Crystal structure of the apoptosis-inducing human granzyme A dimer

Granzyme A (GzmA) belongs to a family of trypsin-like serine proteases localized in cytoplasmic granules of activated lymphocytes and natural killer (NK) cells. In contrast to the related granzyme B (GzmB), GzmA forms a stable disulfide-linked homodimer and triggers target-cell death in a caspase-independent way. Limited proteolysis of a high-molecular-mass complex containing SET (also named putative HLA-associated protein II or PHAPII), PHAPI (pp32, leucine-rich acidic nuclear protein) and HMG2 by GzmA liberates NM23-H1, a Mg2+-dependent DNase that causes single-stranded breaks in nuclear DNA. By analyzing the dimeric GzmA structure at a resolution of 2.5 A, we determined the substrate-binding constraints and selective advantages of the two domains arranged as a unique functional tandem. The active sites of the two subunits point in opposite directions and the nearby noncatalytic surfaces can function as exosites, presenting substrates to the active site region of the adjacent partner in a manner analogous to staphylokinase or streptokinase, which present plasminogen to the cofactor-plasmin and cofactor-plasminogen complexes.     

Analysis of protein processing by N-terminal proteomics reveals novel species-specific substrate determinants of granzyme B orthologs

Using a targeted peptide-centric proteomics approach, we performed in vitro protease substrate profiling of the apoptotic serine protease granzyme B resulting in the delineation of more than 800 cleavage sites in 322 human and 282 mouse substrates, encompassing the known substrates Bid, caspase-7, lupus La protein, and fibrillarin. Triple SILAC (stable isotope labeling by amino acids in cell culture) further permitted intra-experimental evaluation of species-specific variations in substrate selection by the mouse or human granzyme B ortholog. For the first time granzyme B substrate specificities were directly mapped on a proteomic scale and revealed unknown cleavage specificities, uncharacterized extended specificity profiles, and macromolecular determinants in substrate selection that were confirmed by molecular modeling. We further tackled a substrate hunt in an in vivo setup of natural killer cell-mediated cell death confirming in vitro characterized granzyme B cleavages next to several other unique and hitherto unreported proteolytic events in target cells.     

Activity of recombinant dengue 2 virus NS3 protease in the presence of a truncated NS2B co-factor, small peptide substrates, and inhibitors

Recombinant forms of the dengue 2 virus NS3 protease linked to a 40-residue co-factor, corresponding to part of NS2B, have been expressed in Escherichia coli and shown to be active against para-nitroanilide substrates comprising the P6-P1 residues of four substrate cleavage sequences. The enzyme is inactive alone or after the addition of a putative 13-residue co-factor peptide but is active when fused to the 40-residue co-factor, by either a cleavable or a noncleavable glycine linker. The NS4B/NS5 cleavage site was processed most readily, with optimal processing conditions being pH 9, I = 10 mm, 1 mm CHAPS, 20% glycerol. A longer 10-residue peptide corresponding to the NS2B/NS3 cleavage site (P6-P4') was a poorer substrate than the hexapeptide (P6-P1) para-nitroanilide substrate under these conditions, suggesting that the prime side substrate residues did not contribute significantly to protease binding. We also report the first inhibitors of a co-factor-complexed, catalytically active flavivirus NS3 protease. Aprotinin was the only standard serine protease inhibitor to be active, whereas a number of peptide substrate analogues were found to be competitive inhibitors at micromolar concentrations.     

Nucleotides -1 to -4 of hepatitis delta ribozyme substrate increase the specificity of ribozyme cleavage

In the past, the use of delta ribozyme as a therapeutic tool was limited because substrate specificity was thought to be determined by only 8 nucleotides. Recently, we have accumulated evidence suggesting that the substrate sequence upstream of the cleavage site, which is not involved in the binding with the delta ribozyme, appears to be essential in the selection of an appropriate cleavage site. To understand the role of this region in efficient cleavage, we synthesized a collection of small substrates that possessed single and multiple mutations in positions -1 to -4 and determined the kinetic parameters of their cleavage using a model antigenomic delta ribozyme. Some substrates were found to be uncleavage, whereas others showed >60-fold difference in relative specificity between the least and most efficiently cleaved substrates. The base at each position from -1 to -4 contributes differently to the ability of a substrate to be cleaved. An optimal sequence for positions -1 to -4 was determined to be -1HRHY(-4) (H = U, C, or A). These results shed light on new features that contribute to the substrate requirement of delta ribozyme cleavage and should increase interest in the use of this unique ribozyme.     

