Membrane incorporation and induction of secondary structure of synthetic peptides corresponding to the N-terminal signal sequences of the glucitol and mannitol permeases of Escherichia coli

The 22-residue synthetic signal peptide of the glucitol permease (Enzyme IIgut of the bacterial phosphotransferase system; gut22), which in the intact protein is believed to function in envelope targeting, was found to insert into phospholipid monolayers of various phospholipid compositions up to high limiting pressures (36-41 milliNewton/m). The partition coefficient, derived from monolayer area expansion experiments, was greatest for the negatively charged gut22 when partitioning into monolayers of the zwitterionic lipid 1-palmitoyl-2-oleoyl-3-sn-phosphatidylcholine (about 1.1 X 10(5] as compared with that obtained with a mixture of 1-palmitoyl-2-oleoyl-3-sn-phosphatidylcholine and the negatively charged lipids 1-palmitoyl-2-oleoyl-3-sn-phosphatidylglycerol and cardiolipin. Gut22 contains a titratable histidyl residue (pKa = 6.8), and its protonation decreased the relative monolayer area increase 3-fold. Circular dichroism spectra showed that gut22 formed an amphiphilic alpha-helix when incorporated into lipid membranes (estimated percent helix = 65%). Fluorescence measurements indicated that tryptophan 11 is in a more hydrophobic environment in the presence of lipid than in its absence, with the environment being more hydrophobic at pH 5 than at pH 8. The more hydrophilic 15-residue signal peptide of the mannitol permease (mtl15) also incorporated into monolayers and detergent micelles (although to a lesser extent) with induction of secondary structure. Based on these results and a parallel with mitochondrial targeting in eucaryotes, we suggest that the induction of N-terminal amphiphilic structures and their association with a hydrophobic-hydrophilic interface are important for envelope targeting and the initiation of the membrane insertion of bacterial phosphoenol-pyruvate-dependent phosphotransferase system permeases.     

Insertion of the mannitol permease into the membrane of Escherichia coli. Possible involvement of an N-terminal amphiphilic sequence

The in vivo membrane assembly of the mannitol permease, the mannitol Enzyme II (IImtl) of the Escherichia coli phosphotransferase system, has been studied employing molecular genetic approaches. Removal of the N-terminal amphiphilic leader of the permease and replacement with a short hydrophobic sequence resulted in an inactive protein unable to transport mannitol into the cell or catalyze either phosphoenol-pyruvate-dependent or mannitol 1-phosphate-dependent mannitol phosphorylation in vitro. The altered protein (68 kDa) was quantitatively cleaved by an endogenous protease to a membrane-associated 39-kDa fragment and a soluble 28-kDa fragment as revealed by Western blot analyses. Overproduction of the wild-type plasmid-encoded protein also led to cleavage, but repression of the synthesis of the plasmid-encoded enzyme by inclusion of glucose in the growth medium prevented cleavage. Several mtlA-phoA gene fusions encoding fused proteins with N-terminal regions derived from the mannitol permease and C-terminal regions derived from the mature portion of alkaline phosphatase were constructed. In the first fusion protein, F13, the N-terminal 13-aminoacyl residue amphiphilic leader sequence of the mannitol permease replaced the hydrophobic leader sequence of alkaline phosphatase. The resultant fusion protein was inefficiently translocated across the cytoplasmic membrane and became peripherally associated with both the inner and outer membranes, presumably via the noncleavable N-terminal amphiphilic sequence. The second fusion protein, F53, in which the N-terminal 53 residues of the mannitol permease were fused to alkaline phosphatase, was efficiently translocated across the cytoplasmic membrane and was largely found anchored to the inner membrane with the catalytic domain of alkaline phosphatase facing the periplasm. This 53-aminoacyl residue sequence included the amphiphilic leader sequence and a single hydrophobic, potentially transmembrane, segment. Analyses of other MtlA-PhoA fusion proteins led to the suggestion that internal amphiphilic segments may function to facilitate initiation of polypeptide trans-membrane translocation. The dependence of IImtl insertion on the N-terminal amphiphilic leader sequence was substantiated employing site-specific mutagenesis. The N-terminal sequence of the native permease is Met-Ser-Ser-Asp-Ile-Lys-Ile-Lys-Val-Gln-Ser-Phe-Gly.... The following point mutants were isolated, sequenced, and examined regarding the effects of the mutations on insertion of IImtl into the membrane: 1) S3P; 2) D4P; 3) D4L; 4) D4R; 5) D4H; 6) I5N; 7) K6P; and 8) K8P.(ABSTRACT TRUNCATED AT 400 WORDS)     

