A norovirus protease structure provides insights into active and substrate binding site integrity

Norovirus 3C-like proteases are crucial to proteolytic processing of norovirus polyproteins. We determined the crystal structure of the 3C-like protease from Chiba virus, a norovirus, at 2.8-A resolution. An active site including Cys139 and His30 is present, as is a hydrogen bond network that stabilizes the active site conformation. In the oxyanion hole backbone, a structural difference was observed probably upon substrate binding. A peptide substrate/enzyme model shows that several interactions between the two components are critical for substrate binding and that the S1 and S2 sites appropriately accommodate the substrate P1 and P2 residues, respectively. Knowledge of the structure and a previous mutagenesis study allow us to correlate proteolysis and structure.     

Effect of N-methylation on the modulation by synthetic peptides of the activity of the complement-factor-B-derived serine proteinase CVFBb.

Although they share the active-site catalytic triad of less-specific enzymes such as trypsin and chymotrypsin, the serine proteinases of the complement and coagulation cascades each cleave a highly restricted set of substrates. Peptides with sequences similar to that at which C3 is cleaved by the alternative-pathway complement proteinase CVFBb were synthesized by solid-phase methodology and examined for their effects on the activity of this enzyme as measured by three different types of assays. It was found that a peptide methylated at the scissile bond was a far more effective inhibitor of the cleavage of the protein substrate C5 and of the lysis of guinea-pig erythrocytes by the alternative pathway than was the equivalent unmethylated peptide. Whereas the unmethylated peptide inhibited cleavage of the peptide substrate, the methylated peptide actually stimulated cleavage in this assay. This stimulation was found to be due to a 2.8-fold increase in kcat; the dissociation constant for the substrate was not altered significantly. One model consistent with this behaviour is that the binding of the activator peptide in the extended substrate-recognition region stabilizes a catalytically more active conformation of the active site. A small peptide substrate may have access to such an activated active site, whereas the larger substrate, C5, may be excluded from the site. These results demonstrate that the observed effect of a given compound on activity of an enzyme with an extended substrate-recognition region may depend upon the substrate.     

Pepsin as a catalyst of peptide synthesis. Enzyme co-precipitation with emerging peptide products.

Pepsin successfully catalyzed the synthesis of several peptide derivatives from N-protected di- or tripeptides and amino acid or peptide esters or p-nitroanilides in dimethylformamide-water solutions at pH 4.6. An optimal substrates:pepsin ratio depended on the structure of starting peptides, especially their fit to the substrate binding sites of the enzyme. For hexapeptide Z-Ala-Ala-Phe-Leu-Ala-Ala-OCH3 formation, an equilibrium yield was attained at 1:3.10(5) enzyme-substrates ratio that indicated high efficiency of pepsin in synthesis reactions. In the course of the equilibrium peptide synthesis, pepsin gradually disappeared from the liquid phase due to its entrapment within a gel, formed by the hexapeptide product, while retaining its activity. The inclusion into the precipitate was not specific for pepsin, so far as inert proteins, lysozyme, ribonuclease A and carbonic anhydrase, when added to the reaction mixture, became also co-precipitated with the hexapeptide formed. It appears that co-precipitation of pepsin, an important factor limiting the enzyme efficiency, might be operative as well for other proteinases used to catalyze peptide synthesis.     

Substitution of valine for glycine-558 in the congenital dysthrombin thrombin Quick II alters primary substrate specificity

Thrombin Quick II is one of two dysfunctional forms of thrombin derived from the previously described congenital dysprothrombin prothrombin Quick. Thrombin Quick II does not clot fibrinogen, hydrolyze p-nitroanilide substrates of thrombin, or bind N2-[5-(dimethylamino)naphthalene-1-sulfonyl]arginine N,N-(3-ethyl-1,5-pentanediyl)amide, a high-affinity competitive inhibitor of thrombin. To determine the structural alteration in thrombin Quick II, the reduced, carboxymethylated protein was hydrolyzed by a lysyl endopeptidase. A peptide not present in a parallel thrombin hydrolysate was identified by reverse-phase chromatography. The peptide was purified by rechromatography and subjected to Edman degradation which showed that Gly-558 of human prothrombin had been replaced by Val. This corresponds to a point mutation of the Gly codon GGC to GUC. This Gly residue, which is highly conserved in the chymotrypsin family of serine proteases, forms part of the substrate binding pocket for bulky aromatic and basic side chains in chymotrypsin and trypsin, respectively. However, in porcine elastase 1, the corresponding residue is threonine. Consistent with the identified structural alteration, thrombin Quick II incorporates [3H]diisopropyl fluorophosphate stoichiometrically and hydrolyzes the elastase substrate succinyl-Ala-Ala-Pro-Leu-p-nitroanilide with a relative kcat/KM of 0.14 when compared to thrombin. This results from a 3-fold increase in KM and a 2.5-fold decrease in kcat for thrombin Quick II when compared to thrombin acting on the same substrate. These results and those of other investigators studying mutant trypsins support the conclusion that the catalytic activity of serine proteases is very sensitive to structural alterations in the primary substrate binding pocket.     

