Intragenic reversion mutations that improve export of maltose-binding protein in Escherichia coli malE signal sequence mutants

Escherichia coli strains harboring malE signal sequence point mutations accumulate export-defective precursor maltose-binding protein (MBP) in the cytoplasm. Beginning with these mutants, a number of spontaneous intragenic revertants have been obtained in which export of the MBP to the periplasm is either partially or totally restored. With a single exception, each of the reversion mutations resulted in an increase in the overall hydrophobicity of the signal peptide hydrophobic core by one of five different mechanisms. In some revertants, MBP export was achieved at a rate comparable to the wild type MBP; in other cases, the rate of MBP export was significantly slower than wild type. The results indicate that the overall hydrophobicity of the signal peptide, rather than the absolute length of its uninterrupted hydrophobic core, is a major determinant of MBP export competency. An alteration at residue 19 of the mature MBP also has been identified that provides fairly efficient suppression of the export defect in the adjacent signal peptide, further suggesting that important export information may reside in this region of the precursor protein.     

Regions of maltose-binding protein that influence SecB-dependent and SecA-dependent export in Escherichia coli.

In Escherichia coli, the efficient export of maltose-binding protein (MBP) is dependent on the chaperone SecB, whereas export of ribose-binding protein (RBP) is SecB independent. To localize the regions of MBP involved in interaction with SecB, hybrids between MBP and RBP in SecB mutant cells were constructed and analyzed. One hybrid consisted of the signal peptide and first third of the mature moiety of MBP, followed by the C-terminal two-thirds of RBP (MBP-RBP112). This hybrid was dependent upon SecB for its efficient export and exhibited a strong export defect in secA mutant cells. A hybrid between RBP and MBP with the same fusion point was also constructed (RBP-MBP116). The RBP-MBP116 hybrid remained SecB independent and only exhibited a partial export defect in secA mutant cells. In addition, MBP species with specific alterations in the early mature region were less dependent on SecB for their efficient export. The export of these altered MBP species was also less affected in secA mutant cells and in cells treated with sodium azide. These results present additional evidence for the targeting role of SecB.     

prlA suppression of defective export of maltose-binding protein in secB mutants of Escherichia coli.

An Escherichia coli strain containing a signal sequence mutation in the periplasmic maltose-binding protein (MBP) (malE18-1) and a point mutation in the soluble export factor SecB (secBL75Q) is completely defective in export of MBP and unable to grow on maltose (Mal- phenotype). We isolated 95 spontaneous Mal+ revertants and characterized them genetically. Three types of extragenic suppressors were identified: informational (missense) suppressors, a bypass suppressor conferring the Mal+ phenotype in the absence of MBP, and suppressors affecting the prlA gene, which encodes a component of the protein export apparatus. In this study, a novel prlA allele, designated prlA1001 and mapping in the putative second transmembrane domain of the PrlA (SecY) protein, was found. In addition, we isolated a mutation designated prlA1024 which is identical to prlA4-2, the mutation responsible for the signal sequence suppression in the prlA4 (prlA4-1 prlA4-2) double mutant (T. Sako and T. Iino, J. Bacteriol. 170:5389-5391, 1988). Comparison of the prlA1024 mutant and the prlA4 double mutant provides a possible explanation for the isolation of these prlA alleles.     

Export of unprocessed precursor maltose-binding protein to the periplasm of Escherichia coli cells.

The Escherichia coli maltose-binding protein (MBP) R2 signal peptide is a truncated version of the wild-type structure that still facilitates very efficient export of MBP to the periplasm. Among single amino acid substitutions in the R2 signal peptide resulting in an export-defective precursor MBP (pMBP) were two that replaced residues in the consensus Ala-X-Ala sequence (residues -3 to -1) that immediately precedes the cleavage site. It was suggested that the functional hydrophobic core and signal peptidase recognition sequence of this signal peptide substantially overlap and that these two alterations affect both pMBP translocation and processing. In this study, the export of pMBP by the mutants, designated CC15 and CC17, with these two alterations was investigated further. The pMBP of mutant CC17 has an Arg substituted for Leu at the -2 position. It was found that CC17 cells exported only a very small amount of MBP, but that which was exported appeared to be correctly processed. This result was consistent with other studies that have concluded that virtually any amino acid can occupy the -2 position. For mutant CC15, which exhibits a fully Mal+ phenotype, an Asp is substituted for the Ala at the -3 position. CC15 cells were found to export large quantities of unprocessed, soluble pMBP to the periplasm, although such export was achieved in a relatively slow, posttranslational manner. This result was also consistent with other studies that suggested that charged residues are normally excluded from the -3 position of the cleavage site. Using in vitro oligonucleotide-directed mutagenesis, we constructed a new signal sequence mutant in which Asp was substituted for Arg at the -3 position of an otherwise wild-type MBP signal peptide. This alteration had no apparent effect on pMBP translocation across the cytoplasmic membrane, but processing by signal peptidase was inhibited. This pMBP species with its full-length hydrophobic core remained anchored to the membrane, where it could still participate in maltose uptake. The implications of these results for models of protein export are discussed.     

