Leader peptidase

The Escherichia coli leader peptidase has been vital for unravelling problems in membrane assembly and protein export. The role of this essential peptidase is to remove amino-terminal leader peptides from exported proteins after they have crossed the plasma membrane. Strikingly, almost all periplasmic proteins, many outer membrane proteins, and a few inner membrane proteins are made with cleavable leader peptides that are removed by this peptidase. This enzyme of 323 amino acid residues spans the membrane twice, with its large carboxyl-terminal domain protruding into the periplasm. Recent discoveries show that its membrane orientation is controlled by positively charged residues that border (on the cytosolic side) the transmembrane segments. Cleavable pre-proteins must have small residues at -1 and a small or aliphatic residue at -3 (with respect to the cleavage site). Leader peptidase does not require a histidine or cysteine amino acid for catalysis. Interestingly, serine 90 and aspartic acid 153 are essential for catalysis and are also conserved in a mitochondrial leader peptidase, which is 30.7% homologous with the bacterial enzyme over a 101-residue stretch.     

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.     

The aerobactin iron uptake system in enteropathogenic Escherichia coli: evidence for an extinct transposon

Abstract It has previously been demonstrated that the precursor form of the phosphate-binding protein (pre-PhoS) is accumulated in both the cytoplasmic membrane and the cytoplasm under conditions of phosphate-binding protein (PhoS) hyperproduction in Escherichia coli [11]. In this study, the trypsin accessibility of these 2 pre-PhoS pools has been investigated in spheroplasts. The results demonstrate that the membrane-associated pre-PhoS is not accessible to trypsin, and thus has not been translocated. The sensitivity to trypsin of mature PhoS, membrane-associated pre-PhoS and cytoplasmic pre-PhoS was compared. The results suggest a difference in conformation between membrane-associated and cytoplasmic pre-PhoS since the former is more trypsin-sensitive than the latter. Mature PhoS is resistant to trypsin. The significance of these results with regard to the export mechanism for periplasmic proteins is discussed.     

Combined effects of the signal sequence and the major chaperone proteins on the export of human cytokines in Escherichia coli.

We have studied the export of two human proteins in the course of their production in Escherichia coli. The coding sequences of the granulocyte-macrophage colony-stimulating factor and of interleukin 13 were fused to those of two synthetic signal sequences to direct the human proteins to the bacterial periplasm. We found that the total amount of protein varies with the signal peptide-cytokine combination, as does the fraction of it that is soluble in a periplasmic extract. The possibility that the major chaperone proteins such as SecB and the GroEL-GroES and DnaK-DnaJ pairs are limiting factors for the export was tested by overexpressing one or the other of these chaperones concomitantly with the heterologous protein. The GroEL-GroES chaperone pair had no effect on protein production. Overproduction of SecB or DnaK plus DnaJ resulted in a marked increase of the quantity of human proteins in the periplasmic fraction, but this increase depends on the signal peptide-heterologous protein-chaperone association involved.     

Multiple roles of the pilus biogenesis protein pilD: involvement of pilD in excretion of enzymes from Pseudomonas aeruginosa.

In Pseudomonas aeruginosa, the genes pilB, pilC, and pilD encode proteins necessary for posttranslational modification and assembly of pilin monomers into pilus organelles (D. Nunn, S. Bergman, and S. Lory, J. Bacteriol. 172:2911-2919, 1990). We show that PilD, encoding a putative pilin-specific leader peptidase, also controls export of alkaline phosphatase, phospholipase C, elastase, and exotoxin A. pilD mutants accumulate these proteins in the periplasmic space, while secretion of periplasmic and outer membrane proteins appears to be normal. The periplasmic form of exotoxin A was fully mature in size, contained all cysteines in disulfide bonds, and was toxic in a tissue culture cytotoxicity assay, suggesting that in pilD mutants, exotoxin A was folded into its native conformation. The function of the other two accessory proteins, PilB and PilC, appears to be restricted to pilus biogenesis, and strains carrying mutations in their respective genes do not show an export defect. These studies show that in addition to cleaving the leader sequence from prepilin, PilD has an additional role in secretion of proteins that are released from P. aeruginosa into the surrounding media. PilD most likely functions as a protease that is involved in processing and assembly of one or more components of the membrane machinery necessary for the later stages of protein extracellular localization.     