Physical and genetic characterization of the glucitol operon in Escherichia coli.

The glucitol (gut) operon has been identified in the colony bank of Clark and Carbon (A. Sancar and W. D. Rupp, Proc. Natl. Acad. Sci. USA 76:3144-3148, 1979). We subcloned the gut operon by using paCYC184, pACYC177, and pBR322. The operon, which is encoded in a 3.3-kilobase nucleotide fragment, consists of the gutC, gutA, gutB, and gutD genes. The repressor of the gut operon seemed to be encoded in the region downstream from the operon. The gene products of the gut operon were identified by using maxicells. The apparent molecular weights of the glucitol-specific enzyme II (product of the gutA gene), enzyme III (product of the gutB gene), and glucitol-6-phosphate dehydrogenase (product of the gutD gene) were about 46,000, 13,500, and 27,000, respectively, as estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis.     

Structures of revertant signal sequences of Escherichia coli ribose binding protein.

Recently we reported (Yi et al., 1994) that the alpha-helical content of the signal peptide of Escherichia coli ribose binding protein, when determined by circular dichroism (CD) and two-dimensional NMR in trifluoroethanol/water solvent, is higher than that of its nonfunctional mutant signal peptide. In the present investigation, the structures of the signal peptides of two revertant ribose binding proteins in the same solvent were also determined with CD and two-dimensional 1H NMR spectroscopy. According to the CD results, both of these revertant signal peptides showed an intermediate helicity between those of wild-type and mutant signal peptides, the helical content of the revertant peptide with higher recovery of the translocation capability being higher. On the other hand, the alpha-helix regions of the wild-type and the revertant peptides as determined by NMR were shown to be the same. This discrepancy may be due to the difference in stability between identical alpha-helical stretches in wild-type and revertant peptides. A good correlation was observed between the helical content of these four ribose binding protein signal peptides in TFE/water as studied by CD and their in vivo translocation activities. It appears, therefore, that both the proper length of the helix and the stability are of functional significance.     

Periplasmic protein associated with the oligopeptide permeases of Salmonella typhimurium and Escherichia coli.

A periplasmic protein essential for the function of the oligopeptide transport system of Salmonella typhimurium was identified. This protein, encoded by the oppA gene, is one of the most abundant proteins in the periplasm and, with an apparent molecular weight of 52,000, is considerably larger than any other known periplasmic transport component. A similarly abundant periplasmic protein forms part of the oligopeptide transport system of Escherichia coli.     

Structures of wild-type and mutant signal sequences of Escherichia coli ribose binding protein.

The structure of a chemically synthesized 25-residue-long functional signal peptide of Escherichia coli ribose binding protein was compared with that of a nonfunctional mutant-signal peptide using circular dichroism and two-dimensional 1H NMR in solvents mimicking the amphiphilic environments. The functional peptide forms an 18-residue-long alpha-helix starting from the NH2-terminal region and reaching to the hydrophobic stretch in a solvent consisting of 10% dimethylsulfoxide, 40% water, and 50% trifluoroethanol (v/v). The nonfunctional mutant peptide, which contains a Pro at position 9 instead of a Leu in the wild-type peptide, does not have any secondary structure in that solvent but forms a 12-residue-long alpha-helix within the hydrophobic stretch in water/trifluoroethanol (50:50, v/v) solvent. It seems that the Pro-9 residue in the nonfunctional peptide disturbs the helix propagation from the hydrophobic stretch to the NH2-terminal region. Because both of these peptides have stable helices within the hydrophobic stretch, it may be concluded that the additional 2 turns of the alpha-helix in the NH2-terminal region of the wild-type signal peptide is important for its function.     

