The secretion pathway of IgA protease-type proteins in gram-negative bacteria

The pathogenic, Gram-negative bacteria, Neisseria gon-orrhoeae, Neisseria meningitidis and Haemophilus influenzae, secrete immunoglobulin A1 proteases into their extracellular surroundings. An extraordinary feature in the secretory pathway of these putative virulence factors is a self-directed outer membrane transport step allowing the proteins to be secreted autonomously, even from foreign Gram-negative host cells like Escherichia coli. Here we summarize recent achievements in the understanding of IgA protease outer membrane translocation.     

Identification of subtilisin, Epr and Vpr as enzymes that produce CSF, an extracellular signalling peptide of Bacillus subtilis

Cell-cell communication regulates many important processes in bacteria. Gram-positive bacteria use peptide signals for communication, such as the Phr pentapeptides of Bacillus subtilis. The Phr pentapeptides are secreted with a pro domain that is cleaved to produce an active signalling peptide. To identify the protease(s) involved in production of the mature Phr signalling peptides, we developed assays for detecting cleavage of one of the B. subtilis Phr pentapeptides, CSF, from the proCSF precursor. Using both a cellular and a mass spectrometric approach, we determined that a sigma-H-regulated, secreted, serine protease(s) cleaved proCSF to CSF. Mutants lacking the three proteases that fit these criteria, subtilisin, Epr and Vpr, had a defect in CSF production. Purified subtilisin and Vpr were shown to be capable of processing proCSF as well as at least one other Phr peptide produced by B. subtilis, PhrA, but they were not able to process the PhrE signalling peptide of B. subtilis, indicating that there are probably other unidentified proteases involved in Phr peptide production. Subtilisin, Epr and Vpr are members of the subtilisin family of proteases that are widespread in bacteria, suggesting that many bacterial species may be capable of producing Phr signalling peptides.     

Protein secretion in gram-negative bacteria. The extracellular metalloprotease B from Erwinia chrysanthemi contains a C-terminal secretion signal analogous to that of Escherichia coli alpha-hemolysin

The secretion signal of extracellular metalloprotease B that is secreted without a signal peptide by the Gram-negative phytopathogenic bacterium Erwinia chrysanthemi is shown by deletion and gene fusion analyses to be located within the last 40 C-terminal amino acids. Secretion of a peptide containing only this region of the protease requires the same three secretion factors (PrtD, PrtE, and PrtF) that were previously shown to be required for the secretion of the full-length protease. This secretion signal can also be recognized, albeit inefficiently, by the analogous secretion machinery of alpha-hemolysin, another protein with a C-terminal secretion signal that is secreted by some strains of the Gram-negative bacterium Escherichia coli. The secretion signal was fused to an internal 200-amino acid fragment from the sequence of the cytoplasmic protein amylomaltase to promote its specific secretion by the protease secretion pathway. Almost exactly the same sequence as that identified as the protease B secretion signal was also found at the C terminus of metalloprotease C that is also secreted by E. chrysanthemi.     

Secretion of recombinant Bacillus hydrolytic enzymes using Escherichia coli expression systems

Bacillus spp. are Gram-positive bacteria that secrete a large number of extracellular proteins of industrial relevance. In this report, three Bacillus extracellular hydrolytic enzymes, i.e., alpha-amylase, mannanase and chitinase, were cloned and over-expressed in Gram-negative Escherichia coli. We found that both the native signal peptides and that of E. coli outer membrane protein, OmpA, could be used to direct the secretion of the recombinant enzymes. The expressed enzymes were observed as clearing zones on agar plates or in zymograms. Determination of enzyme activities in different cell compartments suggested that the ability of the enzymes to be secreted out into the culture medium depends on the time of induction, the type of the signal peptides and the molecular mass of the enzymes. After overnight induction, most of the enzyme activities (85-96%) could be harvested from the culture supernatant. Our results suggest that various signal peptides of Bacillus spp. can be recognized by the E. coli secretion machinery. It seems possible that other enzymes with similar signal peptide could be secreted equally well in E. coli expression systems. Thus, our finding should be able to apply for cloning and extracellular production of other Bacillus hydrolytic enzymes as well as other proteins.     