A New Class of Rhomboid Protease Inhibitors Discovered by Activity-Based Fluorescence Polarization

Rhomboids are intramembrane serine proteases that play diverse biological roles, including some that are of potential therapeutical relevance. Up to date, rhomboid inhibitor assays are based on protein substrate cleavage. Although rhomboids have an overlapping substrate specificity, substrates cannot be used universally. To overcome the need for substrates, we developed a screening assay using fluorescence polarization activity-based protein profiling (FluoPol ABPP) that is compatible with membrane proteases. With FluoPol ABPP, we identified new inhibitors for the E. coli rhomboid GlpG. Among these was a structural class that has not yet been reported as rhomboid inhibitors: β-lactones. They form covalent and irreversible complexes with the active site serine of GlpG. The presence of alkyne handles on the β-lactones also allowed activity-based labeling. Overall, these molecules represent a new scaffold for future inhibitor and activity-based probe development, whereas the assay will allow inhibitor screening of ill-characterized membrane proteases.     

Extended interactions with prothrombinase enforce affinity and specificity for its macromolecular substrate

The specific action of serine proteinases on protein substrates is a hallmark of blood coagulation and numerous other physiological processes. Enzymic recognition of substrate sequences preceding the scissile bond is considered to contribute dominantly to specificity and function. We have investigated the contribution of active site docking by unique substrate residues preceding the scissile bond to the function of prothrombinase. Mutagenesis of the authentic P(1)-P(3) sequence in prethrombin 2/fragment 1.2 yielded substrate variants that could be converted to thrombin by prothrombinase. Proteolytic activation was also observed with a substrate variant containing the P(1)-P(3) sequence found in a coagulation zymogen not known to be activated by prothrombinase. Lower rates of activation of the variants derived from a decrease in maximum catalytic rate but not in substrate affinity. Replacement of the P(1) residue with Gln yielded an uncleavable derivative that retained the affinity of the wild type substrate for prothrombinase but did not engage the active site of the enzyme. Thus, active site docking of the substrate contributes to catalytic efficiency, but it is does not determine substrate affinity nor does it fully explain the specificity of prothrombinase. Therefore, extended interactions between prothrombinase and substrate regions removed from the cleavage site drive substrate affinity and enforce the substrate specificity of this enzyme complex.     

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.     

Catalytic domain structures of MT-SP1/matriptase, a matrix-degrading transmembrane serine proteinase.

The type II transmembrane multidomain serine proteinase MT-SP1/matriptase is highly expressed in many human cancer-derived cell lines and has been implicated in extracellular matrix re-modeling, tumor growth, and metastasis. We have expressed the catalytic domain of MT-SP1 and solved the crystal structures of complexes with benzamidine at 1.3 A and bovine pancreatic trypsin inhibitor at 2.9 A. MT-SP1 exhibits a trypsin-like serine proteinase fold, featuring a unique nine-residue 60-insertion loop that influences interactions with protein substrates. The structure discloses a trypsin-like S1 pocket, a small hydrophobic S2 subsite, and an open negatively charged S4 cavity that favors the binding of basic P3/P4 residues. A complementary charge pattern on the surface opposite the active site cleft suggests a distinct docking of the preceding low density lipoprotein receptor class A domain. The benzamidine crystals possess a freely accessible active site and are hence well suited for soaking small molecules, facilitating the improvement of inhibitors. The crystal structure of the MT-SP1 complex with bovine pancreatic trypsin inhibitor serves as a model for hepatocyte growth factor activator inhibitor 1, the physiological inhibitor of MT-SP1, and suggests determinants for the substrate specificity.     