Regulation of gluconeogenesis by the glucitol enzyme III of the phosphotransferase system in Escherichia coli.

The gut operon was subcloned into various plasmid vectors (M. Yamada and M. H. Saier, Jr., J. Bacteriol. 169:2990-2994, 1987). Constitutive expression of the plasmid-encoded operon prevented utilization of alanine and Krebs cycle intermediates when they were provided as sole sources of carbon for growth. Expression of the gutB gene alone (encoding the glucitol enzyme III), subcloned downstream from either the lactose promoter or the tetracycline resistance promoter, inhibited utilization of the same compounds. On the other hand, overexpression of the gutA gene (encoding the glucitol enzyme II) inhibited the utilization of a variety of sugars as well as alanine and Krebs cycle intermediates by an apparently distinct mechanism. Phosphoenolpyruvate carboxykinase activity was greatly reduced in cells expressing high levels of the cloned gutB gene but was nearly normal in cells expressing high levels of the gutA gene. A chromosomal mutation in the gutR gene, which gave rise to constitutive expression of the chromosomal gut operon, also gave rise to growth inhibition on gluconeogenic substrates as well as reduced phosphoenolpyruvate carboxykinase activity. Phosphoenolpyruvate synthase activity in general varied in parallel with that of phosphoenolpyruvate carboxykinase. These results suggest that high-level expression of the glucitol enzyme III of the phosphotransferase system can negatively regulate gluconeogenesis by repression or inhibition of the two key gluconeogenic enzymes, phosphoenolpyruvate carboxykinase and phosphoenolpyruvate synthase.     

Nucleotide sequence and expression of the gutQ gene within the glucitol operon of Escherichia coli

The glucitol operon in Escherichia coli is known to consist of five structural genes with the order: gut O P A B D M R. We have sequenced downstream from gutR and have identified an open reading frame encoding a water-soluble protein (223 amino acids; molecular weight = 23,562) with a putative ATP binding site. Expression of this protein in a maxicell system has been demonstrated. A repetitive extragenic palindromic (REP) sequence capable of forming stem-loop structures follows gutQ in the downstream, presumptive intercistronic region. The function of the Gut Q protein is not known.     

SurA assists the folding of Escherichia coli outer membrane proteins.

Many proteins require enzymatic assistance in order to achieve a functional conformation. One rate-limiting step in protein folding is the cis-trans isomerization of prolyl residues, a reaction catalyzed by prolyl isomerases. SurA, a periplasmic protein of Escherichia coli, has sequence similarity with the prolyl isomerase parvulin. We tested whether SurA was involved in folding periplasmic and outer membrane proteins by using trypsin sensitivity as an assay for protein conformation. We determined that the efficient folding of three outer membrane proteins (OmpA, OmpF, and LamB) requires SurA in vivo, while the folding of four periplasmic proteins was independent of SurA. We conclude that SurA assists in the folding of certain secreted proteins.     

Sugar recognition by the glucose and mannose permeases of Escherichia coli. Steady-state kinetics and inhibition studies

The glucose (EII(Glc)) and mannose (EII(Man)) permeases of the phosphoenolpyruvate:sugar phosphotransferase system (PTS) of Escherichia coli belong to structurally different families of PTS transporters. The sugar recognition mechanism of the two transporters is compared using as inhibitors and pseudosubstrates all possible monodeoxy analogues, monodeoxyfluoro analogues, and epimers of D-glucose. The analogues were tested as phosphoryl acceptors in vitro and as uptake inhibitors with intact cells. Both EII have a high K(m) of phosphorylation for glucose modified at C-4 and C-6, and these analogues also are weak inhibitors of uptake. Conversely, modifications at C-1 (and also at C-2 with EII(Man)) were well tolerated. OH-3 is proposed to interact with hydrogen bond donors on EII(Glc) and EII(Man), since only substitution by fluorine was tolerated. Glucose-6-aldehydes, which exist as gem-diols in aqueous solution, are potent and highly selective inhibitors of "nonvectorial" phosphorylation by EII(Glc) (K(I) 3-250 microM). These aldehydes are comparatively weak inhibitors of transport by EII(Glc) and of phosphorylation and transport by EII(Man). Both transporters display biphasic kinetics (with glucose and some analogues) but simple Michaelis-Menten kinetics with 3-fluoroglucose (and other analogues). Kinetic simulations of the phosphorylation activities measured with different substrates and inhibitors indicate that two independent activities are present at the cytoplasmic side of the transporter. A working model that accounts for the kinetic data is presented.     