Direct evidence for a coupling between synthesis and export of PhoS in E. coli

The accumulation of pre-PhoS under conditions of PhoS overproduction has been previously described. It is now demonstrated that during the induction of PhoS, a delay in the completion of polypeptide chain elongation can be detected. This delay is related to the extent of jamming of export sites by pre-PhoS or by other exported proteins. These results suggest that a component required for completion of pre-PhoS polypeptide becomes limiting, being titrated by the excess of nascent chains bearing signal peptides. This component thus probably acts at an early step in the export pathway.     

Evidence that extracellular export of the endoglucanase encoded by egl of Pseudomonas solanacearum occurs by a two-step process involving a lipoprotein intermediate

Pseudomonas solanacearum is an important phytopathogen that produces a variety of extracellular enzymes. Previous reports suggested that one of these, a 43-kDa beta-1,4-endoglucanase (EGL), is initially synthesized with a 45-residue leader sequence that is removed during export. Experiments with globomycin presented here also suggest that the primary precursor of EGL (ppEGL) has a 45-residue leader sequence but that only the first 19 residues of the leader sequence are removed by signal peptidase II during initial export across the inner membrane. Further analysis suggested that the resultant 46-kDa intermediate precursor (pEGL) is a transient fatty acylated lipoprotein and is located on the periplasmic side of the inner membrane of P. solanacearum. Although Escherichia coli could synthesize ppEGL, modify it with palmitate, and remove the first 19 residues of the leader sequence during export across the inner membrane, only P. solanacearum could export pEGL across the outer membrane and remove the remaining 26 residues of the leader sequence producing the mature, extracellular EGL. The second step of the export process requires export machinery not present in E. coli. To our knowledge this represents the first example of a leader sequence with two distinct parts, one removed during export across the inner membrane and the other removed during export across the outer membrane.     

Escherichia coli exports previously folded and biotinated protein domains

Biotination of proteins is a post-translational modification that requires a folded acceptor domain. We previously showed that an acceptor domain fused to the carboxyl terminus of several cytosolic proteins results in biotinated fusion proteins in vivo. We now show that proteins encoded by translational gene fusions of two periplasmic proteins, alkaline phosphatase and TEM beta-lactamase, to carboxyl-terminal biotin-accepting sequences are biotinated and exported by Escherichia coli. Expression of the alkaline phosphatase fusion protein in wild type strains resulted in inefficient biotination of the fusion product. This result was due to the rapid export of the acceptor protein before biotination could occur since a very large increase in biotinated fusion protein levels was observed in strains lacking the SecB chaperone protein. The beta-lactamase fusion protein was biotinated but was only stable in strains lacking the DegP periplasmic protease. Both biotinated fusion proteins accumulated in the culture medium in strains possessing defective outer membranes. These results indicate that the export machinery can accommodate both a post-translational modification and a protein domain previously folded into its mature conformation in vivo.     

Secretion and export of IGF-1 in Escherichia coli strain JM101

Summary The processing of LamB-IGF-1 fusion protein and the export of processed IGF-1 (insulin-like growth-factor-1) into the growth medium was examined in the Escherichia coli host strain, JM101. Several strain or plasmid modifications were tried to increase export of periplasmic (Processed) IGF-1 into the growth medium of JM101. These included: (1) use of a lon null mutant strain to increase accumulation levels of unprocessed LamB-IGF-1 fusion protein; (2) use of an alternative drug resistance marker on the expression plasmid rather than beta-lactamase, thereby reducing any competition for processing of LamB-IGF-1 by signal peptidase; (3) examination of whether phage M13 gene III protein expression caused more periplasmic IGF-1 to be exported into the growth medium due to increased outer membrane permeability; and (4) examination of the effect of E. coli or yeast optimized IGF-1 codons. None of these strain or plasmid modifications caused any significant increase in export of IGF-1 into the growth medium of JM101. Solubility studies of LamB-IGF-1 and processed IGF-1 showed that virtually all of the LamB-IGF-1 and IGF-1 remaining within the cell after a 2 h induction period was insoluble. This implied that only soluble LamB-IGF-1 was processed to IGF-1 and that only soluble IGF-1 was exported into the growth medium. Taken together, the results indicated that LamB-IGF-1 and IGF-1 solubility were the limiting factors in secretion of IGF-1 into the periplasm and export of IGF-1 into the growth medium.     