Signal and propeptide processing of human tissue plasminogen activator: activity of a pro-tPA derivative

We have explored the heterogeneity in the proteolytic processing of the N-terminus of human tissue plasminogen activator. We demonstrate that normal propeptide processing occurs following Arg-4, preceding the sequence Gly-Ala-Arg-Ser+1. Generation of the previously designated Ser+1 occurs via secondary proteolysis following secretion. By site-directed mutagenesis, we have eliminated this cleavage site resulting in a derivative containing the propeptide sequence. N-terminal sequence analysis of this form indicated that signal peptide cleavage occurs following Ser-13. The pro-tPA derivative had near normal serine protease and plasminogen activating activities, and could be stimulated by fibrin. An additional derivative, containing the tribasic sequence from the human protein C propeptide preceding Ser+1, was secreted with full processing of the propeptide. Our data have defined the cleavages for the signal peptide and propeptide and demonstrate that a tribasic sequence can be used to eliminate N-terminal heterogeneity in this molecule. In addition, we demonstrate that, unlike several other serine proteases, a propeptide sequence does not alter the activity of this enzyme.     

Secretion across the bacterial outer membrane.

Many bacteria secrete extracellular proteins such as hydrolytic enzymes or toxins. In Gram-negative bacteria, secreted proteins must cross the two membranes that constitute the cell envelope. Recent studies have identified several specific secretion systems that can be classified in three distinct pathways, and related systems have been discovered in a wide range of prokaryotic and eukaryotic cells.     

The AprV5 Subtilase Is Required for the Optimal Processing of All Three Extracellular Serine Proteases from Dichelobacter nodosus

Dichelobacter nodosus is the principal causative agent of ovine footrot and its extracellular proteases are major virulence factors. Virulent isolates of D. nodosus secrete three subtilisin-like serine proteases: AprV2, AprV5 and BprV. These enzymes are each synthesized as precursor molecules that include a signal (pre-) peptide, a pro-peptide and a C-terminal extension, which are processed to produce the mature active forms. The function of the C-terminal regions of these proteases and the mechanism of protease processing and secretion are unknown. AprV5 contributes to most of the protease activity secreted by D. nodosus. To understand the role of the C-terminal extension of AprV5, we constructed a series of C-terminal-deletion mutants in D. nodosus by allelic exchange. The proteases present in the resultant mutants and their complemented derivatives were examined by protease zymogram analysis, western blotting and mass spectrometry. The results showed that the C-terminal region of AprV5 is required for the normal expression of protease activity, deletion of this region led to a delay in the processing of these enzymes. D. nodosus is an unusual bacterium in that it produces three closely related extracellular serine proteases. We have now shown that one of these enzymes, AprV5, is responsible for its own maturation, and for the optimal cleavage of AprV2 and BprV, to their mature active forms. These studies have increased our understanding of how this important pathogen processes these virulence-associated extracellular proteases and secretes them into its external environment.     

Export and secretion of proteins by bacteria

Abstract A wide variety of proteins are exported or secreted by a range of morphologically distinct bacteria. The processes of protein export are most extensively characterised in Escherichia coli , where recent advances have been made in the identification of genes involved in forming the export machinery. Both Gram-positive and Gram-negative bacteria secrete proteins into the medium. Gram-negative bacteria have adopted a variety of approaches in order to overcome the additional permeability of the outer membrane.     