Protein folding in the periplasm of Escherichia coli

With the discovery of molecular chaperones and the development of heterologous gene expression techniques, protein folding in bacteria has come into focus as a potentially limiting factor in expression and as a topic of interest in its own right. Many proteins of importance in biotechnology contain disulphide bonds, which form in the Escherichia coli periplasm, but most work on protein folding in the periplasm of E. coli is very recent and is often speculative. This MicroReview gives a short overview of the possible fates of a periplasmic protein from the moment it is translocated, as well as of the E. coli proteins involved in this process. After an introduction to the specific physiological situation in the periplasm of E. coli, we discuss the proteins that might help other proteins to obtain their correctly folded conformation — disulphide isomerase, rotamase, parts of the translocation apparatus and putative periplasmic chaperones — and briefly cover the guided assembly of multi-subunit structures. Finally, our MicroReview turns to the fate of misfolded proteins: degradation by periplasmic proteases and aggregation phenomena.     

Role of amino-terminal positive charge on signal peptide in staphylokinase export across the cytoplasmic membrane of Escherichia coli

Staphylokinase mutants having amino acid substitutions within the amino-terminal charged segment of the signal peptide have been produced by in vitro oligonucleotide-directed mutagenesis. When the processing of the gene products was analyzed in Escherichia coli cells, the rate of processing of the mutant staphylokinase precursor decreased as the net charge became more negative. A net positive charge, but not specific amino acid residues, was required on the amino-terminal segment for efficient processing. Staphylokinase precursor having a net negative charge accumulated in the cytoplasm, tending to bind to the cytoplasmic membrane as determined by subcellular fractionation and immunoelectron microscopy. Although a mutant carrying an amino acid substitution in the hydrophobic segment and wild-type staphylokinases had an interfering effect on the processing of other normal secreted proteins, this effect was lost when they also contained charge-altering substitutions in the amino-terminal region. From these results, we concluded that a positive charge on the amino-terminal segment of the staphylokinase signal peptide is required for entrance into the protein export process.     

Disulfide-dependent folding and export of Escherichia coli DsbC

DsbC, a member of the Dsb family in the periplasm of Gram-negative bacteria, is not only a disulfide isomerase but also a chaperone. Five DsbC mutants with Cys in the active site sequence of Cys(98)-Gly-Tyr-Cys(101) and the nonactive site disulfide Cys(141)-Cys(163) replaced by Ser have been studied. The results show that the active site Cys residues are necessary for enzyme activities but not required for chaperone activity, while the lack of the nonactive site disulfide results in a decreased chaperone activity in assisting the reactivation of denatured d-glyceraldehyde-3-phosphate dehydrogenase but has no effect on enzyme activities. Wild-type DsbC was overexpressed and correctly processed as a soluble periplasmic protein. Mutation in one of these Cys residues results in aggregation or extracellular/membrane locations, but does not affect the proper processing. DsbC mutated in either Cys residue of nonactive site disulfide shows higher sensitivity to unfolding by guanidine hydrochloride and slower refolding compared with wild-type DsbC and the active site Cys mutants. The above results provide experimental evidence for structural role of the nonactive site disulfide in folding and biological activities of DsbC.     

Conformational features of signal sequences and folding of secretory proteins in yeasts.