Mutations in maltose-binding protein that alter affinity and solubility properties

Maltose-binding protein (MBP) from Escherichia coli has been shown to be a good substrate for protein engineering leading to altered binding (Marvin and Hellinga, Proc Natl Acad Sci U S A 98:4955–4960, 2001a) and increased affinity (Marvin and Hellinga, Nat Struct Biol 8:795–798, 2001b; Telmer and Shilton, J Biol Chem 278:34555–34567, 2003). It is also used in recombinant protein expression as both an affinity tag and a solubility tag. We isolated mutations in MBP that enhance binding to maltodextrins 1.3 to 15-fold, using random mutagenesis followed by screening for enhanced yield in a microplate-based affinity purification. We tested the mutations for their ability to enhance the yield of a fusion protein that binds poorly to immobilized amylose and their ability to enhance the solubility of one or more aggregation-prone recombinant proteins. We also measured dissociation constants of the mutant MBPs that retain the solubility-enhancing properties of MBP and combined two of the mutations to produce an MBP with a dissociation constant 10-fold tighter than wild-type MBP. Some of the mutations we obtained can be rationalized based on the previous work, while others indicate new ways in which the function of MBP can be modified.     

Mutations that affect the folding of ribose-binding protein selected as suppressors of a defect in export in Escherichia coli

It has been proposed (Randall, L. L., and Hardy, S. J. S. (1986) Cell 46, 921-928) that export of protein involves a kinetic partitioning between the pathway that leads to productive export and the pathway that leads to the folding of polypeptides into a stable conformation that is incompatible with export. As predicted from this model, a decrease in the rate of export of maltose-binding protein to the periplasmic space in Escherichia coli resulting from a defect in the leader sequence was able to be partially overcome by a mutation that slowed the folding of the precursor, thereby increasing the time in which the polypeptide was competent for export. (Liu, G., Topping, T. B., Cover, W. H., and Randall, L. L. (1988) J. Biol. Chem. 263, 14790-14793). Here we describe mutations of the gene encoding ribose-binding protein that were selected as suppressors of a defect in export of that protein and that alter the folding pathway. We propose that selection of such suppressors may provide a general method to obtain mutations that affect the folding properties of any protein that can be expressed and exported in E. coli.     

Thirty-three amino acids of the mature moiety of an unprocessed maltose-binding protein are sufficient for export in Escherichia coli.

Maltose-binding protein (MBP) is translocated across the cytoplasmic membrane of Escherichia coli; successful export depends on information in both the signal peptide and the mature moiety of the protein. To determine the shortest portion of the mature region that would maintain detectable entry of MBP into the export pathway, we took advantage of the properties of an MBP species with proline substituted in the +1 position relative to the cleavage site (MBP27-P). This protein efficiently crosses the cytoplasmic membrane but is not processed and acts as a competitive inhibitor of signal peptidase I (leader peptidase). Export of MBP27-P is measured by the inhibition of processing of other proteins, such as ribose-binding protein (RBP). A series of truncated derivatives of MBP27-P were tested for the ability to inhibit processing of RBP. An MBP27-P species with only 33 amino acids of the mature moiety inhibited processing of RBP, indicating that this truncated polypeptide was probably exported and interacted with signal peptidase I.     

Interaction of the maltose-binding protein with membrane vesicles of Escherichia coli.

The interaction of the radioactively labeled purified maltose-binding protein of Escherichia coli with membrane vesicles was studied. The maltose-binding protein bound specifically to the vesicles, in the presence of maltose, on few sites. Under conditions in which a potential was imposed across the membrane, the specific binding was (i) increased, (ii) dependent on maltose, and (iii) abolished in a mutant defective in the tar gene product, one of the methyl-accepting chemotaxis proteins. At least 1,300 binding sites were present in the membrane fraction of logarithmically growing cells.     

Novel secA alleles improve export of maltose-binding protein synthesized with a defective signal peptide.

