Minimum substrate sequence for signal peptidase I of Escherichia coli

Development of a generic β-lactamase screening system for improved signal peptides for periplasmic targeting of recombinant proteins in Escherichia coli

Targeting of recombinant proteins to the Escherichia coli periplasm is a desirable industrial processing tool to allow formation of disulphide bonds, aid folding and simplify recovery. Proteins are targeted across the inner membrane to the periplasm by an N-terminal signal peptide. The sequence of the signal peptide determines its functionality, but there is no method to predict signal peptide function for specific recombinant proteins, so multiple signal peptides must be screened for their ability to translocate each recombinant protein, limiting throughput. We present a screening system for optimising signal peptides for translocation of a single chain variable (scFv) antibody fragment employing TEM1 β-lactamase (Bla) as a C-terminal reporter of periplasmic localisation. The Pectobacterium carotovorum PelB signal peptide was selected as the starting point for a mutagenic screen. β-lactamase was fused to the C-terminal of scFv and β-lactamase activity was correlated against scFv translocation. Signal peptide libraries were generated and screened for β-lactamase activity, which correlated well to scFv::Bla production, although only some high activity clones had improved periplasmic translocation of scFv::Bla. Selected signal peptides were investigated in fed-batch fermentations for production and translocation of scFv::Bla and scFv without the Bla fusion. Improved signal peptides increased periplasmic scFv activity by ~40%.

Signal Peptidase Enzymology and Substrate Specificity Profiling

Signal peptidases are membrane proteases that play crucial roles in the protein transport pathway of bacteria. They cleave off the signal peptide from precursor proteins that are membrane inserted by the SecYEG or Tat translocons. Signal peptide cleavage releases the translocated protein from the inner membrane allowing the protein to be exported to the periplasm, outer membrane, or secreted into the medium. Signal peptidases are very important proteins to study. They are unique serine proteases with a Ser-Lys dyad, catalyze cleavage at the membrane surface, and are promising potential antibacterial drug targets. This chapter will focus on the isolation of signal peptidases and the preprotein substrates, as well as describe a peptide library approach for characterizing the substrate specificity.

Peptide binding to a bacterial signal peptidase visualized by peptide tethering and carrier-driven crystallization

Bacterial type I signal peptidases (SPases) are membrane-anchored serine proteases that process the signal peptides of proteins exported via the Sec and Tat secretion systems. Despite their crucial importance for bacterial virulence and their attractiveness as drug targets, only one such enzyme, LepB from Escherichia coli, has been structurally characterized, and the transient nature of peptide binding has stymied attempts to directly visualize SPase-substrate complexes. Here, the crystal structure of SpsB, the type I signal peptidase from the Gram-positive pathogen Staphylococcus aureus, is reported, and a peptide-tethering strategy that exploits the use of carrier-driven crystallization is described. This enabled the determination of the crystal structures of three SpsB-peptide complexes, both with cleavable substrates and with an inhibitory peptide. SpsB-peptide interactions in these complexes are almost exclusively limited to the canonical signal-peptide motif Ala-X-Ala, for which clear specificity pockets are found. Minimal contacts are made outside this core, with the variable side chains of the peptides accommodated in shallow grooves or exposed faces. These results illustrate how high fidelity is retained despite broad sequence diversity, in a process that is vital for cell survival.

Structure and mechanism of Escherichia coli type I signal peptidase

Type I signal peptidase is the enzyme responsible for cleaving off the amino-terminal signal peptide from proteins that are secreted across the bacterial cytoplasmic membrane. It is an essential membrane bound enzyme whose serine/lysine catalytic dyad resides on the exo-cytoplasmic surface of the bacterial membrane. This review discusses the progress that has been made in the structural and mechanistic characterization of Escherichia coli type I signal peptidase (SPase I) as well as efforts to develop a novel class of antibiotics based on SPase I inhibition. This article is part of a Special Issue entitled: Protein trafficking and secretion in bacteria. Guest Editors: Anastassios Economou and Ross Dalbey.