A yeast secretion system has been used extensively for the production of eukaryotic proteins that are expressed as non-native aggregates in E. coli. Secretory proteins translocate through the membrane using signal sequences, and fold in the cells (probably with the aid of several molecular chaperones). In combination with recent techniques of mutagenesis, this system has recently been implemented to study structure/function in signal sequences, and in vivo folding mechanisms of proteins. This review focuses on approaches to conformational features of signal sequences and folding of secretory proteins in yeasts.     

Stability and interactions of the amino-terminal domain of ClpB from Escherichia coli

ClpB is a member of a multichaperone system in Escherichia coli (with DnaK, DnaJ, and GrpE) that reactivates aggregated proteins. The sequence of ClpB contains two ATP-binding regions that are enclosed between the N- and C-terminal extensions. Whereas it has been found that the N-terminal region of ClpB is essential for the chaperone activity, the structure of this region is not known, and its biochemical properties have not been studied. We expressed and purified the N-terminal fragment of ClpB (residues 1-147). Circular dichroism of the isolated N-terminal region showed a high content of alpha-helical structure. Differential scanning calorimetry showed that the N-terminal region of ClpB is thermodynamically stable and contains a single folding domain. The N-terminal domain is monomeric, as determined by gel-filtration chromatography, and the elution profile of the N-terminal domain does not change in the presence of the N-terminally truncated ClpB (ClpBDeltaN). This indicates that the N-terminal domain does not form strong contacts with ClpBDeltaN. Consistently, addition of the separated N-terminal domain does not reverse an inhibition of ATPase activity of ClpBDeltaN in the presence of casein. As shown by ELISA measurements, full-length ClpB and ClpBDeltaN bind protein substrates (casein, inactivated luciferase) with similar affinity. We also found that the isolated N-terminal domain of ClpB interacts with heat-inactivated luciferase. Taken together, our results indicate that the N-terminal fragment of ClpB forms a distinct domain that is not strongly associated with the ClpB core and is not required for ClpB interactions with other proteins, but may be involved in recognition of protein substrates.     

Effect of charged residue substitutions on the membrane-interactive properties of signal sequences of the Escherichia coli LamB protein.

Although the central role of the signal sequence in protein export is well established, the molecular details underlying signal sequence in vivo function remain unclear. As part of our continuing effort to relate signal sequence phenotypes to specific biophysical properties, we have carried out an extensive characterization of the secondary structure and lipid interactions for a family of peptides corresponding to the wild-type E. coli LamB signal sequence, and mutants that harbor charged residue point mutations in the hydrophobic core region. We used membrane-resident fluorescence quenching according to the parallax method to determine the relative depth of insertion of tryptophan-labeled analogs of these peptides into the acyl chain region of bilayer vesicles composed of 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphoethanolamine and 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphoglycerol. Also, restriction of acyl chain motion upon peptide binding was evaluated using steady-state fluorescence anisotropy of 1,6-diphenyl-1,3,5-hexatriene. Each of these peptides showed evidence of insertion into the acyl chain region, although most likely not in a transmembrane orientation. The mutant peptides were shown to have a reduced insertion potential relative to the wild-type peptide. Furthermore, tryptophan spectral properties indicated that insertion of the wild-type and mutant peptides enhances bilayer hydration. This effect was particularly pronounced with peptides harboring negatively charged aspartate point substitutions. The results are discussed in relation to the potential roles of signal sequences in mediating protein translocation.     

Recombinant protein folding and misfolding in Escherichia coli

The past 20 years have seen enormous progress in the understanding of the mechanisms used by the enteric bacterium Escherichia coli to promote protein folding, support protein translocation and handle protein misfolding. Insights from these studies have been exploited to tackle the problems of inclusion body formation, proteolytic degradation and disulfide bond generation that have long impeded the production of complex heterologous proteins in a properly folded and biologically active form. The application of this information to industrial processes, together with emerging strategies for creating designer folding modulators and performing glycosylation all but guarantee that E. coli will remain an important host for the production of both commodity and high value added proteins.