Mutations previously designated prlD were described that suppressed malE signal sequence mutations and were located in the vicinity of the secA gene on the Escherichia coli chromosome. In this study, we demonstrated that four such independently isolated prlD mutations represented three unique single-base substitutions in secA, resulting in alterations at residues 111, 373, and 488 of the 901-residue SecA protein. Heretofore, the only mutations that had been described for secA were located early in the gene and resulted in a general protein export defect. Insertion mutations in the cloned gene X-secA operon that reduced or eliminated suppression by a prlD mutation also have been obtained. The properties of these suppressor and insertion mutations provide some insight into the role of SecA in the protein export process.     

Active transport of maltose in membrane vesicles obtained from Escherichia coli cells producing tethered maltose-binding protein.

Attempts to reconstitute periplasmic binding protein-dependent transport activity in membrane vesicles have often resulted in systems with poor and rather inconsistent activity, possibly because of the need to add a large excess of purified binding protein to the vesicles. We circumvented this difficulty by using a mutant which produces a precursor maltose-binding protein that is translocated across the cytoplasmic membrane but is not cleaved by the signal peptidase (J. D. Fikes and P. J. Bassford, Jr., J. Bacteriol. 169:2352-2359, 1987). The protein remains tethered to the cytoplasmic membrane, presumably through the hydrophobic signal sequence, and we show here that the spheroplasts and membrane vesicles prepared from this mutant catalyze active maltose transport without the addition of purified maltose-binding protein. In vesicles, the transport requires electron donors, such as ascorbate and phenazine methosulfate or D-lactate. However, inhibition by dicyclohexylcarbodiimide and stimulation of transport by the inculsion of ADP or ATP in the intravesicular space suggest that ATP (or compounds derived from it) is involved in the energization of the transport. The transport activity of intact cells can be recovered without much inactivation in the vesicles, and their high activity and ease of preparation will be useful in studies of the mechanism of the binding protein-dependent transport process.     

Mutations that alter the allosteric nature of cAMP receptor protein of Escherichia coli.

Mutations which permit cAMP binding protein (CRP) to act in the absence of cAMP have been isolated by in vitro mutagenesis of a plasmid containing the cloned crp gene. Adenylate cyclase deficient cells harbouring the mutant (crp*) plasmids exhibited a variety of fermentation profiles on MacConkey indicator plates containing various sugars. beta-galactosidase synthesis in cells carrying the crp* plasmids was activated most by the addition of cGMP as well as cAMP. The sites of mutations which are responsible for the cAMP independent phenotype were determined by in vitro recombination and DNA sequencing. The amino acid substitutions in the mutant proteins were found in two specific regions of the crp gene encoding residues 53-62 and 141-148 of CRP polypeptide. The first region may participate in cAMP binding, while the second appears to be the inter-domain region of the N-terminal cAMP-binding and C-terminal DNA-binding domains.     

The mature portion of Escherichia coli maltose-binding protein (MBP) determines the dependence of MBP on SecB for export.

The product of the secB gene is required for export of a subset of secreted proteins to the outer membrane and periplasm of Escherichia coli. Precursor maltose-binding protein (MBP) accumulates in the cytoplasm of secB-carrying mutants, but export of alkaline phosphatase is only minimally affected by secB mutations. When export of MBP-alkaline phosphatase hybrid proteins was analyzed in wild-type and secB-carrying mutant strains, the first third of mature MBP was sufficient to render export of the hybrid proteins dependent on SecB. Substitution of a signal sequence from a SecB-independent protein had no effect on SecB-dependent export. These findings show that the first third of mature MBP is capable of conferring export incompetence on an otherwise competent protein.     

The antifolding activity of SecB promotes the export of the E. coli maltose-binding protein

Evidence is presented that the E. coli secB gene encodes a soluble protein that interacts with the mature region of the precursor maltose-binding protein (MBP), and promotes MBP export by preventing premature folding of the newly synthesized polypeptide into an export-incompetent form. The interaction of SecB with MBP was indicated by the finding that synthesis of various export-defective MBP species interfered with normal protein export by limiting SecB availability. The antifolding activity of SecB was demonstrated by the following: the defect in MBP export in SecB- cells was suppressed by mutational alterations affecting MBP folding; export of a mutant MBP that is accomplished in a strictly posttranslational mode was totally blocked in SecB- cells; and the rate of folding of wild-type MBP synthesized in vitro was found to be accelerated when SecB was absent and greatly retarded when excess SecB was present.     

Escherichia coli sec mutants accumulate a processed immature form of maltose-binding protein (MBP), a late-phase intermediate in MBP export.

