Biochemical Properties of a Putative Signal Peptide Peptidase from the Hyperthermophilic Archaeon Thermococcus kodakaraensis KOD1

We have performed the first biochemical characterization ofa putative archaeal signal peptide peptidase (SppA_Tk) from thehyperthermophilic archaeon Thermococcus kodakaraensis KOD1.SppA_Tk, comprised of 334 residues, was much smaller than itscounterpart from Escherichia coli (618 residues) and harboreda single predicted transmembrane domain near its N terminus.A truncated mutant protein without the N-terminal 54 amino acidresidues ( ${Delta}$ N54SppA_Tk) was found to be stable against autoproteolysisand was examined further. ${Delta}$ N54SppA_Tk exhibited peptidase activitytowards fluorogenic peptide substrates and was found to be highlythermostable. Moreover, the enzyme displayed a remarkable stabilityand preference for alkaline pH, with optimal activity detectedat pH 10. ${Delta}$ N54SppA_Tk displayed a K_m of 240 ± 18 µMand a V_max of 27.8 ± 0.7 µmol min^–1 mg^–1towards Ala-Ala-Phe-4-methyl-coumaryl-7-amide at 80°C andpH 10. The substrate specificity of the enzyme was examinedin detail with a FRETS peptide library. By analyzing the cleavageproducts with liquid chromatography-mass spectrometry, ${Delta}$ N54SppA_Tkwas found to efficiently cleave peptides with a relatively smallside chain at the P-1 position and a hydrophobic or aromaticresidue at the P-3 position. The positively charged Arg residuewas preferred at the P-4 position, while substrates with negativelycharged residues at the P-2, P-3, or P-4 position were not cleaved.When predicted signal sequences from the T. kodakaraensis genomesequence were examined, we found that the substrate specificityof ${Delta}$ N54SppA_Tk was in good agreement with its presumed role asa signal peptide peptidase in this archaeon.

INTRODUCTION

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Introduction

In the domain Archaea, research on protein secretion and themachinery involved are still at an early stage (32). Sequencecomparison of genome data have shed light on the features ofthe archaeal signal peptide (5) and have also indicated thepresence or absence of individual components corresponding toeukaryotic or bacterial factors participating in protein secretion(12). Factors that have been analyzed in detail include thoseinvolved in flagellum formation in methanogens (8), the signalrecognition particle of Archaeoglobus fulgidus (9) and Sulfolobussolfataricus (33), the Sec complex of Methanocaldococcus jannaschii(38), and the secretion ATPase of Sulfolobus spp. (1).

Signal peptide peptidases are enzymes considered to cleave thesignal peptide chains of secreted proteins after they are removedfrom the precursor proteins by signal peptidases (15, 28). Eukaryoticsignal peptide peptidases are intramembrane enzymes, with activitydependent on two aspartate residues (21, 39). They have becomea center of attention in mammalian cells due to their involvementin immune surveillance. After signal peptide peptidase cleavessignal peptides of the major histocompatibility complex I molecules,the peptide products are presented on the cell surface by anonclassical major histocompatibility complex class I molecule,HLA-E, indicating to natural killer cells that major histocompatibilitycomplex synthesis is proceeding normally (11, 20).

The bacterial signal peptide peptidase was initially identifiedin Escherichia coli as a cytoplasmic membrane protein namedprotease IV (15, 16, 27). The enzyme, encoded by the sppA gene(17, 34), was found to cleave the signal peptide of outer membranelipoprotein after its release from the precursor protein. Furtherstudies have indicated that protease IV (SppA) carries out onlythe initial breakdown of the signal peptide into smaller peptidefragments, followed by complete digestion through the functionsof cytoplasmic peptidases including oligopeptidase A (25, 26).The gram-positive counterpart of SppA in Bacillus subtilis hasalso been studied, and has been shown to be involved in signalpeptide degradation (10). Furthermore, a cytosolic peptidase,TepA, structurally related to both SppA and ClpP has also beenfound to actively participate in the degradation of signal peptidesin this organism (10).

In terms of signal peptidases and signal peptide peptidasesfrom the Archaea, the type I signal peptidase gene from Methanococcusvoltae has been cloned and its product characterized, confirmingthat the protein exhibits signal peptidase activity (24). Residuescritical for the peptidase activity of the protein have beendetermined (7). FlaK, the signal peptidase for preflagellinsignal cleavage, has also been characterized from this organismand has been demonstrated to be an aspartic protease essentialfor preflagellin cleavage (6). In the Crenarchaeota, the homologueof bacterial type IV prepilin peptidases from S. solfataricus(PibD) has been characterized, and residues on the substratethat are important for recognition by PibD have been examined(2). In contrast to the progress on signal peptidases, experimentalexaminations of archaeal signal peptide peptidases have notbeen reported.