A comparison of staphostatin B with standard mechanism serine protease inhibitors

Staphostatins are the endogenous, highly specific inhibitors of staphopains, the major secreted cysteine proteases from Staphylococcus aureus. We have previously shown that staphostatins A and B are competitive, active site-directed inhibitors that span the active site clefts of their target proteases in the same orientation as substrates. We now report the crystal structure of staphostatin B in complex with wild-type staphopain B at 1.9 A resolution. In the complex structure, the catalytic residues are found in exactly the positions that would be expected for uncomplexed papain-type proteases. There is robust, continuous density for the staphostatin B binding loop and no indication for cleavage of the peptide bond that comes closest to the active site cysteine of staphopain B. The carbonyl carbon atom C of this peptide bond is 4.1 A away from the active site cysteine sulfur Sgamma atom. The carbonyl oxygen atom O of this peptide bond points away from the putative oxyanion hole and lies almost on a line from the Sgamma atom to the C atom. The arrangement is strikingly similar to the "ionmolecule" arrangement for the complex of papain-type enzymes with their substrates but differs significantly from the arrangement conventionally assumed for the Michaelis complex of papain-type enzymes with their substrates and also from the arrangement that is crystallographically observed for complexes of standard mechanism inhibitors and their target serine proteases.     

LDH and structural analogues of pyruvate (author's transl)]

Pyruvate related compounds have been tested for their active or inhibitory properties on LDH. Special structure features were needed for compounds to be bound to the enzyme active site. Pyruvate and the LDH molecule were bound by the interaction of the carboxyl group or its ester derivative, with the enzyme. Ethyl pyruvate seemed to behave as a substrate of the enzyme whereas acetophenone, ethyl acetoacetate and beta-oxoglutarate did not act as substrates or inhibitors of LDH. Phenyl pyruvate, alpha-oxoglutarate and L-mandelate are not substrates but inhibitors of the LDH. It seems that a structure having a carbonyl group in the alpha-position to the carboxyl is required for the binding of a compound to the LDH molecule. Glyoxylate alpha-oxobutyrate and alpha-oxovalerianate appear to be worse LDH substrates than pyruvate itself. This seems to suggest that the shortening or the extension of the pyruvate aliphatic chain induces a decrease of the affinity of the enzyme towards their substrate homologues.     

The crystal structure of a bacterial, bifunctional 5,10 methylene-tetrahydrofolate dehydrogenase/cyclohydrolase.

The structure of a bifunctional 5,10-methylene-tetrahydrofolate dehydrogenase/cyclohydrolase from Escherichia coli has been determined at 2.5 A resolution in the absence of bound substrates and compared to the NADP-bound structure of the homologous enzyme domains from a trifunctional human synthetase enzyme. Superposition of these structures allows the identification of a highly conserved cluster of basic residues that are appropriately positioned to serve as a binding site for the poly-gamma-glutamyl tail of the tetrahydrofolate substrate. Modeling studies and molecular dynamic simulations of bound methylene-tetrahydrofolate and NADP shows that this binding site would allow interaction of the nicotinamide and pterin rings in the dehydrogenase active site. Comparison of these enzymes also indicates differences between their active sites that might allow the development of inhibitors specific to the bacterial target.     

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.     

Conformational restrictions in the active site of unliganded human caspase-3

Caspases are cysteine proteases that play a critical role in the initiation and regulation of apoptosis. These enzymes act in a cascade to promote cell death through proteolytic cleavage of intracellular proteins. Since activation of apoptosis is implicated in human diseases such as cancer and neurodegenerative disorders, caspases are targets for drugs designed to modulate their action. Active caspases are heterodimeric enzymes with two symmetrically arranged active sites at opposite ends of the molecule. A number of crystal structures of caspases with peptides or proteins bound at the active sites have defined the mechanism of action of these enzymes, but molecular information about the active sites before substrate engagement has been lacking. As part of a study of peptidyl inhibitors of caspase-3, we crystallized a complex where the inhibitor did not bind in the active site. Here we present the crystal structure of the unoccupied substrate-binding site of caspase-3. No large conformational differences were apparent when this site was compared with that in enzyme-inhibitor complexes. Instead, the 1.9 A structure reveals critical side chain movements in a hydrophobic pocket in the active site. Notably, the side chain of tyrosine204 is rotated by approximately 90 degrees so that the phenol group occupies the S2 subsite in the active site. Thus, binding of substrate or inhibitors is impeded unless rotation of this side chain opens the area. The positions of these side chains may have important implications for the directed design of inhibitors of caspase-3 or caspase-7.     

The region of the thrombin receptor resembling hirudin binds to thrombin and alters enzyme specificity.