Bacterial type I signal peptidases as antibiotic targets

Despite an alarming increase in morbidity and mortality caused by multidrug-resistant bacteria, the number of antibiotics available to efficiently combat them is dwindling. Consequently, there is a pressing need for new drugs, preferably with novel modes of action to avert the problem of cross-resistance. Several new targets have been proposed, including proteins essential in the protein secretion pathway such as the type I signal peptidase (SPase), indispensable for the release of the signal peptide during secretion of Sec- and Tat-dependent proteins. The type I SPase is considered to be an attractive target because it is essential, substantially different from the eukaryotic counterpart, and its active site is located at the outer leaflet of the cytoplasmic membrane, permitting relatively easy access to potential inhibitors. A few SPase inhibitors have already been identified, but their suitability as drugs is yet to be confirmed. An overview is given on the currently known SPase inhibitors, how they can give valuable information on the structural, biochemical and target validation aspects of the SPases, the approaches to identify them, and their future potential as drugs.

Structural studies of a signal peptide in complex with signal peptidase I cytoplasmic domain: the stabilizing effect of membrane-mimetics on the acquired fold

A protein destined for export from the cell cytoplasm is synthesized as a preprotein with an amino-terminal signal peptide. In Escherichia coli, typically signal peptides that guide preproteins into the SecYEG protein conduction channel are subsequently removed by signal peptidase I. To understand the mechanism of this critical step, we have assessed the conformation of the signal peptide when bound to signal peptidase by solution nuclear magnetic resonance. We employed a soluble form of signal peptidase, which laks the two transmembrane domains (SPase I Δ2-75), and the E. coli alkaline phosphatase signal peptide. Using a transferred NOE approach, we found clear evidence of a weak peptide-enzyme complex formation. The peptide adopts a U-turn shape originating from the proline residues within the primary sequence that is stabilized by its interaction with the peptidase and leaves key residues of the cleavage region exposed for proteolysis. In dodecylphosphocholine (DPC) micelles the signal peptide also adopts a U-turn shape comparable with that observed in association with the enzyme. In both environments this conformation is stabilized by the signal peptide phenylalanine side chain-interaction with enzyme or lipid mimetic. Moreover, in the presence of DPC, the N-terminal core region residues of the peptide adopt a helical motif and based on PRE (paramagnetic relaxation enhancement) experiments are shown to be buried within the membrane. Taken together, this is consistent with proteolysis of the preprotein occurring while the signal peptide remains in the bilayer and the enzyme active site functioning at the membrane surface.

In vitro and in vivo approaches to studying the bacterial signal peptide processing

Protein targeting in both eukaryotic and prokaryotic cells is often directed by a signal sequence located at the amino-terminus of the protein. In eukaryotes, proteins that are sorted into different compartments of the cell, such as endoplasmic reticulum, mitochondria, and chloroplast, require different signal sequences. In bacteria, proteins which are exported to the outer membrane or the periplasmic space are also guided by signal peptides. After the protein is translocated across the cytoplasmic membrane, the signal peptide is proteolytically removed by signal peptide cleavage. Here, in this chapter, we describe methods to study signal peptide processing in bacteria, including purification of signal peptidase and its substrates. We also describe the measurement of the catalytic constants of signal peptidases using an in vitro assay. In addition, we will present an in vivo assay using a temperature sensitive signal peptidase strain to determine which preproteins are processed by Signal peptidase 1.

Profiling the substrate specificity of viral protease VP4 by a FRET-based peptide library approach

Knowing the substrate specificity of a protease is useful in determining its physiological substrates, developing robust assays, and designing specific inhibitors against the enzyme. In this work, we report the development of a combinatorial peptide library method for systematically profiling the substrate specificity of endopeptidases. A fluorescent donor (Edans) and quencher (Dabcyl) pair was added to the C- and N-termini of a support-bound peptide. Protease cleavage of the peptide removed the N-terminal quencher, resulting in fluorescent beads, which were isolated and individually sequenced by partial Edman degradation and mass spectrometry (PED-MS) to reveal the peptide sequence, as well as the site of proteolytic cleavage. The method was validated with bovine trypsin and Escherichia coli leader peptidase and subsequently applied to determine the substrate specificity of a viral protease, VP4, derived from the blotched snakehead virus (BSNV). The results show that VP4 cleaves peptides with a consensus sequence of (Abu/Ala/Pro)-X-Ala downward arrowX, in agreement with the previously observed cleavage sites in its protein substrates. Resynthesis and a solution-phase assay of several representative sequences against VP4 confirmed the library screening results.