Thermococcus kodakaraensis KOD1 is a hyperthermophilic archaeonisolated from a solfatara on Kodakara Island, Kagoshima, Japan(4, 23). The strain is an obligate anaerobe and grows optimallyat 85°C. Only heterotrophic growth has been observed, andthe strain can efficiently utilize and/or degrade amino acids,pyruvate, tryptone, chitin, and starch. The complete genomesequence of T. kodakaraensis has recently been determined andannotated (13). As expected from the growth characteristicsof this strain, the genome sequence revealed the presence ofa large number of extracellular enzymes, including chitinase(36), ${alpha}$ -amylase (35), and subtilisin-like protease (19). An orthologuesearch also revealed that T. kodakaraensis harbors a set offactors involved in protein secretion equivalent to those foundin various hyperthermophilic archaea (see the Kyoto Encyclopediaof Genes and Genomes; http://www.genome.jp/kegg/).

In this study, we have examined the enzymatic properties ofa putative signal peptide peptidase from T. kodakaraensis, revealingthat the substrate specificity of the enzyme is consistent withits presumed role as a signal peptide peptidase in this archaeon.

MATERIALS AND METHODS

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Materials and Methods

Strains, media, and plasmids. T. kodakaraensis KOD1 was cultivated as described elsewhere(4) in order to isolate genomic DNA (29). E. coli DH5 ${alpha}$ and plasmidpUC18 were used for gene cloning, sequencing, and DNA manipulation.E. coli BL21-CodonPlus(DE3)-RIL (Stratagene, La Jolla, CA) andpET21a(+) (Novagen, Madison, WI) were used for gene expression.E. coli strains were cultivated in Luria-Bertani medium (10g liter^–1 of tryptone, 5 g liter^–1 of yeast extract,and 10 g liter^–1 of NaCl) with 100 µg ml^–1ampicillin at 37°C.

DNA manipulation and sequence analysis. Restriction and modification enzymes were purchased from Toyobo(Osaka, Japan). Plasmid DNA was isolated with the Plasmid mini-kitfrom QIAGEN (Hilden, Germany). KOD Plus (Toyobo) was used asa polymerase for PCR, and a GFX PCR DNA and gel band purificationkit (Amersham Biosciences, Buckinghamshire, United Kingdom)was used to recover DNA fragments from agarose gels after electrophoresis.DNA sequencing was performed using BigDye terminator cycle sequencingkit v.3.0 and a model 3100 capillary DNA sequencer (AppliedBiosystems, Foster City, CA). Sequence alignments and constructionof the phylogenetic tree with the neighbor-joining method wereperformed with the ClustalW program available at the DNA DataBank of Japan. Bootstrap resampling was performed 1,000 timeswith the BSTRAP program.

Expression of the sppA_Tk gene in E. coli. The sppA_Tk gene initiating with a Met residue preceding Gln30,omitting the transmembrane domain, was amplified from the genomicDNA of T. kodakaraensis using the primer set sppN1 and sppC1(sppN1, 5'-GTTCTCCATATGCAGGTCAATCCCCCCGCTGT-3'; sppC1, 5'-CAGAATTCAACCACCCCCAATGAGGG-3').The gene for the truncated protein initiating with a Met residuepreceding Cys55 was amplified with sppN2 and sppC1 (sppN2, 5'-ACTTTACGCATATGTGTGAAGGCAGTGTTAAC-3').After confirming the sequences of the DNA fragments, they wereinserted into pET21a(+) at the NdeI and EcoRI sites. After introductioninto E. coli BL21-CodonPlus(DE3)-RIL cells, gene expressionwas induced with 0.1 mM isopropylthiogalactopyranoside (IPTG)at the mid-exponential growth phase with further incubationfor 6 h at 37°C.

Purification of recombinant SppA_Tk. After inducing gene expression, cells were washed with 50 mMTris-HCl (pH 8) and resuspended in the same buffer. Cells weresonicated on ice, and the supernatant after centrifugation (20,000x g, 30 min at 4°C) was applied to heat treatment at 85°Cfor 15 min, immediately cooled on ice, and then centrifuged(20,000 x g, 30 min at 4°C). The soluble protein samplewas brought to 35% saturation with ammonium sulfate and theprecipitate which included SppA_Tk was dissolved in 50 mM Tris-HCl(pH 8) at a concentration of 1 mg ml^–1. This was appliedto anion exchange chromatography (ResourceQ, Amersham Biosciences)equilibrated with 50 mM Tris-HCl (pH 8), 0.2 M NaCl, and proteinswere eluted with a linear gradient (0.2 to 1.0 M, 42 ml) ofNaCl. After desalting with a HiPrep26/10 column (Amersham Biosciences),the sample was applied to gel filtration chromatography (Superdex200 HR 10/30, Amersham Biosciences) equilibrated with 50 mMTris-HCl (pH 8), 0.15 M NaCl, and the fractions obtained wereused for enzyme analysis. Approximately 3 to 7 mg of purifiedoctameric protein was obtained per liter of culture.