A thrombin receptor has recently been cloned and the sequence deduced. The sequence reveals a thrombin cleavage site that accounts for receptor activation. The receptor also has an acidic region with some similarities to the carboxyl-terminal region of the leech thrombin inhibitor, hirudin. Synthetic peptides corresponding to the receptor cleavage site (residues 38-45), the hirudin-like domain (residues 52-69), and the covalently associated domains (residues 38-64) were evaluated for their ability to bind to thrombin. Peptides 38-45 and 38-64 were competitive inhibitors of thrombin's chromogenic substrate activity (Ki = 0.96 mM and 0.6 microM, respectively. Residues 52-69 altered the chromogenic substrate specificity, resulting in accelerated cleavage of some substrates and inhibited cleavage of others. The same peptide binds to thrombin and alters the fluorescence emission intensity of 5-dimethylaminonaphthalene-1-sulfonyl (dansyl)-thrombin in which the dansyl is attached directly to the active site serine (Kd = 32 +/- 7 microM). Residues 52-69 displace the carboxyl-terminal peptide of hirudin, indicating that they share a common binding site in the anion exosite of thrombin. These data suggest that the thrombin receptor has high affinity for thrombin due to the presence of the hirudin-like domain and that this domain alters the specificity of thrombin. This change in specificity may account for the ability of the receptor to serve as an excellent thrombin substrate despite the presence of an Asp residue in the P3 site, which is normally inhibitory to thrombin activity.     

Structural organization in the serine proteases. I. Macromolecular specificity in limited proteolysis

We have been developing computational approaches to increase our ability to analyze the growing body of three-dimensional structural data with applications centered about the serine proteases. The emphasis of these approaches is to compare and contrast macromolecules at the separate levels of secondary, tertiary, and quaternary structure. Our assumption is that in functionally related molecules, regions of structural and/or physicochemical similarity will exhibit functional similarity; regions that are different in structure and/or physicochemical properties will function differently and, therefore, be the source of specificity. Based on this assumption, the independent observations from studies of these enzymes in solution and in biological systems are combined with the structural observations from X-ray crystallographic analysis. A goal of the present research effort is to probe the biomolecular architecture of the serine proteases to evaluate the role of the three-dimensional structure beyond that of the active site in determining recognition and reactivity determinants for these enzymes, and to determine those principles that might be applied successfully to other enzyme systems as well. Of particular note has been our observation of a macromolecular recognition surface which occurs as a topographical feature outside of the active site and under evolutionary control to produce specificity towards macromolecular substrates and inhibitors. In addition we have established the important role of conformational changes that occur beyond the active site of an enzyme and differentiate between natural and synthetic inhibitor-enzyme interactions. This suggests that the specificity and reactivity determinants of a macromolecule are derived from its architecture and structural organization.     

Sequence and Conformational Specificity in Substrate Recognition: SEVERAL HUMAN KUNITZ PROTEASE INHIBITOR DOMAINS ARE SPECIFIC SUBSTRATES OF MESOTRYPSIN*

Mesotrypsin is an isoform of trypsin that is uniquely resistant to polypeptide trypsin inhibitors and can cleave some inhibitors rapidly. Previous studies have shown that the amyloid precursor protein Kunitz protease inhibitor domain (APPI) is a specific substrate of mesotrypsin and that stabilization of the APPI cleavage site in a canonical conformation contributes to recognition by mesotrypsin. We hypothesized that other proteins possessing potential cleavage sites stabilized in a similar conformation might also be mesotrypsin substrates. Here we evaluated a series of candidate substrates, including human Kunitz protease inhibitor domains from amyloid precursor-like protein 2 (APLP2), bikunin, hepatocyte growth factor activator inhibitor type 2 (HAI2), tissue factor pathway inhibitor-1 (TFPI1), and tissue factor pathway inhibitor-2 (TFPI2), as well as E-selectin, an unrelated protein possessing a potential cleavage site displaying canonical conformation. We find that Kunitz domains within APLP2, bikunin, and HAI2 are cleaved by mesotrypsin with kinetic profiles of specific substrates. TFPI1 and TFPI2 Kunitz domains are cleaved less efficiently by mesotrypsin, and E-selectin is not cleaved at the anticipated site. Cocrystal structures of mesotrypsin with HAI2 and bikunin Kunitz domains reveal the mode of mesotrypsin interaction with its canonical substrates. Our data suggest that major determinants of mesotrypsin substrate specificity include sequence preferences at the P₁ and P′₂ positions along with conformational stabilization of the cleavage site in the canonical conformation. Mesotrypsin up-regulation has been implicated previously in cancer progression, and proteolytic clearance of Kunitz protease inhibitors offers potential mechanisms by which mesotrypsin may mediate pathological effects in cancer.     