Quorum sensing by peptide pheromones and two-component signal-transduction systems in Gram-positive bacteria

Cell-density-dependent gene expression appears to be widely spread in bacteria. This quorum-sensing phenomenon has been well established in Gram-negative bacteria, where N -acyl homoserine lactones are the diffusible communication molecules that modulate cell-density-dependent phenotypes. Similarly, a variety of processes are known to be regulated in a cell-density- or growth-phase-dependent manner in Gram-positive bacteria. Examples of such quorum-sensing modes in Gram-positive bacteria are the development of genetic competence in Bacillus subtilis and Streptococcus pneumoniae , the virulence response in Staphylococcus aureus , and the production of antimicrobial peptides by several species of Gram-positive bacteria including lactic acid bacteria. Cell-density-dependent regulatory modes in these systems appear to follow a common theme, in which the signal molecule is a post-translationally processed peptide that is secreted by a dedicated ATP-binding-cassette exporter. This secreted peptide pheromone functions as the input signal for a specific sensor component of a two-component signal-transduction system. Moreover, genetic linkage of the common elements involved results in autoregulation of peptide-pheromone production.     

Peptide signal molecules and bacteriocins in Gram-negative bacteria: a genome-wide in silico screening for peptides containing a double-glycine leader sequence and their cognate transporters

Quorum sensing (QS) in Gram-negative bacteria is generally assumed to be mediated by N-acyl-homoserine lactone molecules while Gram-positive bacteria make use of signaling peptides. We analyzed the occurrence in Gram-negative bacteria of peptides and transporters that are involved in quorum sensing in Gram-positive bacteria. Many class II bacteriocins and inducing factors produced by lactic acid bacteria (LAB) and competence stimulating peptides (CSPs) synthesized by streptococci are processed by their cognate ABC-transporters during their secretion. During transport, a conserved leader sequence, termed the double-glycine motif (GG-motif), is cleaved off by the N-terminal domain of the transporter, which belongs to the Peptidase C39 protein family. Several peptides containing a GG-motif were recently described in Gram-negative bacteria (Trends Microbiol 2001;9:164-8). To screen for additional putative GG-motif containing peptides, an in silico strategy based on MEME, HMMER2.2 and Wise2 was designed. Using a curated training set, a motif model of the leader peptide was built and used to screen over 120 fully sequenced bacterial genomes. The screening methodology was applied at the nucleotide level as probably many small peptide genes have not been annotated and may be absent from the non-redundant databases. It was found that 33% of the screened genomes of Gram-negative bacteria contained one or more transporters carrying a Peptidase C39 domain, compared to 44% of the genomes of Gram-positive bacteria. The transporters can be subdivided into four classes on the basis of their domain organization. Genes coding for putative peptides containing 23-142 amino acids and a GG-motif were found in close association with genes coding for Peptidase C39 domain containing proteins. These peptides show structural similarity to bacteriocins and peptide pheromones of Gram-positive bacteria. The possibility of signal transduction based on peptide signaling in Gram-negative bacteria is discussed.     

Detection and characterization of protease secreted by the plant pathogen Xylella fastidiosa

Xylella fastidiosa is a pathogenic bacterium found in several plants. These bacteria secrete extracellular proteases into the culture broth as visualized in sodium-dodecyl-sulfate polyacrylamide activity gels containing gelatin as a copolymerized substrate. Three major protein bands were produced by the citrus strain with molar masses (MM) of 122, 84 and 65 kDa. Grape strain 9,713 produced two bands of approximately 84 and 64 kDa. These organisms produced zones of hydrolysis in agar plates amended with gelatin, casein and hemoglobin. Gelatin was the best substrate for these proteases. Sodium dodecyl sulfate-polyacrylamide electrophoresis (SDS-PAGE) activity gel indicated that the protease of Xylella fastidiosa from citrus and grape were completely inhibited by PMSF and partially inhibited by EDTA. The optimal temperature for protease activity was 30 degrees C with an optimal pH of 7.0. Among the proteolytic enzymes secreted by the phytopathogen, chitinase and beta-1,3-glucanase activities were also detected in cultures of Xylella fastidiosa (citrus). From these results, it is suggested that proteases produced by strains of Xylella fastidiosa from citrus and grape, belong to the serine- and metallo-protease group, respectively.     