Protein analysis of purified recombinant SppA_Tk. The native molecular mass of the purified protein was examinedby gel-filtration chromatography using Superdex 200 HR 10/30in 50 mM Tris-HCl (pH 8), 0.15 M NaCl. The retention time wascalibrated with those of the standard proteins thyroglobulin(669 kDa), ferritin (440 kDa), catalase (232 kDa), aldolase(158 kDa), albumin (67 kDa), ovalbumin (43 kDa), chymotrypsinogenA (25 kDa), and RNase A (13.7 kDa). Protein concentration wasdetermined with the protein assay kit (Bio-Rad, Hercules, CA)using bovine serum albumin as a standard. Determination of N-terminalamino acid sequences of proteins were performed with a proteinsequencer (model 491 cLC, Applied Biosystems) after separationby sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis(PAGE) and electroblotting onto a polyvinylidene difluoridemembrane (Millipore, Bedford, MA).

Enzyme activity measurements. Most activity measurements were performed with peptidyl-MCAsubstrates [peptidyl- ${alpha}$ -(4-methylcoumaryl-7-amide) substrates]available from Peptide Institute (Osaka, Japan). Release of7-amino-4-methylcoumarin was monitored consecutively with afluorescence spectrophotometer capable of maintaining the cuvetteat desired temperatures between 30 and 100°C. Excitationand emission wavelengths were 380 nm and 460 nm, respectively.Standard activity measurements were performed at 60°C ina final volume of 1 ml with 0.1 µg of purified proteinand Ala-Ala-Phe-MCA (200 µM) in 50 mM CHES (N-cyclohexyl-2-aminoethanesulfonicacid; pH 10.0). The final concentration of dimethyl sulfoxideused to dissolve the substrate was constant at 3% of the reactionmixture. Kinetic parameters were calculated with SigmaPlot (SPSSScience, Chicago, IL).

Effects of temperature and pH on enzyme activity. All buffers were prepared so that they would reflect accuratevalues at the applied temperatures. In examining the effectof temperature, the standard assay method was applied at eachtemperature. The effect of pH was examined in the presence of50 mM of morpholineethanesulfonic acid (MES)-NaOH (pH 6.0 to7.0), HEPES-NaOH (pH 7.0 to 8.0), Bicine-NaOH (pH 8.0 to 9.0),CHES-NaOH (pH 9.0 to 10.0), and CAPS (N-cyclohexyl-3-aminopropanesulfonicacid)-NaOH (pH 10.0 to 12.0), respectively. Thermostabilityof the protein was analyzed by measuring the residual activityof the protein after incubation at various temperatures in 50mM CHES-NaOH (pH 10.0). The initial activity of the enzyme incubatedat 60°C was designated as 100%. Alkaline stability was analyzedby measuring the residual activity of the protein after incubationat various pH in 50 mM CAPS-NaOH at 60°C. The initial activityof the enzyme incubated in 50 mM CAPS-NaOH (pH 10.0) was designatedas 100%. In measuring thermostability and alkaline stability,the protein concentration during incubation was 1 µg ml^–1.Residual activities were measured with the standard assay methoddescribed above.

Effect of protease inhibitors. The effects of various protease inhibitors at concentrationsof 200 µM, 1 mM, or 10 mM were examined at 60°C andpH 10. The substrate Ala-Ala-Phe-MCA was present at a concentrationof 200 µM. Activity in the absence of inhibitors was definedas 100%.

Determination of substrate specificity. Substrate specificity was examined with a FRETS peptide library(25Xaa series, Peptide Institute) (37). These peptide substratesharbor a highly fluorescent 2-(N-methylamino)benzoyl group linkedto the side chain of the amino terminal D-2,3-diaminopropionicacid residue (D-A₂pr), along with a 2,4-dinitrophenyl group(quencher) linked to the ${epsilon}$ -amino group of a Lys residue. In betweenthe D-A₂pr and Lys residue lies the peptide Gly-Zaa-Yaa-Xaa-Ala-Phe-Pro,where Zaa is a mixture of Phe, Ala, Val, Glu, and Arg, Yaa isa mixture of Pro, Tyr, Lys, Ile, and Asp, and the Xaa residueis a defined single amino acid of choice (see below). Excitationand emission wavelengths were 340 nm and 440 nm, respectively.