Use of phoA fusions to study the topology of the Escherichia coli inner membrane protein leader peptidase.

A topology of the Escherichia coli leader peptidase has been previously proposed on the basis of proteolytic studies. Here, a collection of alkaline phosphatase fusions to leader peptidase is described. Fusions to the periplasmic domain of this protein exhibit high alkaline phosphatase activity, while fusions to the cytoplasmic domain exhibit low activity. Elements within the cytoplasmic domain are necessary to stably anchor alkaline phosphatase in the cytoplasm. The amino-terminal hydrophobic segment of leader peptidase acts as a weak export signal for alkaline phosphatase. However, when this segment is preceded by four lysines, it acts as a highly efficient export signal. The coherence of in vitro studies with alkaline phosphatase fusion analysis of the topology of leader peptidase further indicates the utility of this genetic approach to membrane protein structure and insertion.     

Abnormal fractionation of beta-lactamase in Escherichia coli: evidence for an interaction with the inner membrane in the absence of a leader peptide.

beta-Lactamase with the -20 to -1 region of the leader peptide deleted (almost complete deletion of the leader peptide) [delta(-20,-1) beta-lactamase] was released from Escherichia coli cells by osmotic shock. Fractionation of the cells by conversion to spheroplasts and protease accessibility experiments further indicated that a portion of the protein may be bound to the cytoplasmic membrane and be partially exposed in the periplasmic space. Expression of delta(-20,-1) beta-lactamase conferred a 25-fold increase in the 50% lethal dose for ampicillin relative to that for controls, thus confirming that a small amount (about 2%) of the active protein is completely exported from the cytoplasm. These results suggest that even in the absence of a leader peptide, mature beta-lactamase is able to interact with the cytoplasmic membrane and be translocated into the periplasmic space, albeit with a low efficiency.     

Involvement of SecB, a chaperone, in the export of ribose-binding protein.

Ribose-binding protein (RBP) is an exported protein of Escherichia coli that functions in the periplasm. The export of RBP involves the secretion machinery of the cell, consisting of a cytoplasmic protein, SecA, and the integral membrane translocation complex, including SecE and SecY. SecB protein, a chaperone known to mediate the export of some periplasmic and outer membrane proteins, was previously reported not to be involved in RBP translocation even though small amounts of in vitro complexes between SecB and RBP have been detected. In our investigation, it was shown that a dependence on SecB could be demonstrated under conditions in which export was compromised. Species of RBP which carry two mutations, one in the leader that blocks export and a second in the mature protein which partially suppresses the export defect, were shown to be affected by SecB for efficient translocation. Five different changes which suppress the effect of the signal sequence mutation -17LP are all located in the N domain of the tertiary structure of RBP. All species of RBP show similar interaction with SecB. Furthermore, a leaky mutation, -14AE, generated by site-specific mutagenesis causes reduced export in the absence of SecB. These results indicate that SecB can interact with RBP during secretion, although it is not absolutely required under normal circumstances.     