In vitro stepwise autoprocessing of the proform of pro-aminopeptidase processing protease from Aeromonas caviae T-64

PA protease (pro-aminopeptidase processing protease) is an extracellular zinc metalloprotease produced by the Gram-negative bacterium Aeromonas caviae T-64. The 590-amino-acid precursor of PA protease is composed of a putative 19-amino-acid signal sequence, a 165-amino-acid N-terminal propeptide, a 33 kDa mature protease domain and an 11 kDa C-terminal propeptide. The proform of PA protease, which was produced as inclusion bodies in Escherichia coli, was subjected to in vitro refolding. It was revealed that the processing of the proform involved a stepwise autoprocessing mechanism. Firstly, the N-terminal propeptide was autocatalytically removed on completion of refolding and secondly, the C-terminal propeptide was autoprocessed after the degradation of the N-terminal propeptide. Both the N- and C-terminal propeptides existed as intact peptides after their successive removal, and they were subsequently degraded gradually. The degradation of the N-terminal propeptide appears to be the rate-limiting step in the maturation of the proform of PA protease.     

Autocatalytic maturation of the Tat-dependent halophilic subtilase Nep produced by the archaeon Natrialba magadii

Halolysins are subtilisin-like extracellular proteases produced by haloarchaea that possess unique protein domains and are salt dependent for structural integrity and functionality. In contrast to bacterial subtilases, the maturation mechanism of halolysins has not been addressed. The halolysin Nep is secreted by the alkaliphilic haloarchaeon Natrialba magadii, and the recombinant active enzyme has been synthesized in Haloferax volcanii. Nep contains an N-terminal signal peptide with the typical Tat consensus motif (GRRSVL), an N-terminal propeptide, the protease domain, and a C-terminal domain. In this study, we used Nep as a model protease to examine the secretion and maturation of halolysins by using genetic and biochemical approaches. Mutant variants of Nep were constructed by site-directed mutagenesis and expressed in H. volcanii, which were then analyzed by protease activity and Western blotting. The Tat dependence of Nep secretion was demonstrated in Nep RR/KK variants containing double lysine (KK) in place of the twin arginines (RR), in which Nep remained cell associated and the extracellular activity was undetectable. High-molecular-mass Nep polypeptides without protease activity were detected as cell associated and extracellularly in the Nep S/A variant, in which the catalytic serine 352 had been changed by alanine, indicating that Nep protease activity was needed for precursor processing and activation. Nep NSN 1-2 containing a modification in two potential cleavage sites for signal peptidase I (ASA) was not efficiently processed and activated. This study examined for the first time the secretion and maturation of a Tat-dependent halophilic subtilase.     

Secretion processing and activation of Erwinia chrysanthemi proteases

E chrysanthemi, a phytopathogenic enterobacterium, secretes several enzymes into the medium such as pectinases cellulases and proteases. It also produces 3 distinct and antigenically related extracellular proteases. The proteases secretion pathway seems to be distinct from that of the other extracellular enzymes since pleiotropic mutants impaired in cellulase and pectinase secretion are unimpaired in protease secretion. E chrysanthemi proteases B and C secretion occurs without an N-terminal signal peptide and is dependent upon specific secretion functions which are encoded by genes adjacent to the protease structural genes. This secretion pathway might be analogous to the alpha-hemolysin secretion pathway in E coli. Protection against intracellular proteolytic activity is achieved by 2 distinct mechanisms: the proteases are synthesized as inactive precursors with an N-terminal extension of 15 aminoacids (protease B) and 17 aminoacids (protease C) absent in the mature active extracellular enzymes; an intracellular specific protease inhibitor is produced by some E chrysanthemi strains.     