In the initial assay to examine the preference for residuesat the P-1 position, 1 µg of purified enzyme was addedto the reaction mixture with a final volume of 1 ml containing30 µM substrate in 50 mM CHES (pH 10). The final concentrationof dimethyl sulfoxide used to dissolve the substrate was constantat 3% of the reaction mixture. A second assay to identify thecleavage sites and the preference towards residues at the P-2to P-4 positions was performed on selected substrates. Aliquots(100 µl) from the cleavage reactions were taken at varioustime intervals that corresponded to 15 to 30% cleavage of thesubstrates, and subjected to liquid chromatography (LC)-massspectrometry analysis. An ODS A-302 column (YMC, Kyoto, Japan)was used for separation with 0.05% trifluoroacetic acid in H₂Oas eluant A and 0.05% trifluoroacetic acid in CH₃CN as eluantB. The gradient was 5-40% of eluant B in A at a flow rate of1.0 ml min^–1 over a time span of 55 min. Aliquots takenfrom the cleavage reactions were injected and the cleaved productswere monitored with absorbance at 220 nm, as well as fluorescenceintensity in order to identify the N-terminal segments. Thestructures of the cleaved products were deduced from the theoreticalmolecular weights.

RESULTS

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Results

Putative signal peptide peptidase gene on the genome of T. kodakaraensis. Using the primary structure of the signal peptide peptidasefrom E. coli (SppA_Ec), we performed a BLAST search against theprotein sequences of T. kodakaraensis. Although significantlysmaller in size than SppA_Ec (618 amino acid residues), one openreading frame, encoding TK1164 (334 residues), displayed significantsimilarity (27% identical) to SppA_Ec, and was therefore designatedsppA_Tk (Fig. 1). The deduced molecular mass of the protein was36,211 Da. A BLAST search against the complete genome sequencesof various archaeal strains was performed with the SppA_Ec andSppA_Tk sequences. Similar orthologues were found in many generaof the Euryarchaeota, including Picrophilus, Pyrococcus, andThermoplasma, as well as the methanogens and the haloarchaea.We also found orthologues in Nanoarchaeum and the crenarchaeonPyrobaculum.

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FIG. 1. Sequence alignment of putative signal peptide peptidase proteins from E. coli, B. subtilis, and representative archaeal strains. The 19 archaeal SppA sequences described in Fig. 2 were aligned with the sequences of SppA from E. coli and B. subtilis. After alignment, representative sequences were selected. Asterisks indicate highly conserved residues that were present in at least 18 of the 21 sequences aligned. Among these, residues that were conserved in all sequences examined are indicated by stars. The bar above the alignment indicates the putative transmembrane domain of signal peptide peptidase from T. kodakaraensis. Arrowheads indicate the residues that immediately follow the artificial Met residue incorporated in ${Delta}$ N29SppA_Tk and ${Delta}$ N54SppA_Tk. Tko, T. kodakaraensis; Mja, Methanocaldococcus jannaschii; Tac, Thermoplasma acidophilum; PaI, Pyrobaculum aerophilum I; Neq, Nanoarchaeum equitans; Hba, Halobacterium sp. strain NRC-1; Bsp, B. subtilis; Eco, E. coli. Due to their lengths, not all residues are shown for Pyrobaculum aerophilum I (608 residues), Halobacterium sp. strain NRC-1 (300 residues), and E. coli (618 residues).

A phylogenetic analysis of these sequences along with severalselected bacterial sequences is shown in Fig. 2. Although thecatalytic residues have not been experimentally verified, effectsof various inhibitors have suggested that SppA_Ec is a serineprotease (16). We indeed observed multiple serine residues thatwere highly conserved among the archaeal and bacterial SppAsequences (Fig. 1). As in the case of SppA_Ec, SppA_Tk is structurallycategorized in the S49 family of the SK clan of serine proteases(MEROPS, the peptidase database, http://merops.sanger.ac.uk/)(31). Another common feature was that both proteins harboreda putative transmembrane region(s) near their N termini. Basedon these similar features, we set out to express the sppA_Tkgene and examine the enzymatic properties of the recombinantprotein.

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FIG. 2. Phylogenetic tree of putative archaeal SppA sequences. SppA sequences from archaea that displayed high similarity to SppA_Ec and SppA_Tk were analyzed along with the sequences of SppA_Ec and the SppA and TepA from B. subtilis. The proteins used (accession numbers) were B. subtilis SppA (CAB14931) and TepA (CAB13552), E. coli (BAA15557), Haloarcula marismortui I (AAV45638), II (AAV46904), and III (AAV47811), Halobacterium sp. strain NRC-1 (AAG19125), Methanocaldococcus jannaschii (AAB98642), Methanococcus maripaludis (CAF30625), Methanosarcina acetivorans (AAM07395), Methanosarcina mazei (AAM30562), Methanothermobacter thermautotrophicus (AAB85306), Nanoarchaeum equitans (AAR39164), Picrophilus torridus (AAT42796), Pyrobaculum aerophilum I (AAL65089) and II (AAL64441), Pyrococcus abyssi (CAB49512), Pyrococcus furiosus (AAL81707), Pyrococcus horikoshii (BAA30681), Thermococcus kodakaraensis (BAD85353), Thermoplasma acidophilum (CAC11222), and Thermoplasma volcanium (BAB59171). Only bootstrap values above 50 are indicated.