In vivo analysis of integration of membrane proteins in Escherichia coli

The in vivo process of membrane protein integration was studied by pulse-labelling Escherichia coli cells, and assessing integral anchoring of labelled proteins to the lipid bilayer based on their resistance to alkali extraction. To conduct this experiment, conditions for extracting E. coli proteins with alkali were refined, and the immunoprecipitation procedures were improved to allow effective detection of integral membrane proteins. Examination of pulse-labelled, integral membrane proteins, including lactose permease (LacY), SecY, cytochrome omicron subunit II and leader peptidase revealed that all were in the alkali-insoluble fraction, indicating that membrane integration of these proteins takes place rapidly in wild-type cells. However, when LacY was synthesized in excess from a multicopy plasmid, significant proportions were found in the alkali-soluble fraction, indicating that the solubility in alkali is not an intrinsic property of the protein, and suggesting that LacY depends on some limited cellular factor for membrane integration. The unintegrated species of LacY sedimented slowly through an alkaline sucrose gradient. The secY24 mutant cells accumulated higher proportions of unintegrated LacY molecules at lower levels of overproduction than the sec+ cells. LacY overproduction in wild-type cells was found to inhibit processing (export) of beta-lactamase but not of OmpA and OmpF. These results are interpreted to mean that integration of LacY depends on multiple cellular components, one of which is also involved in export of beta-lactamase.     

Export of beta-lactamase is independent of the signal recognition particle

In Escherichia coli, three different types of proteins engage the SecY translocon of the inner bacterial membrane for translocation or insertion: 1) polytopic membrane proteins that prior to their insertion into the membrane are targeted to the translocon using the bacterial signal recognition particle (SRP) and its receptor; 2) secretory proteins that are targeted to and translocated across the SecY translocon in a SecA- and SecB-dependent reaction; and 3) membrane proteins with large periplasmic domains, requiring SRP for targeting and SecA for the translocation of the periplasmic moiety. In addition to its role as a targeting device for membrane proteins, a function of the bacterial SRP in the export of SecB-independent secretory proteins has also been postulated. In particular, beta-lactamase, a hydrolytic enzyme responsible for cleavage of the beta-lactam ring containing antibiotics, is considered to be recognized and targeted by SRP. To examine the role of the SRP pathway in beta-lactamase targeting and export, we performed a detailed in vitro analysis. Chemical cross-linking and membrane binding assays did not reveal any significant interaction between SRP and beta-lactamase nascent chains. More importantly, membrane vesicles prepared from mutants lacking a functional SRP pathway did block the integration of SRP-dependent membrane proteins but supported the export of beta-lactamase in the same way as that of the SRP-independent protein OmpA. These data demonstrate that in contrast to previous results, the bacterial SRP is not involved in the export of beta-lactamase and further suggest that secretory proteins of Gram-negative bacteria in general are not substrates of SRP.     

A family of bacteriocin ABC transporters carry out proteolytic processing of their substrates concomitant with export

Lantibiotic and non-lantibiotic bacteriocins are synthesized as precursor peptides containing N-terminal extensions (leader peptides) which are cleaved off during maturation. Most non-lantibiotics and also some lantibiotics have leader peptides of the so- called double-glycine type. These leader peptides share consensus sequences and also a common processing site with two conserved glycine residues In positions -1 and 2. The double-glycine-type leader peptides are unrelated to the N-terminal signal sequences which direct proteins across the cytoplasmic membrane via the sec pathway. Their processing sites are also different from typical signal peptidase cleavage sites, suggesting that a different processing enzyme is involved. Peptide bacteriocins are exported across the cytoplasmic membrane by a dedicated ATP-binding cassette (ABC) transporter. Here we show that the ABC transporter is the maturation protease and that its proteolytic domain resides in the N-terminal part of the protein. This result demonstrates that the ABC transporter has a dual function: (i) removal of the leader peptide from its substrate, and (ii) translocation of its substrate across the cytoplasmic membrane. This represents a novel strategy for secretion of bacterial proteins.     

Secretion of the Escherichia coli K-12 SheA hemolysin is independent of its cytolytic activity

The Escherichia coli K-12 sheA gene encodes a pore-forming hemolysin that is secreted to the medium by a hitherto unidentified mechanism. To study SheA secretion, we constructed fusions between SheA and the mature form of the periplasmic enzyme beta-lactamase, and performed site-directed mutagenesis on these constructs. The SheA-Bla and Bla-SheA hybrid proteins displayed hemolytic activity and were efficiently exported to the extracellular medium. Our results with mutant hybrid proteins show that secretion of SheA is independent of its cytolytic activity, that secretion is paralleled by a transient leakage of periplasmic contents to the extracellular medium, and that deletion of the 11 C-terminal residues of SheA has no effect on its secretion and cytolytic activity.     