An easy and fast method for the evaluation of Staphylococcus epidermidis type I signal peptidase inhibitors

In the framework of the search for new antimicrobial therapies to combat resistant bacteria, the type I signal peptidase (SPase I) serves as a potentially interesting target for the development of antibacterials with a new mode of action. Bacterial SPases I play a key role in protein secretion as they are responsible for the cleavage of signal peptides from secreted proteins. For the Gram-positive Staphylococcus epidermidis, an important source of biofilm-associated infections, three putative SPases I (denoted Sip1, Sip2, Sip3) have been described, of which Sip1 lacks the catalytic lysine. Here, we report the in vitro activity of purified Sip2 and Sip3 using pre-SceD as a native preprotein substrate of S. epidermidis and in a FRET-based assay. For the latter, a novel internally quenched fluorescent peptide substrate based on the signal peptide sequence of this native preprotein was developed and specific cleavage of this synthetic fluorogenic peptide substrate was demonstrated. The latter in vitro assay represents a rapid and reliable tool in future research for the identification and validation of potential SPase I inhibitors.

Capillary electrophoresis with laser-induced fluorescence detection as a tool for enzyme characterization and inhibitor screening

An effective, rapid and economical CE/LIF (capillary electrophoresis/laser-induced fluorescence) method was developed and applied to the characterization of signal peptidase (SPase) enzyme, which is a target for the screening of new drug candidates. In this method, CE separates the product from the substrate and LIF selectively detects the fluorescence-labeled product and substrate. By measuring the increase of the product as a function of time, one can monitor the progression of the enzyme reaction. The progression curves were also used for screening inhibitors for this enzyme. The effects of various reaction conditions were also studied and discussed. In addition, this CE/LIF method was applied to the determination of the enzyme activity, the quality control of the substrate and/or enzymes, and the cross-reactivity of inhibitors to the enzyme. It can be concluded that this method is suitable for high throughput screening (HTS) assays because it can deliver fast, sensitive, quantitative, and reliable results.

Surface plasmon resonance-based interaction studies reveal competition of Streptomyces lividans type I signal peptidases for binding preproteins

Type I signal peptidases (SPases) are responsible for the cleavage of signal peptides from secretory proteins.Streptomyces lividanscontains four different SPases, denoted SipW, SipX, SipY and SipZ, having at least some differences in their substrate specificity. In this reportin vitropreprotein binding/processing and protein secretion in single SPase mutants was determined to gain more insight into the substrate specificity of the different SPases and the underlying molecular basis. Results indicated that preproteins do not preferentially bind to a particular SPase, suggesting SPase competition for binding preproteins. This observation, together with the fact that each SPase could process each preprotein tested with a similar efficiency in anin vitroassay, suggested that there is no real specificity in substrate binding and processing, and that they are all actively involved in preprotein processingin vivo. Although this seems to be the case for some proteins tested, high-level secretion of others was clearly dependent on only one particular SPase demonstrating clear differences in substrate preference at thein vivoprocessing level. Hence, these results strongly suggest that there are additional factors other than the cleavage requirements of the enzymes that strongly affect the substrate preference of SPasesin vivo.

Type I signal peptidases of Gram-positive bacteria

Proteins that are exported from the cytoplasm to the periplasm and outer membrane of Gram-negative bacteria, or the cell wall and growth medium of Gram-positive bacteria, are generally synthesized as precursors with a cleavable signal peptide. During or shortly after pre-protein translocation across the cytoplasmic membrane, the signal peptide is removed by signal peptidases. Importantly, pre-protein processing by signal peptidases is essential for bacterial growth and viability. This review is focused on the signal peptidases of Gram-positive bacteria, Bacillus and Streptomyces species in particular. Evolutionary concepts, current knowledge of the catalytic mechanism, substrate specificity requirements and structural aspects are addressed. As major insights in signal peptidase function and structure have been obtained from studies on the signal peptidase LepB of Escherichia coli, similarities and differences between this enzyme and known Gram-positive signal peptidases are highlighted. Notably, while the incentive for previous research on Gram-positive signal peptidases was largely based on their role in the biotechnologically important process of protein secretion, present-day interest in these essential enzymes is primarily derived from the idea that they may serve as targets for novel anti-microbials.