Protein translocation across the Escherichia coli cytoplasmic membrane may consist of several temporally or topographically distinct steps. Although early events in the translocation pathway have been characterized to some extent, the mechanisms responsible for the trans-bilayer movement of a polypeptide are only poorly understood. This article reports on our attempts to dissect the translocation pathway in vivo. A processed form of maltose-binding protein (MBP) was detected in the spheroplasts of secY and secA temperature-sensitive mutant cells that had been pulse-labeled at the permissive temperature (30 degrees C). This species of molecule was found to have an electrophoretic mobility identical to that of the mature MBP, but a considerable fraction of it was inaccessible to externally added protease. It had not attained the protease-resistant conformation characteristically observed for the exported mature protein. The radioactivity associated with this species decreased during chase and was presumably converted into the exported mature form, a process that required energy, probably the proton motive force, as demonstrated by its inhibition by an energy uncoupler. The spheroplast-associated processed form was more predominantly observed in the presence of a low concentration of chloramphenicol. A similar intermediate was also detected for beta-lactamase in wild-type cells. These results suggest that in a late phase of translocation, the bulk of the polypeptide chain can move through the membrane in the absence of the covalently attached leader peptide, and the secA-secY gene products are somehow involved in this process. We termed the processed intermediates processed immature forms.     

SecB-independent export of Escherichia coli ribose-binding protein (RBP): some comparisons with export of maltose-binding protein (MBP) and studies with RBP-MBP hybrid proteins.

The efficient export of the Escherichia coli maltose-binding protein (MBP) is known to be SecB dependent, whereas ribose-binding protein (RBP) export is SecB independent. When the MBP and RBP signal peptides were exchanged precisely at the signal peptidase processing sites, the resultant RBP-MBP and MBP-RBP hybrid proteins both were efficiently exported in SecB+ cells. However, only MBP-RBP was efficiently exported in SecB- cells; RBP-MBP exhibited a significant export defect, a finding that was consistent with previous proposals that SecB specifically interacts with the mature moiety of precursor MBP to promote export. The relatively slow, totally posttranslational export mode exhibited by certain mutant RBP and MBP-RBP species in SecB+ cells was not affected by the loss of SecB. In contrast, MBP and RBP-MBP species with similarly altered signal peptides were totally export defective in SecB- cells. Both export-defective MBP and RBP-MBP interfered with SecB-mediated protein export by depleting cells of functional SecB. In contrast, neither export-defective RBP nor MBP-RBP elicited such an interference effect. These and other data indicated that SecB is unable to interact with precursor RBP or that any interaction between these two proteins is considerably weaker than that of SecB with precursor MBP. In addition, no correlation could be established between a SecB requirement for export and PrlA-mediated suppression of signal peptide export defects. Finally, previous studies have established that wild-type MBP export can be accomplished cotranslationally, whereas wild-type RBP export is strictly a posttranslational process. In this study, cotranslational export was not detected for either MBP-RBP or RBP-MBP. This indicates that the export mode exhibited by a given precursor protein (cotranslational versus posttranslational) is determined by properties of both the signal peptide and the mature moiety.     

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.     

Electrochemical potential releases a membrane-bound secretion intermediate of maltose-binding protein in Escherichia coli.

A secretionary intermediate of the Escherichia coli maltose-binding protein accumulated in the inner membrane when the membrane electrochemical potential was reduced and the cytosolic ATP concentration was normal. The intermediate was mature in size, but maintained a conformation similar to the cytosolic precursor form, and not the mature periplasmic protein, as measured by differences in susceptibility to proteinase K in vitro. The intermediate was located on the periplasmic side of the inner membrane. Restoration of the membrane electrochemical potential resulted in the movement of the intermediate from the inner membrane to the periplasm. In other experiments in which the ATP concentration was reduced by 96% and the electrochemical potential remained normal, no intermediate accumulated. Thus, the final step in the export of maltose-binding protein requires the electrochemical potential of the inner membrane and does not require ATP.     

SecD and SecF facilitate protein export in Escherichia coli.

We show here that the rate of protein translocation in the bacterium Escherichia coli depends on the levels of the SecD and SecF proteins in the cell. Overexpression of SecD and SecF stimulates translocation in wild type cells and improves export of proteins with mutant signal sequences. Depletion of SecD and SecF from the cell greatly reduces but does not abolish protein translocation. A secDF::kan null mutant deleted for the genes encoding both proteins is cold-sensitive for growth and protein export, has a severe export defect at 37 degrees C and is barely viable. The phenotypes of a secD null mutant and a secF null mutant are identical to the secDF::kan double null mutant. These results partially resolve the conflict between genetic studies and results from in vitro translocation systems which do not require SecD and SecF for activity, affirm the importance of these proteins to the export process, and suggest that SecD and SecF function together to stimulate protein export in a role fundamentally different from other Sec proteins. Our results provide additional support for the notion that an early step in protein export is cold-sensitive.