Contribution of the glutamine 19 side chain to transition-state stabilization in the oxyanion hole of papain

The existence of an oxyanion hole in cysteine proteases able to stabilize a transition-state complex in a manner analogous to that found with serine proteases has been the object of controversy for many years. In papain, the side chain of Gln19 forms one of the hydrogen-bond donors in the putative oxyanion hole, and its contribution to transition-state stabilization has been evaluated by site-directed mutagenesis. Mutation of Gln19 to Ala caused a decrease in kcat/KM for hydrolysis of CBZ-Phe-Arg-MCA, which is 7700 M-1 s-1 in the mutant enzyme as compared to 464,000 M-1 s-1 in wild-type papain. With a Gln19Ser variant, the activity is even lower, with a kcat/KM value of 760 M-1 s-1. The 60- and 600-fold decreases in kcat/KM correspond to changes in free energy of catalysis of 2.4 and 3.8 kcal/mol for Gln19Ala and Gln19Ser, respectively. In both cases, the decrease in activity is in large part attributable to a decrease in kcat, while KM values are only slightly affected. These results indicate that the oxyanion hole is operational in the papain-catalyzed hydrolysis of CBZ-Phe-Arg-MCA and constitute the first direct evidence of a mechanistic requirement for oxyanion stabilization in the transition state of reactions catalyzed by cysteine proteases. The equilibrium constants Ki for inhibition of the papain mutants by the aldehyde Ac-Phe-Gly-CHO have also been determined. Contrary to the results with the substrate, mutation at position 19 of papain has a very small effect on binding of the inhibitor.(ABSTRACT TRUNCATED AT 250 WORDS)     

Role of catalytic residues in the formation of a tetrahedral adduct in the acylation reaction of bovine β-trypsin: A molecular orbital study

In the acylation reaction of serine proteases the effect of amino acid residues on the geometrical change of the catalytic site from Michaelis to tetrahedral state was studied by using ab initio molecular orbital calculations. Amino acid residues in the catalytic site and the peptide substrate were calculated as a quantum mechanical region, and all the other amino acid residues and the calcium ion were included in the calculation as the electrostatic effects. The effects of Asp102, Asp194, N-terminus and the oxyanion binding site are large. The oxyanion binding site directly stabilizes the tetrahedral substrate. Asp102 stabilizes the enzyme intermediate, interacting with the protonated His57 residue. In order to elucidate the roles of Asp102 and the oxyanion binding site, energy decomposition analyses were done for the intermolecular interactions. The contribution of Asp102 and the oxyanion binding site to the decrease of energy in the geometrical change is due to the electrostatic effect. The energies of the proton shuttle from Ser195 O^γ to the leaving group of the substrate were calculated for amide and ester substrate models.     

An internally quenched fluorescent substrate for collagenase

A synthetic collagenase substrate containing the internal peptide sequence--Gly-Gly-Pro-Leu-Gly-Pro-Pro-Gly-Pro--has been synthesized, with an N-terminus 4-((4-(dimethylamino)phenyl)azo)-benzoyl (DABCYL) group and C-terminus 5-[2-(acetamido)ethylamino] naphthalene-1-sulfonic acid (AEDANS) moiety resulting in internal quenching of AEDANS fluorescence. Peptide bond hydrolysis results in a large increase in fluorescence at 490 nm upon excitation at 336 nm. The substrate is cleaved exclusively by Clostridium histolyticum collagenase and is completely resistant to attack by proteases like thermolysin, proteinase K, and trypsin. K(m) and V(max) values for substrate hydrolysis by collagenase have been determined, establishing the peptide as one of the best binding substrates for the enzyme. MALDI mass spectrometry using a derivative of the substrate establishes that the sites of cleavage lie within the collagen like domain. The CD spectrum of an analog peptide lacking the donor and acceptor groups reveals spectral features that are reminiscent of weak polyproline structures.     

