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.     

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.     

Mutational alterations affecting the export competence of a truncated but fully functional maltose-binding protein signal peptide.

The wild-type maltose-binding protein (MBP) signal peptide is 26 amino acids in length. A mutationally altered MBP signal peptide has been previously described that is missing one of the basic residues from the hydrophilic segment and seven residues from the hydrophobic core; however, it still facilitates MBP secretion to the periplasm at a rate and efficiency comparable to those of the wild-type structure. Thus, this truncated signal peptide (designated the R2 signal peptide) must retain all of the essential features required for proper export function. In this study, alterations were obtained in the R2 signal peptide that resulted in an export-defective MBP. For the first time, signal sequence mutations were obtained that resulted in the synthesis of a totally export-defective MBP. As was previously the case for the wild-type signal peptide, the introduction of either charged residues or helix-breaking proline residues adversely affected export function. Despite these similarities, the position of these alterations within the R2 signal peptide, their relative effects on MBP secretion and processing, and an analysis of the ability of various extragenic prl mutations to suppress the secretion defects provide additional insight into the minimal requirements for a functional MBP signal peptide.     

Analysis of mutational alterations in the hydrophilic segment of the maltose-binding protein signal peptide.

Oligonucleotide-directed mutagenesis was employed to investigate the role of the hydrophilic segment of the Escherichia coli maltose-binding protein (MBP) signal peptide in the protein export process. The three basic residues residing at the amino terminus of the signal peptide were systematically substituted with neutral or acidic residues, decreasing the net charge in a stepwise fashion from +3 to -3. It was found that a net positive charge was not absolutely required for MBP export to the periplasm. However, export was most rapid and efficient when the signal peptide retained at least a single basic residue and a net charge of +1. The nature of the adjacent hydrophobic core helped to determine the effect of charge changes in the hydrophilic segment on MBP export, which suggested that these two regions of the signal peptide do not have totally distinct functions. Although the stepwise decrease in net charge of the signal peptide also resulted in a progressive decrease in the level of MBP synthesis, the data do not readily support a model in which MBP synthesis and export are obligately coupled events. The export defect resulting from alterations in the hydrophilic segment was partially suppressed in strains harboring certain prl alleles but not in strains harboring prlA alleles that are highly efficient suppressors of signal sequence mutations that alter the hydrophobic core.     

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.     

Mutations that improve export of maltose-binding protein in SecB- cells of Escherichia coli.

It previously has been proposed that the Escherichia coli SecB protein promotes the export of the maltose-binding protein (MBP) from the cytoplasm by preventing the folding of the precursor MBP (preMBP) into a translocation-incompetent conformation. The export of wild-type MBP is only partially blocked in SecB- cells. In contrast, the export of MBP16-1, an MBP species with a defective signal peptide, is totally dependent on SecB; hence, SecB- cells that synthesize MBP16-1 are unable to utilize maltose as a sole carbon source. The selection of Mal+ revertants primarily yielded mutants with alterations in the MBP16-1 signal peptide that permitted SecB-independent MBP export to the periplasm to various extents. Although each of these alterations increased the overall hydrophobicity of the signal peptide, it was not possible to strictly equate changes in hydrophobicity with the degree of SecB-independent export. Somewhat unexpectedly, two mutants were obtained in which MBP export in SecB- cells was markedly superior to that of the wild-type MBP. Although wild-type MBP is not cotranslationally translocated in SecB- cells, the two mutant proteins designated MBP172 and MBP173 exhibited significant cotranslational export in the absence of SecB. Thus, the role of SecB was partially supplanted by a signal peptide that promoted more rapid movement of MBP through the export pathway. When preMBP included the MBP172 signal peptide as well as an alteration in the mature moiety that slows folding, the SecB requirement for maximal MBP export efficiency was almost totally eliminated. These results provide additional strong support for the proposed antifolding role of SecB in MBP export.     

Silent and functional changes in the periplasmic maltose-binding protein of Escherichia coli K12. I. Transport of maltose

The malE gene encodes the periplasmic maltose-binding protein (MBP). Nineteen mutations that still permit synthesis of stable MBP were generated by random insertion of a BamHI octanucleotide into malE and six additional mutations by in-vitro recombinations between mutant genes. The sequence changes were determined; in most cases the linker insertion is accompanied by a small deletion (30 base-pairs on average). The mutant MBP were studied for export, growth on maltose and maltodextrins, maltose transport and binding, and maltose-induced fluorescence changes. Sixteen mutant MBP (out of 21 studied in detail) were found in the periplasmic space: 12 of them retained a high affinity for maltose, and 10 activity for growth on maltose. The results show that several regions of MBP are dispensable for stability, substrate binding and export. Three regions (residues 207 to 220, 297 to 303 and 364 to 370) may be involved in interactions with the MalF or MalG proteins. A region near the C-terminal end is important for maltose binding. Two regions of the mature protein (residues 18 to 42 and 280 to 296) are required for export to, or solubility in, the periplasm.     