Expression of the sppA_Tk gene in E. coli and purification of the recombinant protein. The putative transmembrane domain of SppA_Tk corresponds to residuesLys7 to Tyr29 (Fig. 1). In order to characterize the catalyticdomain of the protein, we omitted this region when constructingthe expression vector. An artificial Met residue was incorporatedin the place of Tyr29, and this gene was expressed in E. coli.As expected, we obtained a soluble protein ( ${Delta}$ N29SppA_Tk) whichwas resistant to heat treatment at 85°C for 15 min. We foundthat the thermostable protein exhibited peptidase activity towardspeptide substrates such as Ala-Ala-Phe-MCA. The recombinantprotein was purified with ammonium sulfate fractionation, anionexchange chromatography, and gel filtration chromatography.During these procedures, we observed a gradual decrease in themolecular weight of the protein as judged by SDS-PAGE, leadingto three major molecular species (Fig. 3).

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FIG. 3. SDS-PAGE analysis of purified ${Delta}$ N29SppA_Tk (lane 1) and ${Delta}$ N54SppA_Tk (lane 2). Solid dots to the right of lane 1 indicate the purified ${Delta}$ N29SppA_Tk and the major degradation products.

We determined the N-terminal amino acid sequences of each speciesand found that in the smaller proteins, degradation at the N-terminalregion had occurred, probably due to autoproteolysis. As thesmallest species harbored the Cys55 at its extreme N terminus,we reconstructed an expression plasmid so that translation initiatedat a Met residue adjacent to Cys55. The protein produced ( ${Delta}$ N54SppA_Tk)was purified with the methods mentioned above (Fig. 3), andwas found to be relatively stable in terms of proteolytic degradation.This protein, ${Delta}$ N54SppA_Tk, was therefore used for further biochemicalexamination. Although not shown in the results described below, ${Delta}$ N29SppA_Tk and ${Delta}$ N54SppA_Tk displayed similar tendencies in termsof specific activity, pH dependency, and substrate preferenceusing the FRETS peptide library.

Oligomeric form of ${Delta}$ N54SppA_Tk. The molecular mass of the purified ${Delta}$ N54SppA_Tk using gel filtrationchromatography was estimated to be slightly larger than thatof catalase (232 kDa). The molecular mass of a single subunitof ${Delta}$ N54SppA_Tk is 30,421 Da, suggesting that the protein formedan octamer. Besides this major peak, we observed a second peakat 460 to 500 kDa. The octameric form of the protein was usedfor further examination. It should be noted that the resultsobtained here are those of a truncated protein, and may notaccurately reflect the oligomeric state of the native protein,which can be assumed to be associated with the membrane. Ithas previously been reported that the oligomeric form of thenative SppA_Ec was suggested to be tetrameric through cross-linkingexperiments, while the results of native PAGE raised the possibilityof an even higher oligomeric form (17).

Optimal pH and temperature. The effects of pH and temperature on the activity of ${Delta}$ N54SppA_Tkwere examined with the substrate Ala-Ala-Phe-MCA. As shown inFig. 4A, the protein exhibited maximal activity at an unexpectedlyhigh pH range of 10 to 10.5. High levels of activity were maintainedat even higher pH values of 11.5 (58%) and 12 (50%). The effectsof temperature on activity were analyzed with the same substrateat pH 10. Maximum activity under the conditions examined wasobserved at approximately 80°C (Fig. 4B). The Arrheniusplot gave a constant slope from 30°C to 60°C, and theactivation energy of the reaction was calculated to be 54 kJmol^–1 (Fig. 4C). The thermostability of the enzyme wasexamined for 72 h at pH 10 (Fig. 4D), and alkaline stabilitywas measured at 60°C for 48 h (Fig. 4E). In terms of temperature,we observed extremely high stability at 60 and 70°C, withover 60% of the initial activity remaining after 72 h. At 80°C,we detected a relatively greater decrease in activity at theinitial phases of incubation, which was consistently reproducedin multiple experiments. However after 30 min, the enzyme seemedto stabilize and follow the usual deactivation kinetics, wherethe deactivation rate (–dN_E/dt) is proportional to theamount of enzyme (N_E), or –dN_E/dt = kN_E. We still observedover 30% residual activity after 48 h at 80°C and pH 10. ${Delta}$ N54SppA_Tk also exhibited high alkaline stability. Nearly 50%residual activity was observed after 24 h at pH 11.5 and 60°C,and the calculated half-life at pH 12 was approximately 10 h.