Macromolecular substrate affinity for the tissue factor-factor VIIa complex is independent of scissile bond docking.

The upstream coagulation enzymes are homologous trypsin-like serine proteases that typically function in enzyme-cofactor complexes, exemplified by coagulation factor VIIa (VIIa), which is allosterically activated upon binding to its cell surface receptor tissue factor (TF). TF cooperates with VIIa to create a bimolecular recognition surface that serves as an exosite for factor X binding. This study analyzes to what extent scissile bond docking to the catalytic cleft contributes to macromolecular substrate affinity. Mutation of the P1 Arg residue in factor X to Gln prevented activation by the TF.VIIa complex but did not reduce macromolecular substrate affinity for TF.VIIa. Similarly, mutations of the S and S' subsites in the catalytic cleft of the enzyme VIIa failed to reduce affinity for factor X, although the affinity for small chromogenic substrates and the efficiency of factor X scissile bond cleavage were reduced. Thus, docking of the activation peptide bond to the catalytic cleft of this enzyme-cofactor complex does not significantly contribute to affinity for macromolecular substrate. Rather, it appears that the creation of an extended macromolecular substrate recognition surface involving enzyme and cofactor is utilized to generate substrate specificity between the highly homologous, regulatory proteases of the coagulation cascade.     

Redesigning the PheA domain of gramicidin synthetase leads to a new understanding of the enzyme's mechanism and selectivity

The PheA domain of gramicidin synthetase A, a non-ribosomal peptide synthetase, selectively binds phenylalanine along with ATP and Mg2+ and catalyzes the formation of an aminoacyl adenylate. In this study, we have used a novel protein redesign algorithm, K*, to predict mutations in PheA that should exhibit improved binding for tyrosine. Interestingly, the introduction of two predicted mutations to PheA did not significantly improve KD, as measured by equilibrium fluorescence quenching. However, the mutations improved the specificity of the enzyme for tyrosine (as measured by kcat/KM), primarily driven by a 56-fold improvement in KM, although the improvement did not make tyrosine the preferred substrate over phenylalanine. Using stopped-flow fluorometry, we examined binding of different amino acid substrates to the wild-type and mutant enzymes in the pre-steady state in order to understand the improvement in KM. Through these investigations, it became evident that substrate binding to the wild-type enzyme is more complex than previously described. These experiments show that the wild-type enzyme binds phenylalanine in a kinetically selective manner; no other amino acids tested appeared to bind the enzyme in the early time frame examined (500 ms). Furthermore, experiments with PheA, phenylalanine, and ATP reveal a two-step binding process, suggesting that the PheA-ATP-phenylalanine complex may undergo a conformational change toward a catalytically relevant intermediate on the pathway to adenylation; experiments with PheA, phenylalanine, and other nucleotides exhibit only a one-step binding process. The improvement in KM for the mutant enzyme toward tyrosine, as predicted by K*, may indicate that redesigning the side-chain binding pocket allows the substrate backbone to adopt productive conformations for catalysis but that further improvements may be afforded by modeling an enzyme:ATP:substrate complex, which is capable of undergoing conformational change.     

One functional switch mediates reversible and irreversible inactivation of a herpesvirus protease

Distinct mechanisms have evolved to regulate the function of proteolytic enzymes. Viral proteases in particular have developed novel regulatory mechanisms, presumably due to their comparatively rapid life cycles and responses to constant evolutionary pressure. Herpesviruses are a family of human pathogens that require a viral protease with a concentration-dependent zymogen activation involving folding of two alpha-helices and activation of the catalytic machinery, which results in formation of infectious virions. Kaposi's sarcoma-associated herpesvirus protease (KSHV Pr) is unique among the herpesvirus proteases in possessing an autolysis site in the dimer interface, which removes the carboxyl-terminal 27 amino acids comprising an alpha-helix adjacent to the active site. Truncation results in the irreversible loss of dimerization and concomitant inactivation. We characterized the conformational and functional differences between the active dimer, inactive monomer, and inactive truncated protease to determine the different protease regulatory mechanisms that control the KSHV lytic cycle. Circular dichroism revealed a loss of 31% alpha-helicity upon dimer dissociation. Comparison of the full-length and truncated monomers by NMR showed differences in 21% of the protein structure, mainly located adjacent to the dimer interface, with little perturbation of the overall protein upon truncation. Fluorescence polarization and active site labeling, with a transition state mimetic, characterized the functional effects of these conformational changes. Substrate turnover is abolished in both the full-length and truncated monomers; however, substrate binding remained intact. Disruption of the helix 6 interaction with the active site oxyanion loop is therefore used in two independent regulatory mechanisms of proteolytic activity.     