Discovery of substrate for type I signal peptidase SpsB from Staphylococcus aureus

Based on the kinetic model of substrate phage proteolysis, we have formulated a strategy for best manipulating the conditions in screening phage display libraries for protease substrates (Sharkov, N. A., Davis, R. M., Reidhaar-Olson, J. F., Navre, M., and Cai, D. (2001) J. Biol. Chem. 276, 10788-10793). This strategy is exploited in the present study with signal peptidase SpsB from Staphylococcus aureus. We demonstrate that highly active substrate phage clones can be isolated from a phage display library by systematically tuning the selection stringency in screening. Several of the selected clones exhibit superior reactivity over a control, the best clone, SIIIRIII-8, showing >100-fold improvement. Because no conserved sequence features were readily revealed that could allow delineation of the active and unreactive clones, the sequences identified in five of the active clones were tested as synthetic dodecamers, Ac-AGX(8)GA-NH(2). Using electrospray ionization mass spectrometry, we show that four of these peptides can be cleaved by SpsB and that Ala is the P1 residue exclusively and Ala or Leu the P3 residue, in keeping with the (-3, -1) rule for substrate recognition by signal peptidase. Our successful screening with SpsB demonstrated the general applicability of the screening strategy and allowed us to isolate the first peptide substrates for the enzyme.

Kinetic constants of signal peptidase I using cytochrome b5 as a precursor substrate

A procedure is described for measuring Escherichia coli signal peptidase I activity which exploits an intact precursor protein composed of the alkaline phosphatase signal peptide fused to the full length mammalian cytochrome b5. This cytochrome b5 precursor protein has been extensively characterised and shown to be processed accurately by purified signal peptidase I [Protein Expr. Purif. 7 (1996) 237]. The amphipathic, chimaeric cytochrome b5 precursor was isolated in mg quantities in a highly homogeneous state under non-denaturing conditions. The processing of the cytochrome b5 precursor by signal peptidase displayed Michaelis-Menten kinetics with K(m)=50 microM and k(cat)=11 s(-1). The K(m) was 20-fold lower than that obtained with signal peptide substrates and 3-fold higher than that reported for pro-OmpA-nuclease A precursor fusion. The corresponding turnover number, k(cat), was four orders of magnitude greater than the peptide substrates but was 2-fold lower than pro-OmpA-nuclease A precursor fusion. These results confirm that both the affinities and the catalytic power of the signal peptidase are significantly higher for macromolecular precursor substrates than for the shorter signal peptide substrates.

Biochemical characterization of signal peptidase I from gram-positive Streptococcus pneumoniae

Bacterial signal peptidase I is responsible for proteolytic processing of the precursors of secreted proteins. The enzymes from gram-negative and -positive bacteria are different in structure and specificity. In this study, we have cloned, expressed, and purified the signal peptidase I of gram-positive Streptococcus pneumoniae. The precursor of streptokinase, an extracellular protein produced in pathogenic streptococci, was identified as a substrate of S. pneumoniae signal peptidase I. Phospholipids were found to stimulate the enzymatic activity. Mutagenetic analysis demonstrated that residues serine 38 and lysine 76 of S. pneumoniae signal peptidase I are critical for enzyme activity and involved in the active site to form a serine-lysine catalytic dyad, which is similar to LexA-like proteases and Escherichia coli signal peptidase I. Similar to LexA-like proteases, S. pneumoniae signal peptidase I catalyzes an intermolecular self-cleavage in vitro, and an internal cleavage site has been identified between glycine 36 and histidine 37. Sequence analysis revealed that the signal peptidase I and LexA-like proteases show sequence homology around the active sites and some common properties around the self-cleavage sites. All these data suggest that signal peptidase I and LexA-like proteases are closely related and belong to a novel class of serine proteases.

The structure and mechanism of bacterial type I signal peptidases. A novel antibiotic target

Type I signal peptidases are essential membrane-bound serine proteases that function to cleave the amino-terminal signal peptide extension from proteins that are translocated across biological membranes. The bacterial signal peptidases are unique serine proteases that utilize a Ser/Lys catalytic dyad mechanism in place of the classical Ser/His/Asp catalytic triad mechanism. They represent a potential novel antibiotic target at the bacterial membrane surface. This review will discuss the bacterial signal peptidases that have been characterized to date, as well as putative signal peptidase sequences that have been recognized via bacterial genome sequencing. We review the investigations into the mechanism of Escherichia coli and Bacillus subtilis signal peptidase, and discuss the results in light of the recent crystal structure of the E. coli signal peptidase in complex with a beta-lactam-type inhibitor. The proposed conserved structural features of Type I signal peptidases give additional insight into the mechanism of this unique enzyme.