Maltose-binding protein interacts simultaneously and asymmetrically with both subunits of the Tar chemoreceptor

The Tar chemotactic signal transducer of Escherichia coli mediates attractant responses to L-aspartate and to maltose. Aspartate binds across the subunit interface of the periplasmic receptor domain of a Tar homodimer. Maltose, in contrast, first binds to the periplasmic maltose-binding protein (MBP), which in its ligand-stabilized closed form then interacts with Tar. Intragenic complementation was used to determine the MBP-binding site on the Tar dimer. Mutations causing certain substitutions at residues Tyr-143, Asn-145, Gly-147, Tyr-149, and Phe-150 of Tar lead to severe defects in maltose chemotaxis, as do certain mutations affecting residues Arg-73, Met-76, Asp-77, and Ser-83. These two sets of mutations defined two complementation groups when the defective proteins were co-expressed at equal levels from compatible plasmids. We conclude that MBP contacts both subunits of the Tar dimer simultaneously and asymmetrically. Mutations affecting Met-75 could not be complemented, suggesting that this residue is important for association of MBP with each subunit of the Tar dimer. When the residues involved in interaction with MBP were mapped onto the crystal structure of the Tar periplasmic domain, they localized to a groove at the membrane-distal apex of the domain and also extended onto one shoulder of the apical region.     

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.     

Export of maltose-binding protein species with altered charge distribution surrounding the signal peptide hydrophobic core in Escherichia coli cells harboring prl suppressor mutations.

It is believed that one or more basic residues at the extreme amino terminus of precursor proteins and the lack of a net positive charge immediately following the signal peptide act as topological determinants that promote the insertion of the signal peptide hydrophobic core into the cytoplasmic membrane of Escherichia coli cells with the correct orientation required to initiate the protein export process. The export efficiency of precursor maltose-binding protein (pre-MBP) was found to decrease progressively as the net charge in the early mature region was increased systematically from 0 to +4. This inhibitory effect could be further exacerbated by reducing the net charge in the signal peptide to below 0. One such MBP species, designated MBP-3/+3 and having a net charge of -3 in the signal peptide and +3 in the early mature region, was totally export defective. Revertants in which MBP-3/+3 export was restored were found to harbor mutations in the prlA (secY) gene, encoding a key component of the E. coli protein export machinery. One such mutation, prlA666, was extensively characterized and shown to be a particularly strong suppressor of a variety of MBP export defects. Export of MBP-3/+3 and other MBP species with charge alterations in the early mature region also was substantially improved in E. coli cells harboring certain other prlA mutations originally selected as extragenic suppressors of signal sequence mutations altering the hydrophobic core of the LamB or MBP signal peptide. In addition, the enzymatic activity of alkaline phosphatase (PhoA) fused to a predicted cytoplasmic domain of an integral membrane protein (UhpT) increased significantly in cells harboring prlA666. These results suggest a role for PrlA/SecY in determining the orientation of signal peptides and possibly other membrane-spanning protein domains in the cytoplasmic membrane.     

Intragenic suppressor mutations that restore export of maltose binding protein with a truncated signal peptide

A deletion mutation, malE delta 12-18, removes seven residues from the hydrophobic core of the maltose binding protein (MBP) signal peptide and thus prevents secretion of this protein to the periplasm of E. coli. Intragenic suppressor mutations of malE delta 12-18 have been obtained, some highly efficient in their ability to restore proper MBP export. Twelve independently isolated suppressors represent six unique mutational events. Five result in alterations within the MBP signal peptide; one changes the amino acid at residue 19 of the mature MBP. Analysis of these suppressors indicates that the length of the hydrophobic core is a major determinant of signal peptide function. The experiments further suggest that the hydrophobic core region serves primarily a structural role in mediating protein secretion, and that other sequences outside of this region may be responsible for providing the initial recognition of the MBP nascent chain as a secreted protein.     

Progress in the identification of interaction sites on the periplasmic maltose binding protein from E coli

The periplasmic maltose binding protein (MBP) is required for the high affinity transport of maltose and maltodextrins and for chemotaxis towards these sugars. In these functions, MBP interacts with proteins of the cytoplasmic membrane: MalF and MalG for transport, Tar for chemotaxis. A large number of MBP mutations have been isolated by us and other laboratories. We grouped these mutations into classes depending on the interactions affected and we represented the corresponding residues on the 3-D model for MBP so as to further identify the sites of MBP interacting with the MalF-MalG complex and with the Tar protein. MBP (like the other binding proteins) is composed of 2 lobes enclosing a cleft where the substrate binds. The face of the protein opposite the cleft seems to interact neither with MalF-MalG nor with Tar. The other face, corresponding to the cleft, contains sites for interactions with MalF-MalG and Tar. These sites appear to cover both sides of the cleft and may overlap in part. The present definition of the interaction sites suggests further that MBP has different in vivo orientations when it interacts with MalF-MalG or with Tar. This work constitutes an additional step in combining the use of genetic and structural analysis to define the interaction sites on MBP. Because of the structural similarities between periplasmic binding proteins, the regions of interaction defined could be relevant for other members of this family.     