Structure of the Mature Streptococcal Cysteine Protease Exotoxin mSpeB in Its Active Dimeric Form

Invasive infections of Streptococcus pyogenes are dependent on the cysteine protease streptococcal pyrogenic exotoxin B. Previous structures of the enzyme have not disclosed the proper active-site configuration. Here, the crystal structure of the mature enzyme is presented to 1.55 Å, disclosing a homodimer. A serine from one subunit inserts into the active site of the other to donate to the oxyanion hole and coordinates the ligand proximal to the active-site cysteine. Dimerization is unique to the mature form and is clearly a prerequisite for catalysis. The present structure supports a tripartite switch system that is triggered upon dimerization and substrate binding: (1) liberation of the active-site histidine from an inactive configuration, (2) relocation of residues blocking the substrate binding pockets and (3) repositioning of two active-site tryptophans to settle in the active configuration. Based on the present structure, the active site of clan CA cysteine proteases is expanded and a detailed mechanism of the deacylation mechanism is proposed. The results may have applications for the development of protease inhibitors specific to bacterial cysteine proteases.     

Synthesis of substrates and inhibitors of botulinum neurotoxin type A metalloprotease.

Botulinum neurotoxin (BoNT) metalloproteases and related proteases are the most selective proteases known. X-ray crystal structures suggest that the active sites of the native enzymes exist in catalytically incompetent forms that must be activated by substrate binding. In order to characterize the postulated substrate-induced conformational changes for enzyme activation, we synthesized a series of transition-state analog inhibitors in which the dipeptide cleavage site is replaced by tetrahedral intermediate analogs within the minimal substrate peptide sequence. In this paper, we report our efforts to design inhibitors of BoNT/A metalloprotease. We confirm that an effective substrate sequence for BoNT/A metalloprotease is a 17-mer peptide corresponding to residues 187-203 of SNAP-25. A more stable substrate, Nle202SNAP-25 [187-203] was synthesized in order to develop an assay for proteolytic activity of BoNT/A metalloprotease that can be used to monitor time-dependent inhibition. Alpha-thiol amide analogs of Gln-197 were incorporated via solid-phase peptide synthesis into both 17-mer minimal peptide substrate sequences. The synthesis, characterization and inhibition kinetics for the alpha-thiol amide analogs of holotoxin A substrate are described. These substrate-derived inhibitors were shown to be submicromolar inhibitors of BoNT/A catalytic activity.     

Crystal structures of highly constrained substrate and hydrolysis products bound to HIV-1 protease. Implications for the catalytic mechanism

HIV-1 protease is a key target in treating HIV infection and AIDS, with 10 inhibitors used clinically. Here we used an unusual hexapeptide substrate, containing two macrocyclic tripeptides constrained to mimic a beta strand conformation, linked by a scissile peptide bond, to probe the structural mechanism of proteolysis. The substrate has been cocrystallized with catalytically active synthetic HIV-1 protease and an inactive isosteric (D25N) mutant, and three-dimensional structures were determined (1.60 A). The structure of the inactive HIVPR(D25N)/substrate complex shows an intact substrate molecule in a single orientation that perfectly mimics the binding of conventional peptide ligands of HIVPR. The structure of the active HIVPR/product complex shows two monocyclic hydrolysis products trapped in the active site, revealing two molecules of the N-terminal monocyclic product bound adjacent to one another, one molecule occupying the nonprime site, as expected, and the other monocycle binding in the prime site in the reverse orientation. The results suggest that both hydrolysis products are released from the active site upon cleavage and then rebind to the enzyme. These structures reveal that N-terminal binding of ligands is preferred, that the C-terminal site is more flexible, and that HIVPR can recognize substrate shape rather than just sequence alone. The product complex reveals three carboxylic acids in an almost planar orientation, indicating an unusual hexagonal homodromic complex between three carboxylic acids. The data presented herein regarding orientation of catalytic aspartates support the cleavage mechanism proposed by Northrop. The results imply strategies for design of inhibitors targeting the N-terminal side of the cleavage site or taking advantage of the flexibility in the protease domain that accommodates substrate/inhibitor segments C-terminal to the cleavage site.     