Production and characterization of two variants of human cystatin SA encoded by two alleles at the CST2 locus of the type 2 cystatin gene family

Two variants of cystatin SA encoded by two alleles at the CST2 locus of the type 2 human cystatin gene family were expressed in Escherichia coli. One, termed cystatin SA1, is identical to cystatin SA [S. Isemura, E. Saitoh, and K. Sanada J. Biochem. 102, 693-704, 1987]. Another, termed cystatin SA2, carries two amino acid substitutions (59Gly-->Asp; 120Glu-->Asp), one of which is in the so-called QXVXG region (the first hairpin loop) and another in the C-terminal portion of the molecule. Four recombinant cystatins [full-sized cystatin SA1, two N-terminally truncated cystatin SA1 lacking four residues (WSPQ) and six residues (WSPQEE), and full-sized cystatin SA2] were purified from the periplasmic fractions of E. coli cells. Two N-terminally truncated recombinant cystatin SA1 inhibited bovine cathepsin C with 2- to 20-fold lower Ki values than that of the full-sized one. In the inhibition of papain and ficin, however, both of the N-terminally truncated cystatin SA1 displayed a 10-fold higher Ki value than that of full-sized one. In the inhibition of papain, ficin, and recombinant human cathepsin K, recombinant cystatin SA2 showed, respectively, 3826-, 1090-, and 30-fold higher Ki values compared with those of SA1. Recombinant cystatin SA2 inhibited bovine cathepsin C with a 50-fold lower Ki value compared with that of SA1. Recombinant cystatin SA1 did not inhibit human cathepsin H but SA2 inhibited it slightly (Ki = 528 nM). Neither of the recombinant variants inhibited bovine cathepsin B. Our data supply evidence indicating that the amino acid sequence of the first hairpin loop of the cystatin superfamily is important in the inhibition of papain, ficin, cathepsin C, cathepsin H, and cathepsin K.

Development of an internally quenched fluorescent substrate for Escherichia coli leader peptidase

Escherichia coli leader peptidase, an integral membrane protein, is responsible for the cleavage of the signal sequence of many exported proteins. Recent studies suggest that it is a novel serine protease that utilizes a serine-lysine catalytic dyad. In an effort to further understand the mechanism of this enzyme, an internally quenched fluorescent peptide substrate incorporating the leader peptidase cleavage site of maltose binding protein signal peptide, Y(NO2)-F-S-A-S-A-L-A-K-I-K(Abz) (anthraniloyl), was designed and synthesized. In the intact peptide, the fluorescence of the anthraniloyl group is quenched by the 3-nitrotyrosine. This quenched fluorescence is liberated upon cleavage of the peptide by the leader peptidase, resulting in increased fluorescence that could then be monitored fluorometrically. The designed substrate can be cleaved effectively by E. coli leader peptidase as detected by both HPLC and fluorescent spectroscopy. Mass spectra of cleavage products demonstrated that the cleavage occurs at the predicted site (A-K). The cleavage of the peptide substrate has a linear dependence on the enzyme concentration (0.1 to 1.9 microM) and the kcat/K(m) was calculated to be 71.1 M-1 s-1. These data are comparable with the unmodified peptide substrate. This report represents the first direct continuous assay based on fluorescence resonance energy transfer for E. coli leader peptidase.

The chemistry and enzymology of the type I signal peptidases

The discovery that proteins exported from the cytoplasm are typically synthesized as larger precursors with cleavable signal peptides has focused interest on the peptidases that remove the signal peptides. Here, we review the membrane-bound peptidases dedicated to the processing of protein precursors that are found in the plasma membrane of prokaryotes and the endoplasmic reticulum, the mitochondrial inner membrane, and the chloroplast thylakoidal membrane of eukaryotes. These peptidases are termed type I signal (or leader) peptidases. They share the unusual feature of being resistant to the general inhibitors of the four well-characterized peptidase classes. The eukaryotic and prokaryotic signal peptidases appear to belong to a single peptidase family. This review emphasizes the evolutionary concepts, current knowledge of the catalytic mechanism, and substrate specificity requirements of the signal peptidases.