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FIG. 4. (A) Effect of pH on the activity of ${Delta}$ N54SppA_Tk. Measurements were performed at 60°C in the following buffers at a concentration of 50 mM: MES-NaOH (open triangles), HEPES-NaOH (solid squares), Bicine-NaOH (open squares), CHES-NaOH (solid circles), and CAPS-NaOH (open circles). (B) Effect of temperature on the activity of ${Delta}$ N54SppA_Tk. Reactions were carried out in 50 mM CHES-NaOH (pH 10.0). (C) Arrhenius plot of B, indicating the activation energy of substrate hydrolysis catalyzed by ${Delta}$ N54SppA_Tk. (D) Thermostability of ${Delta}$ N54SppA_Tk at various temperatures. Incubation of the enzyme was carried out in 50 mM CHES-NaOH (pH 10.0). Symbols: 60°C, open circles; 70°C, solid circles; 80°C, open squares; 90°C, solid squares. (E) Stability of ${Delta}$ N54SppA_Tk at various pHs. Enzyme incubation was carried out at 60°C in 50 mM CAPS-NaOH (pH 10.0, open circles; pH 10.5, solid circles; pH 11.0, open squares; pH 11.5, solid squares; pH 12.0, open triangles). All activity measurements (A to E) were carried out with 200 µM Ala-Ala-Phe-MCA.

Effects of various inhibitors. The effects of various protease inhibitors were examined at60°C and pH 10 (Fig. 5). Leupeptin, chymostatin, and antipainexhibited relatively strong inhibition, leading to an 80% orhigher decrease in activity at 200 µM. Diisopropyl fluorophosphate,which specifically reacts with serine residues, also stronglyinhibited the activity of SppA_Tk at 1 mM. In contrast, additionof EDTA, a typical inhibitor of metalloproteases, and pepstatin,an inhibitor of aspartate proteases, did not result in significantdecreases in activity. Although the effects of phenylmethylsulfonylfluoride were lower than expected, the results as a whole agreewith the assumption that SppA_Tk is a serine protease.

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FIG. 5. Effect of various protease inhibitors on the activity of ${Delta}$ N54SppA_Tk. The inhibitors examined were leupeptin (a), antipain (b), chymostatin (c), diisopropyl fluorophosphate (d), phenylmethylsulfonyl fluoride (e), pepstatin (f), elastatinal (g), and EDTA (h). Activity measurements were performed at 60°C with the indicated inhibitor concentrations.

Preference of ${Delta}$ N54SppA_Tk for various peptidyl-MCA substrates. We examined the activity of ${Delta}$ N54SppA_Tk on various peptidyl-MCAsubstrates shown in Table 1. At pH 10, we found that Ala-Ala-Phe-MCAwas by far the preferred substrate, followed by moderate activitiestowards N-glutaryl (Glt)-Ala-Ala-Phe-MCA and N-benzyloxycarbonyl(Z)-Val-Lys-Met-MCA. At pH 8, the preference became stricter,with Ala-Ala-Phe-MCA and Glt-Ala-Ala-Phe-MCA the only substratesleading to significant cleavage.

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TABLE 1. Activity of ${Delta}$ N54SppA_Tk towards various peptidyl-MCA substrates^a

Kinetic analysis. A kinetic analysis of the reaction catalyzed by ${Delta}$ N54SppA_Tk wascarried out at 80°C and pH 10 with the substrate Ala-Ala-Phe-MCA.The reaction followed Michaelis-Menten kinetics with a K_m of240 ± 18 µM and a V_max of 27.8 ± 0.7 µmolmin^–1 mg protein^–1. The k_cat of the enzyme was calculatedto be 14.1 s^–1.

Examining the substrate preference of ${Delta}$ N54SppA_Tk with a FRETS peptide library. We next evaluated the peptidase activity of ${Delta}$ N54SppA_Tk againsta FRETS peptide library described in Materials and Methods.This analysis provides detailed information on the preferenceof a peptidase towards substrate residues at the P-1, P-2, P-3,and, in some cases, the P-4 position. An initial analysis wascarried out with 19 substrates corresponding to all amino acidsat the Xaa site with the exception of cysteine (Fig. 6A). Wedetected a preference of ${Delta}$ N54SppA_Tk for substrates with rathersmall residues (Gly, Ser, Ala, and Thr) at the Xaa position(Fig. 6B). Cleavage rates of substrates with charged or aromaticresidues were low.