Analysis of an enzyme-substrate complex by X-ray crystallography and transferred nuclear Overhauser enhancement measurements: porcine pancreatic elastase and a hexapeptide

The hexapeptide substrate Thr-Pro-nVal-NMeLeu-Tyr-Thr reacts with porcine pancreatic elastase sufficiently slowly that accelerated crystallographic data collection procedures and two-dimensional transferred nuclear Overhauser enhancement measurements could be used to study the geometry of binding. Both studies report a time-averaged population of the Michaelis complex state, prior to proteolysis. This result provides an important data point along the reaction coordinate pathway for serine proteases. Crystallographic data to 1.80-A resolution were used in the structure analysis with refinement to an R-factor of 0.19.     

Functional determinants of the Epstein-Barr virus protease

Herpesvirus proteases are essential for the production of progeny virus. They cleave the assembly protein that fills the immature capsid in order to make place for the viral DNA. The recombinant protease of the human gamma-herpesvirus Epstein-Barr virus (EBV) was expressed in Escherichia coli and purified. Circular dichroism indicated that the protein was properly folded with a secondary structure content similar to that of other herpesvirus proteases. Gel filtration and sedimentation analysis indicated a fast monomer-dimer equilibrium of the protease with a K(d) of about 60 microM. This value was not influenced by glycerol but was lowered to 1.7 microM in the presence of 0.5 M sodium citrate. We also developed an HPLC-based enzymatic assay using a 20 amino acid residue synthetic peptide substrate derived from one of the viral target sequences for the protease. We found that conditions that stabilised the dimer also led to a higher enzymatic activity. Through sequential deletion of amino acid residues from either side of the cleavage site, the minimal peptide substrate for the protease was determined as P5-P2'. This minimal sequence is shorter than that for other herpesvirus proteases. The implications of our findings are discussed with reference to the viral life-cycle. These results are the first ever published on the EBV protease and represent a first step towards the development of protease inhibitors.     

Herpesvirus protease inhibition by dimer disruption

Kaposi's sarcoma-associated herpesvirus (KSHV), like all herpesviruses, encodes a protease (KSHV Pr), which is necessary for the viral lytic cycle. Herpesvirus proteases function as obligate dimers; however, each monomer has an intact, complete active site which does not interact directly with the other monomer across the dimer interface. Protein grafting of an interfacial KSHV Pr alpha-helix onto a small stable protein, avian pancreatic polypeptide, generated a helical 30-amino-acid peptide designed to disrupt the dimerization of KSHV Pr. The chimeric peptide was optimized through protein modeling of the KSHV Pr-peptide complex. Circular dichroism analysis and gel filtration chromatography revealed that the rationally designed peptide adopts a helical conformation and is capable of disrupting KSHV Pr dimerization, respectively. Additionally, the optimized peptide inhibits KSHV Pr activity by 50% at a approximately 200-fold molar excess of peptide to KSHV Pr, and the dissociation constant was estimated to be 300 microM. Mutagenesis of the interfacial residue M197 to a leucine resulted in an inhibitory concentration which was twofold higher for KSHV Pr M197L than for KSHV Pr, in agreement with the model that the dimer interface is involved in peptide binding. These results indicate that the dimer interface, as well as the active sites, of herpesvirus proteases is a viable target for inhibiting enzyme activity.     

Myristoyl CoA:protein N-myristoyltransferase activities from rat liver and yeast possess overlapping yet distinct peptide substrate specificities

A variety of eukaryotic viral and cellular proteins possesses an NH2-terminal N-myristoylglycine residue important for their biological functions. Recent studies of the primary structural requirements for peptide substrates of the enzyme responsible for this modification in yeast demonstrated that residues 1, 2, and 5 play a critical role in enzyme: ligand interactions (Towler, D. A., Adams, S. P., Eubanks, S. R., Towery, D. S., Jackson-Machelski, E., Glaser, L., and Gordon J. I. (1987b) Proc. Natl. Acad. Sci. U. S. A. 84, 2708-2812). This was determined by examining as substrates a series of synthetic peptides whose sequences were systematically altered from a "parental" peptide derived from the known N-myristoylprotein bovine heart cyclic AMP-dependent protein kinase (A kinase) catalytic subunit. We have now extended these studies in order to examine structure/activity relationships in the COOH-terminal regions of octapeptide substrates of yeast N-myristoyltransferase (NMT). The interaction between yeast NMT and the side chain of residue 5 in peptide ligands is apparently sterically constrained, since Thr5 is unable to promote the very high affinity binding observed with a Ser5 substitution. A substrate hexapeptide core has been defined which contains much of the information necessary for recognition by this lower eukaryotic NMT. Addition of COOH-terminal basic residues to this hexapeptide enhances peptide binding, while COOH-terminal acidic residues destabilize NMT: ligand interactions. Based on the results obtained from our in vitro studies of over 80 synthetic peptides and yeast NMT, we have identified a number of potential N-myristoylproteins from searches of available protein databases. These include hepatitis B virus pre-S1, human SYN-kinase, rodent Gi alpha, and bovine transducin-alpha. Peptides corresponding to the NH2-terminal sequences of these proteins and several known N-myristoylproteins were assayed using yeast NMT as well as partially purified rat liver NMT. While a number of the synthetic peptides exhibited similar catalytic properties with the yeast and mammalian enzymes, surprisingly, the SYN-kinase, Gi alpha, and transducin-alpha peptides were N-myristoylated by rat NMT but not by yeast NMT. This suggests that either multiple NMT activities exist in rat liver or the yeast and rodent enzymes have similar but distinct peptide substrate specificities.     