Use of site-directed chemical modification to study an essential lysine in Escherichia coli leader peptidase

Escherichia coli leader peptidase, which catalyzes the cleavage of signal peptides from pre-proteins, is an essential, integral membrane serine peptidase that has its active site residing in the periplasmic space. It contains a conserved lysine residue that has been proposed to act as the general base, abstracting the proton from the side chain hydroxyl group of the nucleophilic serine 90. To help elucidate the role of the essential lysine 145 in the activity of E. coli leader peptidase, we have combined site-directed mutagenesis and chemical modification methods to introduce unnatural amino acid side chains at the 145-position. We show that partial activity can be restored to an inactive K145C leader peptidase mutant by reacting it with 2-bromoethylamine.HBr to produce a lysine analog (gamma-thia-lysine) at the 145-position. Modification with the reagents 3-bromopropylamine.HBr and 2-mercaptoethylamine also allowed for partial restoration of activity showing that there is some flexibility in the length requirements of this essential residue. Modification with (2-bromoethyl)trimethylammonium.Br to form a positively charged, nontitratable side chain at the 145-position failed to restore activity to the inactive K145C leader peptidase mutant. This result, along with an inactive K145R mutant result, supports the claim that the lysine side chain at the 145-position is essential due to its ability to form a hydrogen bond(s) or to act as a general base rather than because of an ability to form a critical salt bridge. We find that leader peptidase processes the pre-protein substrate, pro-OmpA nuclease A, with maximum efficiency at pH 9.0, and apparent pKa values for titratable groups at approximately 8.7 and 9.3 are revealed. We show that the lysine modifier maleic anhydride inhibits leader peptidase by reacting with lysine 145. The results of this study are consistent with the hypothesis that the lysine at the 145-position of leader peptidase functions as the active site general base. A model of the active site region of leader peptidase is presented based on the structure of the E. coli UmuD', and a mechanism for bacterial leader peptidase is proposed.

Identification of Trp300 as an important residue for Escherichia coli leader peptidase activity

We previously reported that leader peptidase from Escherichia coli was extensively inactivated by reaction with N-bromosuccinimide with concomitant and selective modification of the Trp300 and Trp310 residues [Kim, Y.-T., Muramatsu, T. & Takahashi, K. (1995) J. Biochem. (Tokyo) 117, 535-544]. This indicated that one or both of these tryptophan residues are important for the activity of the enzyme. In order to define further the role of individual tryptophan residues in the activity of leader peptidase, site-directed mutagenesis studies were performed to replace each tryptophan residue with phenylalanine and/or alanine. The replacements of Trp20, Trp59, Trp261, Trp284, and Trp310 with phenylalanine hardly affected the enzyme activity toward a synthetic peptide substrate and the ability to complement the temperature sensitivity of the mutant leader peptidase in E. coli IT41. In contrast, the activity toward the synthetic substrate was significantly decreased by replacement of Trp300 with phenylalanine or alanine. The kcat values of the W300F and W300A mutant enzymes were reduced to 42% and 22%, respectively, of that of the wild-type enzyme, whereas the Km values of these mutant enzymes were almost identical with that of the wild-type enzyme. Moreover, the complementing ability in E. coli IT41 was lost (almost) completely when Trp300 was replaced with phenylalanine or alanine. These results strongly indicate that Trp300 in leader peptidase is important for the catalytic mechanism and/or the construction of the active site structure of the enzyme.

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 (delta 2-75). 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 P4(2)2(1)2, with unit cell dimensions of a = b = 115 A and c = 100 A, and contain 2 molecules per asymmetric unit. This is the first report of the crystallization of a leader (or signal) peptidase.

Characterization of a soluble, catalytically active form of Escherichia coli leader peptidase: requirement of detergent or phospholipid for optimal activity

Leader peptidase is a novel serine protease in Escherichia coli, which functions to cleave leader sequences from exported proteins. Its catalytic domain extends into the periplasmic space and is anchored to the membrane by two transmembrane segments located at the N-terminal end of the protein. At present, there is no information on the structure of the catalytic domain. Here, we report on the properties of a soluble form of leader peptidase (delta 2-75), and we compare its properties to those of the wild-type enzyme. We find that the truncated leader peptidase has a kcat of 3.0 S-1 and a Km of 32 microM with a pro-OmpA nuclease A substrate. In contrast to the wild-type enzyme (pI of 6.8), delta 2-75 is water-soluble and has an acidic isoelectric point of 5.6. We also show with delta 2-75 that the replacement of serine 90 and lysine 145 with alanine residues results in a 500-fold reduction in activity, providing further evidence that leader peptidase employs a catalytic serine/lysine dyad. Finally, we find that the catalysis of delta 2-75 is accelerated by the presence of the detergent Triton X-100, regardless if the substrate is pro-OmpA nuclease A or a peptide substrate. Triton X-100 is required for optimal activity of delta 2-75 at a level far below the critical micelle concentration. Moreover, we find that E. coli phospholipids stimulate the activity of delta 2-75, suggesting that phospholipids may play an important physiological role in the catalytic mechanism of leader peptidase.