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FIG. 6. (A) Structure of the peptide substrates from a FRETS peptide library utilized in B and C. (B) Peptidase activity towards various substrates from the FRETS peptide library. Amino acid residues at the Xaa position are indicated. Each substrate was examined at a concentration of 30 µM. (C) The major cleaved products of four substrates (Xaa = Gly, Ser, Ala, and Val) were detected by LC-mass spectrometry. Relative quantities are indicated to the right of the sequences.

We next selected four substrates with high cleavage rates (Xaa= Gly, Ser, Ala, and Val), and subjected the cleaved productsto LC-mass spectrometry analysis. In order to identify productsgenerated from the initial cleavage reaction of the substrate,reactions were stopped at various intervals corresponding to15 to 30% substrate cleavage. The most abundant cleavage productsfor each of the four substrates are shown in Fig. 6C. In thecase of Xaa = Gly, we found that cleavage predominantly occurredat the C-terminal amide bond of Ala, and not the expected Glyresidue. In this case, we can obtain insight on the preferredresidues at the P-3 and P-4 sites. At the P-3 site, Ile ledto the highest levels of cleavage, followed by Tyr and Pro.Products with Asp at the P-3 position could not be found. Concerningthe P-4 position, we found a high preference for Arg. We alsodetected products with Phe or Val at the P-4 site. As in thecase of the P-3 residue, we could not find products with thenegatively charged Glu residue at the P-4 site. Among the productsthat were actually cleaved at the Gly residue, Tyr and Lys werefound at the P-2 site, and Phe and Val at the P-3 site.

With Xaa = Ala, Ser, or Val, we found a common tendency withthe results described above for the Xaa = Gly substrate. Inall three cases, the most preferred P-3 residue was Ile or Phe,followed by Val, while cleavage products with negatively chargedresidues at this site were not found. A preference for the positivelycharged Arg at the P-4 site was also observed for all threesubstrates. The results also indicated a broad substrate specificityof ${Delta}$ N54SppA_Tk towards the P-2 residue.

DISCUSSION

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Discussion

We have described the biochemical properties of ${Delta}$ N54SppA_Tk, atruncated form of the putative signal peptide peptidase fromT. kodakaraensis. One remarkable feature of the enzyme was itshigh activity at high alkaline pH. Alkaliphilic proteases haveattracted much attention due to their high demand in application,particularly in the detergent industry (3, 14, 18, 22). A numberof enzymes are commercially available, including Savinase, subtilisinCarlsberg, and subtilisin BPN'. Various strategies in the proteinengineering field have been applied to alkaliphilic proteaseswith the aim to improve their (thermo)stability, and this hasled to significant improvements in terms of catalytic efficiencyand stability (14). However, as ${Delta}$ N54SppA_Tk was obtained froma hyperthermophile, the stability of the enzyme can be regardedas exceptionally high in comparison with previously known alkalineproteases/peptidases. We have detected over 50% residual activityafter incubation at 70°C and pH 10 for 3 days.

As the enzyme exhibits intrinsic thermophilic and alkaliphilicproperties, ${Delta}$ N54SppA_Tk should be an attractive target for futureprotein engineering focusing on the modification of its substratespecificity. We have examined whether ${Delta}$ N54SppA_Tk exhibits hydrolaseactivity towards proteins at 60°C and pH 10. Using bovineserum albumin, ovalbumin, ${alpha}$ -casein, hemoglobin, and lysozyme,we found that protease activity of ${Delta}$ N54SppA_Tk was dependent onthe particular protein substrate. Degradation of bovine serumalbumin and ovalbumin was not observed, while ${alpha}$ -casein, hemoglobin,and lysozyme were degraded to various extents (data not shown).

SppA_Tk is structurally categorized in the S49 family of serineproteases, a prokaryotic family of proteases of which stilllittle is understood. There are no three-dimensional structuresavailable, and moreover, the catalytic mechanism of signal peptidepeptidases and the residues involved have not yet been experimentallydetermined. Information on the enzymatic properties of previouslyidentified signal peptide peptidases is also limited. The specificactivity of SppA_Ec has been measured in several studies andranges between 0.733 µmol mg^–1 min^–1 at 25°Cagainst Z-valine p-nitrophenyl ester (27) and 13.6 µmolmg^–1 min^–1 at 37°C against Z-valine ß-naphthylester (17). Taking into account the V_max at 80°C and theeffects of temperature, the specific activity of the archaealSppA_Tk was calculated to be 6.6 µmol mg^–1 min^–1at 40°C against Ala-Ala-Phe-MCA.