Cytoplasmic and periplasmic expression of a synthetic gene for ferredoxin in Escherichia coli

A synthetic gene coding for a modified ferredoxin II of Desulfovibrio desulfuricans Norway strain was assembled from 10 oligonucleotides. This gene was cloned into various expression vectors allowing either cytoplasmic expression or export to the periplasmic space. In the latter case, two different constructs were made, each of which contained the OmpA signal peptide: one of these constructs contained 3 additional N-terminal amino acids as compared to the wild-type ferredoxin (56 amino acid residues). The expression of proteins encoded by the 3 constructs was assayed in E coli and the proteins were localized by cell fractionation and immunogold labelling. A low percentage of the periplasmic ferredoxin (approximately 5%) was secreted to the medium in the absence of cell lysis. The recombinant ferredoxin was purified and found to be correctly processed by the leader peptidase. However, due to the high cysteine content intramolecular and intermolecular disulfide bonds were formed and prevented binding of [4Fe-4S] clusters. Reconstitution experiments using these recombinant proteins are in progress.     

The ultimate localization of an outer membrane protein of Escherichia coli K-12 is not determined by the signal sequence

To study the role of the signal sequences in the biogenesis of outer membrane proteins, we have constructed two hybrid genes: a phoE-ompF hybrid gene, which encodes the signal sequence of outer membrane PhoE protein and the structural sequence of outer membrane OmpF protein, and a bla-phoE hybrid gene which encodes the signal sequence as well as 158 amino acids of the structural sequence of the periplasmic enzyme beta-lactamase and the complete structural sequence of PhoE protein. The products of these genes are normally transported to and assembled into the outer membrane These results show: (i) that signal sequences of exported proteins are export signals which function independently of the structural sequence, and (ii) that the information which determines the ultimate location of an outer membrane protein is located in the structural sequence of this protein, and not in the signal sequence.     

Export incompatibility of N-terminal basic residues in a mature polypeptide of Escherichia coli can be alleviated by optimising the signal peptide

Summary Export of the outer membrane protein, OmpA, across the cytoplasmic membrane of Escherichia coli was severely inhibited by the presence of two, three, four or six additional basic residues at the N-terminus of the mature polypeptide, but not by three similarily positioned acidic residues. Because a few bacterial proteins do possess basic residues close to the leader peptidase cleavage site and because the type of inhibition described here could pose problems in the construction of hybrid secretory proteins, we also studied means of alleviating this form of export incompatibility. Inhibition was abolished when basic residues were preceded by acidic ones. Also, the processing rates of the mutants with two or six basic residues could be partially restored by increasing the length of the hydrophobic core of the signal peptide. Taking this as a precedent, it is suggested that the structure of the signal peptide is an important feature for maintenance of a reasonable rate of translocation of those exported proteins which possess basic residue(s) at the N-terminus of the mature polypeptide.     

Crystallization of a soluble,catalytically active form of Escherichia coli leader peptidase

Leader peptidase, a novel serine protease in Escherichia coli, catalyzes the cleavage of the amino-terminal leader sequences from exported proteins. It is an integral membrane protein containing two transmembrane segments with its carboxy-terminal catalytic domain residing in the periplasmic space. Here, we report a procedure for the purification and the crystallization of a soluble non-membrane-bound form of leader peptidase (Δ2-75). Crystals were obtained by the sitting-drop vapor diffusion technique using ammonium dihydrogen phosphate as the precipitant. Interestingly, we have found that the presence of the detergent Triton X-100 is required to obtain crystals sufficiently large for X-ray analysis. The crystals belong to the tetragonal space group P4₂2₁2, with unit cell dimensions of a = b = 115 Å and c = 100 Å, and contain 2 molecules per asymmetric unit. This is the first report of the crystallization of a leader (or signal) peptidase. © 1995 Wiley-Liss, Inc.