Identification of the potential active site of the signal peptidase SipS of Bacillus subtilis. Structural and functional similarities with LexA-like proteases

Signal peptidases remove signal peptides from secretory proteins. By comparing the type I signal peptidase, SipS, of Bacillus subtilis with signal peptidases from prokaryotes, mitochondria, and the endoplasmic reticular membrane, patterns of conserved amino acids were discovered. The conserved residues of SipS were altered by site-directed mutagenesis. Replacement of methionine 44 by alanine yielded an enzyme with increased activity. Two residues (aspartic acid 146 and arginine 84) appeared to be conformational determinants; three other residues (serine 43, lysine 83, and aspartic acid 153) were critical for activity. Comparison of SipS with other proteases requiring serine, lysine, or aspartic acid residues in catalysis revealed sequence similarity between the region of SipS around serine 43 and lysine 83 and the active-site region of LexA-like proteases. Furthermore, self-cleavage sites of LexA-like proteases closely resembled signal peptidase cleavage sites. Together with the finding that serine and lysine residues are critical for activity of the signal peptidase of Escherichia coli (Tschantz, W.R., Sung, M., Delgado-Partin, V.M., and Dalbey, R.E. (1993) J. Biol. Chem. 268, 27349-27354), our data indicate that type I signal peptidases and LexA-like proteases are structurally and functionally related serine proteases. A model envisaging a catalytic serine-lysine dyad in prokaryotic type I signal peptidases is proposed to accommodate our observations.

Families of serine peptidases

This chapter examines families of serine peptidases. Serine peptidases are found in viruses, bacteria, and eukaryotes. They include exopeptidases, endopeptidases, oligopeptidases, and omega peptidases. On the basis of three-dimensional structures, most of the serine peptidase families can be grouped together into about six clans that may have common ancestors. The structures are known for members of four of the clans, chymotrypsin, subtilisin, carboxypeptidase C, and Escherichia D-Ala-D-Ala peptidase A. The peptidases of chymotrypsin, subtilisin, and carboxypeptidase C clans have a common “catalytic triad” of three amino acids—namely, serine (nucleophile), aspartate (electrophile), and histidine (base). The geometric orientations of these are closely similar between families; however the protein folds are quite different. The arrangements of the catalytic residues in the linear sequences of members of the various families commonly reflect their relationships at the clan level. The members of the chymotrypsin family are almost entirely confined to animals. 10 families are included in chymotrypsin clan (SA), and all the active members of these families are endopeptidases. The order of catalytic residues in the polypeptide chain in clan SA is His/Asp/Ser.

Evidence that the catalytic activity of prokaryote leader peptidase depends upon the operation of a serine-lysine catalytic dyad

Leader peptidase (LP) is the enzyme responsible for proteolytic cleavage of the amino acid leader sequence from bacterial preproteins. Recent data indicate that LP may be an unusual serine proteinase which operates without involvement of a histidine residue (M. T. Black, J. G. R. Munn, and A. E. Allsop, Biochem. J. 282:539-543, 1992; M. Sung and R. E. Dalbey, J. Biol. Chem. 267:13154-13159, 1992) and that, therefore, one or more alternative residues must perform the function of a catalytic base. With the aid of sequence alignments, site-specific mutagenesis of the gene encoding LP (lepB) from Escherichia coli has been employed to investigate the mechanism of action of the enzyme. Various mutant forms of plasmid-borne LP were tested for their abilities to complement the temperature-sensitive activity of LP in E. coli IT41. Data are presented which indicate that the only conserved amino acid residue possessing a side chain with the potential to ionize, and therefore with the potential to transfer protons, which cannot be substituted with a neutral side chain is lysine at position 145. The data suggest that the catalytic activity of LP is dependent on the operation of a serine-lysine catalytic dyad.