Crystal structure of a bacterial signal Peptide peptidase

Signal peptide peptidase (Spp) is the enzyme responsible for cleaving the remnant signal peptides left behind in the membrane following Sec-dependent protein secretion. Spp activity appears to be present in all cell types, eukaryotic, prokaryotic and archaeal. Here we report the first structure of a signal peptide peptidase, that of the Escherichia coli SppA (SppA_EC). SppA_EC forms a tetrameric assembly with a novel bowl-shaped architecture. The bowl has a dramatically hydrophobic interior and contains four separate active sites that utilize a Ser/Lys catalytic dyad mechanism. Our structural analysis of SppA reveals that while in many Gram-negative bacteria as well as characterized plant variants, a tandem duplication in the protein fold creates an intact active site at the interface between the repeated domains, other species, particularly Gram-positive and archaeal organisms, encode half-size, unduplicated SppA variants that could form similar oligomers to their duplicated counterparts, but using an octamer arrangement and with the catalytic residues provided by neighboring monomers. The structure reveals a similarity in the protein fold between the domains in the periplasmic Ser/Lys protease SppA and the monomers seen in the cytoplasmic Ser/His/Asp protease ClpP. We propose that SppA may, in addition to its role in signal peptide hydrolysis, have a role in the quality assurance of periplasmic and membrane-bound proteins, similar to the role that ClpP plays for cytoplasmic proteins.     

Synthesis of precursor maltose-binding protein with proline in the +1 position of the cleavage site interferes with the activity of Escherichia coli signal peptidase I in vivo.

The residues occupying the -3 and -1 positions relative to the cleavage site of secretory precursor proteins are usually amino acids with small, neutral side chains that are thought to constitute the recognition site for the processing enzyme, signal peptidase. No restrictions have been established for residues positioned +1 to the cleavage site, although there have been several indications that mutant precursor proteins with a proline at +1 cannot be processed by Escherichia coli signal peptidase I (also called leader peptidase). A maltose-binding protein (MBP) species with proline at +1, designated MBP27-P, was translocated efficiently but not processed when expressed in E. coli cells. Unexpectedly, induced expression of MBP27-P was found to have an adverse effect on the processing kinetics of five different nonlipoprotein precursors analyzed, but not precursor Lpp (the major outer membrane lipoprotein) processed by a different enzyme, signal peptidase II. Cell growth also was inhibited following induction of MBP27-P synthesis. Substitutions in the MBP27-P signal peptide that blocked MBP translocation across the cytoplasmic membrane and, hence, access to the processing enzyme or that altered the signal peptidase I recognition site at position -1 restored both normal growth and processing of other precursors. Since overproduction of signal peptidase I also restored normal growth and processing to cells expressing unaltered MBP27-P, it was concluded that precursor MBP27-P interferes with the activity of the processing enzyme, probably by competing as a noncleavable substrate for the enzyme's active site. Thus, although signal peptidase I, like many other proteases, is unable to cleave an X-Pro bond, a proline at +1 does not prevent the enzyme from recognizing the normal processing site. When the RBP signal peptide was substituted for the MBP signal peptide of MBP27-P, the resultant hybrid protein was processed somewhat inefficiently at an alternate cleavage site and elicited a much reduced effect on cell growth and signal peptidase I activity. Although the MBP signal peptide also has an alternate cleavage site, the different properties of the RBP and MBP signal peptides with regard to the substitution of proline at +1 may be related to their respective secondary structures in the processing site region.     

Dependence of maltose transport and chemotaxis on the amount of maltose-binding protein

Maltose-binding protein (MBP) is essential for maltose transport and chemotaxis in Escherichia coli. To perform these functions it must interact with two sets of cytoplasmic membrane proteins, the MalFGK transport complex and the chemotactic signal transducer Tar. MBP is present at high concentrations, on the order of 1 mM, in the periplasm of maltose-induced or malTc constitutive cells. To determine how the amount of MBP affects transport and taxis, we utilized a series of malE signal-sequence mutations that interfere with export of MBP. The MBP content in shock fluid from cells carrying the various mutations ranged from 4 to 23% of the malE+ level. The apparent Km for maltose transport varied by less than a factor of 2 among malE+ and mutant strains. At a saturating maltose concentration 9% (approximately 90 microM) of the malE+ amount of MBP was required for half-maximal uptake rates. Transport exhibited a sigmoidal dependence on the amount of periplasmic MBP, indicating that MBP may be involved in a cooperative interaction at some stage of the transport process. The chemotactic response to a saturating maltose stimulus exhibited a first-order dependence on the amount of periplasmic MBP. Thus, interaction of a single substrate-bound MBP with Tar appears sufficient to initiate a chemotactic signal from the transducer. A half-maximal chemotactic response occurred at 25% of the malE+ MBP level, suggesting that in vivo the KD for binding of maltose-loaded MBP to Tar is quite high (approximately 250 microM).     