Residues preferred at the cleavage site have also been examinedfor SppA_Ec with both synthetic substrates and signal peptides.The former revealed a preference of cleavage at the C-terminalside of Ala, Leu, Val, Gly, and Phe (27), while the latter indicateda preference for Val, Leu, Ile, Gly, Thr, and Ala (25). As inthe case of the specific activity described above, the substratesused and the conditions applied in these experiments vary greatly,making it difficult to accurately compare the two enzymes. Onepoint that is worthy of note is that many residues (Ala, Val,Thr, and Gly) are commonly preferred at the P-1 site by bothSppA_Ec and SppA_Tk.

By performing a BLAST search against the genome sequences ofarchaea, we were able to identify SppA orthologues in most strainsof Euryarchaeota (Fig. 2). As exceptions, we could not identifyhighly similar orthologues on the A. fulgidus and Methanopyruskandleri genomes. Interestingly, most members of the Crenarchaeotado not seem to utilize structurally related signal peptide peptidases.The two protein sequences from Pyrobaculum aerophilum, the onlySppA orthologues from Crenarchaeota, contained exceptionallylong extensions in their C-terminal domains. Residues that arehighly conserved among bacterial and archaeal SppA sequencesare indicated in Fig. 1 and may be involved in catalysis and/orsubstrate specificity. In particular, Ser162 in SppA_Tk is conservedin all SppA sequences and is also conserved in the functionallyand structurally related B. subtilis TepA protease (10). Althoughthis serine residue of TepA has not been experimentally analyzed,it is included in a region which displays similarity to theregion containing the active site serine of E. coli ClpP, raisingthe possibilities that this residue is the nucleophile in allof these proteins. However, the His and Asp/Glu residues thatconstitute the conventional catalytic triad found in ClpP arenot conserved among the archaeal proteins and are not even presentin the SppA proteins from E. coli and B. subtilis. In orderto accurately determine the active-site residues of SppA proteins,including the nucleophilic serine, site-directed mutagenesisstudies will be necessary.

Using the FRET peptide library, we have been able to clarifysome of the preferences of ${Delta}$ N54SppA_Tk towards residues at theP-1, P-2, P-3, and P-4 sites. A relatively small side chainseems to be preferred at the P-1 position. The specificity atthe P-2 position can be regarded as broad. Hydrophobic and/oraromatic residues are recognized most at the P-3 site, whilethe positively charged Arg enhances the activity of ${Delta}$ N54SppA_Tkwhen present at the P-4 position. Our results also indicatethat the presence of acidic residues at any one of the sitesfrom P-2 to P-4 has a negative effect on the substrate recognitionof ${Delta}$ N54SppA_Tk. With the MCA substrates, a direct comparison amongsubstrates to determine the residue preference of ${Delta}$ N54SppA_Tkwas difficult, as multiple factors differ even between two givensubstrates. One point that can be noted is that a negative chargeat the P-4 position has a large negative effect on substraterecognition (Ala-Ala-Phe-MCA > Glt-Ala-Ala-Phe-MCA).

Taking into account the specificity of ${Delta}$ N54SppA_Tk, we examineda vast number of putative signal sequences that were identifiedon the T. kodakaraensis genome using the SOSUI program. Somerepresentative signal sequences, those from four proteins thathave been experimentally proven to be secreted from T. kodakaraensis(19, 30, 35, 36; unpublished data), are shown in Fig. 7. Asin the case of most putative signal sequences on the T. kodakaraensisgenome, acidic residues are not found, consistent with the factthat ${Delta}$ N54SppA_Tk does not cleave peptides with acidic residuesin the P-2 to P-4 sites. Further, we found a number of candidatesequences in each signal sequence that can be presumed to beefficiently recognized and cleaved by ${Delta}$ N54SppA_Tk.

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FIG. 7. Predicted signal sequences of four T. kodakaraensis proteins that have been biochemically characterized. Prediction was carried out with the SOSUI program. The signal sequence of ${alpha}$ -amylase has been confirmed experimentally. Scissors indicate sites that can be presumed to be cleaved by SppA_Tk when its substrate specificity is taken into account.

Although future gene disruption studies will be necessary toconfirm the physiological role of SppA_Tk, the similarity inprimary structure to SppA_Ec as well as the enzymatic propertiesof the enzyme are in good agreement with the assumption thatSppA_Tk functions as a signal peptide peptidase in T. kodakaraensis.

ACKNOWLEDGMENTS

This work was supported by a grant of the National Project onProtein Structural and Functional Analyses from the Ministryof Education, Culture, Sports, Science and Technology of Japan.

FOOTNOTES

* Corresponding author. Mailing address: Department of Synthetic Chemistry and Biological Chemistry, Graduate School of Engineering, Kyoto University, Katsura, Nishikyo-ku, Kyoto 615-8510, Japan. Phone: 81-(0)75-383-2777. Fax: 81-(0)75-383-2778. E-mail: imanaka{at}sbchem.kyoto-u.ac.jp.

REFERENCES

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