplast outer envelope membrane offers various interesting and challenging questions that are relevant to the understanding of organelle biogenesis, plant growth and development, and also membrane biology in general.