Active-Site Gating Regulates Substrate Selectivity in a Chymotrypsin-Like Serine Protease: The Structure of Haemophilus influenzae Immunoglobulin A1 Protease

We report here the first structure of a member of the immunoglobulin A protease (IgAP) family at 1.75-Å resolution. This protease is a founding member of the type V (autotransporter) secretion system and is considered a virulence determinant among the bacteria expressing the enzyme. The structure of the enzyme fits that of a classic autotransporter in which several unique domains necessary for protein function are appended to a central, 100-Å-long β-helical domain. The N-terminal domain of the IgAP is found to possess a chymotrypsin-like fold. However, this catalytic domain contains a unique loop D that extends over the active site acting as a lid, gating substrate access. The data presented provide a structural basis for the known ability of IgAPs to cleave only the proline/serine/threonine-rich hinge peptide unique to IgA1 (isotype 1) in the context of the intact fold of the immunoglobulin. Based upon the structural data, as well as molecular modeling, a model suggesting that the unique extended loop D in this IgAP sterically occludes the active-site binding cleft in the absence of immunoglobulin binding is presented. Only in the context of binding of the IgA1-Fc domain in a valley formed between the N-terminal protease domain and another domain appended to the β-helix spine (domain 2) is the lid stabilized in an open conformation. The stabilization of this open conformation through Fc association subsequently allows access of the hinge peptide to the active site, resulting in recognition and cleavage of the substrate.     

Inherent chaperone-like activity of aspartic proteases reveals a distant evolutionary relation to double-psi barrel domains of AAA-ATPases

Chaperones and proteases share the ability to interact with unfolded proteins. Here we show that enzymatically inactive forms of the aspartic proteases HIV-1 protease and pepsin have inherent chaperone-like activity and can prevent the aggregation of denatured substrate proteins. In contrast to proteolysis, which requires dimeric enzymes, chaperone-like activity could be observed also with monomeric domains. The involvement of the active site cleft in the chaperone-like function was demonstrated by the inhibitory effect of peptide substrate inhibitors. The high structural similarity between aspartic proteases and the N-terminal double-psi barrels of Cdc48-like proteins, which are involved in the unfolding and dissociation of proteins, suggests that they share a common ancestor. The latent chaperone-like activity in aspartic proteases can be seen as a relic that has further evolved to serve substrate binding in the context of proteolytic activity.     

Enzymatic activity of the Staphylococcus aureus SplB serine protease is induced by substrates containing the sequence Trp-Glu-Leu-Gln

Proteases are of significant importance for the virulence of Staphylococcus aureus. Nevertheless, their subset, the serine protease-like proteins, remains poorly characterized. Here presented is an investigation of SplB protease catalytic activity revealing that the enzyme possesses exquisite specificity and only cleaves efficiently after the sequence Trp-Glu-Leu-Gln. To understand the molecular basis for such selectivity, we solved the three-dimensional structure of SplB to 1.8 Å. Modeling of substrate binding to the protease demonstrated that selectivity relies in part on a canonical specificity pockets-based mechanism. Significantly, the conformation of residues that ordinarily form the oxyanion hole, an essential structural element of the catalytic machinery of serine proteases, is not canonical in the SplB structure. We postulate that within SplB, the oxyanion hole is only formed upon docking of a substrate containing the consensus sequence motif. It is suggested that this unusual activation mechanism is used in parallel with classical determinants to further limit enzyme specificity. Finally, to guide future development, we attempt to point at likely physiological substrates and thus the role of SplB in staphylococcal physiology.