Phosphorylation of myelin basic protein and peptides by ganglioside-stimulated protein kinase

Rabbit myelin basic protein (MBP) was phosphorylated by a ganglioside-stimulated protein kinase to a stoichiometry of 1.4 and 2.1 mol phosphate/mol MBP in the presence and absence of GTlb, respectively. Two-dimensional peptide mapping analyses revealed that two of the sites of phosphorylation were distinct from those catalyzed by cAMP-dependent protein kinase or protein kinase C. Phosphorylation of one of these sites by ganglioside-stimulated protein kinase was inhibited by GTlb, suggesting that the inhibitory effect of gangliosides on MBP phosphorylation may be substrate-directed. Although ganglioside-stimulated protein kinase did not phosphorylate MBP at a domain containing residues 82-117, a synthetic peptide Arg-Phe-Ser-Trp-Gly-Ala-Glu-Gly-Gln-Lys corresponding to residues 111-120 was phosphorylated by the kinase in a ganglioside-stimulated manner. These findings suggest that the conformation of MBP may be important in determining its phosphorylatability.     

Role of the mature protein sequence of maltose-binding protein in its secretion across the E. coli cytoplasmic membrane

Secretion of amber fragments of an E. coli periplasmic protein, the maltose-binding protein, was studied to determine if the mature portion of the protein is required for its export across the cytoplasmic membrane. A fragment lacking 25–35 amino acid residues at the C terminus is secreted at normal levels, suggesting that this sequence is not required for secretion. This is in contrast to the results obtained with the periplasmic protein β-lactamase. In studying another fragment of one-third the molecular weight of the intact protein, we found that the majority of the fragment is not recovered from the periplasmic fraction. However, a small amount of secretion of this polypeptide was observed. This fragment is synthesized as a larger molecular weight form when cells are induced for the synthesis of a maltose-binding protein-β-galactosidase hybrid protein, which was previously shown to block the proper localization and processing of envelope proteins. This result is consistent with the idea that the larger form is a precursor with an unprocessed signal sequence, whereas in the absence of the hybrid protein the fragment is a processed mature form. Thus secretion of the smaller fragment may be occurring up to the point where the signal sequence is removed. That this fragment has passed through the cytoplasmic membrane is further supported by its accessibility to externally added trypsin. We suggest that the fragment may be secreted to the periplasm, but cannot assume a water-soluble conformation; the majority of the polypeptide may be associated with the external surface of the cytoplasmic membrane. Thus the mature sequence of maltose-binding protein, at least its C-terminal two thirds, may not be required for its export across the cytoplasmic membrane.     

Escherichia coli signal peptides direct inefficient secretion of an outer membrane protein (OmpA) and periplasmic proteins (maltose-binding protein, ribose-binding protein, and alkaline phosphatase) in Bacillus subtilis.

Signal peptides of gram-positive exoproteins generally carry a higher net positive charge at their amino termini (N regions) and have longer hydrophobic cores (h regions) and carboxy termini (C regions) than do signal peptides of Escherichia coli envelope proteins. To determine if these differences are functionally significant, the ability of Bacillus subtilis to secrete four different E. coli envelope proteins was tested. A pulse-chase analysis demonstrated that the periplasmic maltose-binding protein (MBP), ribose-binding protein (RBP), alkaline phosphatase (PhoA), and outer membrane protein OmpA were only inefficiently secreted. Inefficient secretion could be ascribed largely to properties of the homologous signal peptides, since replacing them with the B. amyloliquefaciens alkaline protease signal peptide resulted in significant increases in both the rate and extent of export. The relative efficiency with which the native precursors were secreted (OmpA >> RBP > MBP > PhoA) was most closely correlated with the overall hydrophobicity of their h regions. This correlation was strengthened by the observation that the B. amyloliquefaciens levansucrase signal peptide, whose h region has an overall hydrophobicity similar to that of E. coli signal peptides, was able to direct secretion of only modest levels of MBP and OmpA. These results imply that there are differences between the secretion machineries of B. subtilis and E. coli and demonstrate that the outer membrane protein OmpA can be translocated across the cytoplasmic membrane of B. subtilis.