A facile reporter system for the experimental identification of twin-arginine translocation (Tat) signal peptides from all kingdoms of life

We have developed a reporter protein system for the experimental verification of twin-arginine signal peptides. This reporter system is based on the Streptomyces coelicolor agarase protein, which is secreted into the growth medium by the twin-arginine translocation (Tat) pathway and whose extracellular activity can be assayed colorimetrically in a semiquantitative manner. Replacement of the native agarase signal peptide with previously characterized twin-arginine signal peptides from other Gram-positive and Gram-negative bacteria resulted in efficient Tat-dependent export of agarase. Candidate twin-arginine signal peptides from archaeal proteins as well as plant thylakoid-targeting sequences were also demonstrated to mediate agarase translocation. A naturally occurring variant signal peptide with an arginine-glutamine motif instead of the consensus di-arginine was additionally recognized as a Tat-targeting sequence by Streptomyces. Application of the agarase assay to previously uncharacterized candidate Tat signal peptides from Bacillus subtilis identified two further probable Tat substrates in this organism. This is the first versatile reporter system for Tat signal peptide identification.     

Protease secretion by Erwinia chrysanthemi. Proteases B and C are synthesized and secreted as zymogens without a signal peptide

The gene encoding the secreted 53-kDa metalloprotease (protease B) and the 5' end of the gene encoding the secreted 55-kDa metalloprotease (protease C) of the Gram-negative bacterium Erwinia chrysanthemi have been sequenced. The predicted sequences of the two proteases do not have typical signal sequences at their NH2 termini. Both proteases are synthesized as inactive higher molecular weight precursors (zymogens proB and proC) which are secreted into the external medium where divalent cation-mediated activation occurs. The activation of proB occurs with a t1/2 of less than 5 min at 37 degrees C in Luria broth medium, whereas that of proC occurs with a t1/2 of about 150 min. The NH2 termini of purified proteases B, proB, and C were sequenced. ProB starts at the initiator methionine whereas B and C start, respectively, at residues +16 and +18 of the sequence deduced from the nucleotide sequence. A short NH2-terminal extension is therefore removed during the activation process, most likely by an autocatalytic mechanism. Protease B shows a high degree of sequence homology with the secreted 50-kDa metalloprotease of Serratia marcescens, which also lacks a signal peptide and for which an inactive higher molecular weight form has been reported.     

Extracellular autoprocessing of a metalloprotease from Streptomyces cacaoi.

We have previously demonstrated that the extracellular neutral metalloprotease (Npr) of Streptomyces cacaoi is synthesized as a 60-kDa preproenzyme (P60), then processed to the 35-kDa mature form (P35) (Chang, P. C., Kuo, T.-C., Tsugita, A., and Lee, Y.-H. W. (1990) Gene (Amst.) 88, 87-95). In this study, we investigated the active site and the mechanism involved in the maturation of the protease. Site-specific mutations at the putative zinc-binding ligands and active site of Npr at His202, Glu203, His206, and Glu240 led to complete abolishment of Npr activity and concomitant accumulation of a 57-kDa inactive protein (P57) which was secreted. Sequence analysis of the NH2 terminus indicated that P57 was derived from P60 after removal of the signal peptide and represented the proenzyme form of Npr (pro-Npr). Analysis of the zinc content of purified mutant P57 proteins revealed a dramatic loss of zinc atom as compared with the wild-type P35 protein. In vitro with the aid of exogenous active Npr, the mutant P57 protein could be converted to the mature inactive P35 with an identical NH2-terminal sequence and a molecular mass the same as that of the wild-type P35. From these studies, we conclude that these highly conserved residues (His202, Glu203, His206, and Glu240) are indispensable for zinc binding and protease activity, as well as processing of Npr. In addition, we have clearly demonstrated that maturation of Npr occurs extracellularly via an autocatalytic cleavage of the pro-Npr propeptide. This is the first report of such a maturation mechanism for an extracellular protease in streptomycetes which can serve as a model for further studies on the mechanism of secretion and processing of proteases from Gram-positive bacteria.     