Signal peptidases in prokaryotes and eukaryotes--a new protease family

Signal peptidases remove targeting peptides from pre-proteins and play central roles in the secretory pathway, as well as in the delivery of proteins to the mitochondrial intermembrane space and to the lumen of thylakoids. The catalytic mechanism of pre-protein cleavage has long been an enigma, but recent data from site-directed mutagenesis and sequence alignment studies suggest that signal peptidases may constitute a new type of serine protease, mechanistically related to the beta-lactamases.

Kinetics and sequence specificity of processing of prepilin by PilD, the type IV leader peptidase of Pseudomonas aeruginosa

PilD, originally isolated as an essential component for the biogenesis of the type IV pili of Pseudomonas aeruginosa, is a unique endopeptidase responsible for processing the precursors of the P. aeruginosa pilin subunits. It is also required for the cleavage of the leader peptides from the Pdd proteins, which are essential components of an extracellular secretion pathway specific for the export of a number of P. aeruginosa hydrolytic enzymes and toxins. Substrates for PilD are initially synthesized with short, i.e., 6- to 8-amino-acid-long, leader peptides with a net basic charge and share a high degree of amino acid homology through the first 16 to 30 residues at the amino terminus. In addition, they all have a phenylalanine residue at the +1 site relative to the cleavage site, which is N methylated prior to assembly into the oligomeric structures. In this study, the kinetics of leader peptide cleavage from the precursor of the P. aeruginosa pilin subunit by PilD was determined in vitro. The rates of cleavage were compared for purified enzyme and substrate as well as for enzyme and substrate contained within total membranes extracted from P. aeruginosa strains overexpressing the cloned pilD or pilA genes. Optimal conditions were obtained only when both PilD and substrate were contained within total membranes. PilD catalysis of P. aeruginosa prepilin followed normal Michaelis-Menten kinetics, with a measured apparent Km of approximately 650 microM, and a kcat of 180 min-1. The kinetics of PilD processing of another type IV pilin precursor, that from Neisseria gonorrhoeae with a 7-amino-acid-long leader peptide, were essentially the same as that measured for wild-type P. aeruginosa prepilin. Quite different results were obtained for a number of prepilin substrates containing substitutions at the conserved phenylalanine at the +1 position relative to the cleavage site, which were previously shown to be well tolerated in vivo. Substitutions of methionine, serine, and cysteine for phenylalanine show that Km values remain close to that measured for wild-type substrate, while kcat and kcat/Km values were significantly decreased. This indicates that while the affinity of enzyme for substrate is relatively unaffected by the substitutions, the maximum rate of catalysis favors a phenylalanine at this position. Interesting, PilD cleavage of one mutated pillin (asparagine) resulted in a lower Km value of 52.5 microM, which indicates a higher affinity for the enzyme, as well as a lower kcat value of 6.1 min m(-1). This suggests that it may be feasible to design peptide inhibitors of PilD.

Proteolysis in protein import and export: signal peptide processing in eu- and prokaryotes

Numerous proteins in pro- and eukaryotes must cross cellular membranes in order to reach their site of function. Many of these proteins carry signal sequences that are removed by specific signal peptidases during, or shortly after, membrane transport. Signal peptidases have been identified in the rough endoplasmic reticulum, the matrix and inner membrane of mitochondria, the stroma and thylakoid membrane of chloroplasts, the bacterial plasma membrane and the thylakoid membrane of cyanobacteria. The composition of these peptidases varies between one and several subunits. No site-specific inhibitors are known for the majority of these enzymes. Accordingly, signal peptidases recognize structural motifs rather than linear amino acid sequences. Such motifs have become evident by employing extensive site-directed mutagenesis to investigate the anatomy of signal sequences. Analysis of the reaction specificities and the primary sequences of several signal peptidases suggests that the enzymes of the endoplasmic reticulum, the inner mitochondrial membrane and the thylakoid membrane of chloroplasts all have evolved from bacterial progenitors.

Inter-molecular degradation of signal peptidase I in vitro

Highly purified preparations of signal peptidase I (36 kDa) were found to undergo an apparent inter-autocatalytic degradation at 4 degrees C and 37 degrees C. The disappearance of the 36 kDa protein coincided with the stable appearance of a 31 kDa and a 5 kDa species. Amino-terminal sequencing of the 31 kDa product indicated a site specific cleavage following Ala38-Gln-Ala of signal peptidase I. The 31 kDa fragment was purified and shown to have 100-fold less activity than the native enzyme, with pre-maltose binding protein as a substrate.

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.