The role of the N-terminal propeptide of the pro-aminopeptidase processing protease: refolding,processing, and enzyme inhibition

Pro-aminopeptidase processing protease (PA protease) is an extracellular zinc metalloprotease produced by Aeromonas caviae T-64 and it is classified as M04.016 according to the MEROPS database. The precursor of PA protease consists of four regions; a signal peptide, an N-terminal propeptide, a C-terminal propeptide, and the mature PA protease. The in vitro refolding of the intermediate pro-PA protease containing the C-terminal propeptide (MC) was investigated in the presence and absence of the N-terminal propeptide. The results indicate that the noncovalently linked N-terminal propeptide is able to assist in the refolding of MC. In the absence of the N-terminal propeptide, MC is trapped into a folding competent state that is converted into the active form by the addition of the N-terminal propeptide. Moreover, the N-terminal propeptide was found to form a complex with the folded MC and inhibit further processing of MC into the mature PA protease. Inhibitory activity of the purified N-terminal propeptide toward mature PA protease was also observed, and the mode of this inhibition was determined to be a mixed, noncompetitive inhibition with an associated allosteric effect.     

Protease propeptide structures,mechanisms of activation,and functions

Abstract

Proteases are a diverse group of hydrolytic enzymes, ranging from single-domain catalytic molecules to sophisticated multi-functional macromolecules. Human proteases are divided into five mechanistic classes: aspartate, cysteine, metallo, serine and threonine proteases, based on the catalytic mechanism of hydrolysis. As a protective mechanism against uncontrolled proteolysis, proteases are often produced and secreted as inactive precursors, called zymogens, containing inhibitory N-terminal propeptides. Protease propeptide structures vary considerably in length, ranging from dipeptides and propeptides of about 10 amino acids to complex multifunctional prodomains with hundreds of residues. Interestingly, sequence analysis of the different protease domains has demonstrated that propeptide sequences present higher heterogeneity compared with their catalytic domains. Therefore, we suggest that protease inhibition targeting propeptides might be more specific and have less off-target effects than classical inhibitors. The roles of propeptides, besides keeping protease latency, include correct folding of proteases, compartmentalization, liganding, and functional modulation. Changes in the propeptide sequence, thus, have a tremendous impact on the cognate enzymes. Small modifications of the propeptide sequences modulate the activity of the enzymes, which may be useful as a therapeutic strategy. This review provides an overview of known human proteases, with a focus on the role of their propeptides. We review propeptide functions, activation mechanisms, and possible therapeutic applications.     

Identification of plasma proteases inhibited by Manduca sexta serpin-4 and serpin-5 and their association with components of the prophenol oxidase activation pathway

One innate immune response pathway of insects is a serine protease cascade that activates prophenol oxidase (pro-PO) in plasma. However, details of this pathway are not well understood, including the number and order of proteases involved. Protease inhibitors from the serpin superfamily appear to regulate the proteases in the pathway. Manduca sexta serpin-4 and serpin-5 suppress pro-PO activation in plasma, apparently by inhibiting proteases upstream of the direct activator of pro-PO. To identify plasma proteases inhibited by these serpins, we used immunoaffinity chromatography with serpin antibodies to isolate serpin-protease complexes that formed after activation of the cascade by exposure of plasma to bacteria or lipopolysaccharide. Covalent complexes of serpin-4 with hemolymph proteases HP-1 and HP-6 appeared in plasma activated by Gram-positive or Gram-negative bacteria, whereas serpin-4 complexes with HP-21 and two unidentified proteases were unique to plasma treated with Gram-positive bacteria. HP-1 and HP-6 were also identified as target proteases of serpin-5, forming covalent complexes after bacterial activation of the cascade. These results suggest that HP-1 and HP-6 may be components of the pro-PO activation pathway, which are activated in response to infection and regulated by serpin-4 and serpin-5. HP-21 and two unidentified proteases may participate in a Gram-positive bacteria-specific branch of the pathway. Several plasma proteins that co-purified with serpin-protease complexes, most notably immulectins and serine protease homologs, are known to be components of the pro-PO activation pathway. Our results suggest that after activation by exposure to bacteria, components of the pro-PO pathway associate to form a large noncovalent complex, which localizes the melanization reaction to the surface of invading microorganisms.