Crystal structure at 1.63 A resolution of the native form of porcine beta-trypsin: revealing an acetate ion binding site and functional water network

The active center of a serine protease is the catalytic triad composed of His-57, Ser-195 and Asp-102. The existing crystal structure data on serine proteases have not fully answered a number of fundamental questions relating to the catalytic activity of serine proteases. The new high resolution native porcine beta-trypsin (BPT) structure is aimed at extending the knowledge on the conformation of the active site and the ordered water structure within and around the active site. The crystal structure of BPT has been determined at 1.63 A resolution. An acetate ion bound at the active site of a trypsin molecule by both classical hydrogen bonds and C-HellipsisO hydrogen bonds has been identified for the first time. A large network of water molecules extending from the recognition amino acid Asp-184 to the entry of the active site has been observed in the BPT structure. A detailed comparison with inhibitor complexes and autolysates indicates that the sulfate ion and the acetate ion bind at the same site of the trypsin molecule. The Ser-195 Cbeta-Ogamma-His-57 Nepsilon angle in the catalytic triad of BPT is intermediate between the corresponding values of the complex and native structure due to acetate ion binding. The network of waters from the recognition amino acid to the active site entry is probably the first ever complete picture of functional waters around the active site. Structural comparisons show that the functional waters involved in the binding of small molecule inhibitors and protease inhibitors are distinctly different.     

L-aspartase from Escherichia coli: substrate specificity and role of divalent metal ions

The enzyme L-aspartase from Escherichia coli has an absolute specificity for its amino acid substrate. An examination of a wide range of structural analogues of L-aspartic acid did not uncover any alternate substrates for this enzyme. A large number of competitive inhibitors of the enzyme have been characterized, with inhibition constants ranging over 2 orders of magnitude. A divalent metal ion is required for enzyme activity above pH 7, and this requirement is met by many transition and alkali earth metals. The binding stoichiometry has been established to be one metal ion bound per subunit. Paramagnetic relaxation studies have shown that the divalent metal ion binds at the recently discovered activator site on L-aspartase and not at the enzyme active site. Enzyme activators are bound within 5 A of the enzyme-bound divalent metal ion. The activator site is remote from the active site of the enzyme, since the relaxation of inhibitors that bind at the active site is not affected by paramagnetic metal ions bound at the activator site.     

Crystallographic mapping of beta-lactams bound to a D-alanyl-D-alanine peptidase target enzyme

X-ray crystallography has been used to examine the binding of three members of the beta-lactam family of antibiotics to the D-alanyl-D-alanine peptidase from Streptomyces R61, a target of penicillins. Cephalosporin C, the monobactam analog of penicillin G and (2,3)-alpha-methylene benzylpenicillin have been mapped at 2.3 A resolution in the form of acyl-enzyme complexes bound to serine 62. On the basis of the positions of these inhibitors, the binding of a tripeptide substrate for the enzyme, L-lysyl-D-alanyl-D-alanine, has been modeled in the active site. The binding of both inhibitors and substrate is facilitated by hydrogen-bonding interactions with a conserved beta-strand (297-303), which is antiparallel to the beta-lactam's acylamide linkage or the substrate's peptide bond. The active site is similar to that in beta-lactamases.     

Acarbose rearrangement mechanism implied by the kinetic and structural analysis of human pancreatic alpha-amylase in complex with analogues and their elongated counterparts

A mechanistic study of the poorly understood pathway by which the inhibitor acarbose is enzymatically rearranged by human pancreatic alpha-amylase has been conducted by structurally examining the binding modes of the related inhibitors isoacarbose and acarviosine-glucose, and by novel kinetic measurements of all three inhibitors under conditions that demonstrate this rearrangement process. Unlike acarbose, isoacarbose has a unique terminal alpha-(1-6) linkage to glucose and is found to be resistant to enzymatic rearrangement. This terminal glucose unit is found to bind in the +3 subsite and for the first time reveals the interactions that occur in this part of the active site cleft with certainty. These results also suggest that the +3 binding subsite may be sufficiently flexible to bind the alpha-(1-6) branch points in polysaccharide substrates, and therefore may play a role in allowing efficient cleavage in the direct vicinity of such junctures. Also found to be resistant to enzymatic rearrangement was acarviosine-glucose, which has one fewer glucose unit than acarbose. Collectively, structural studies of all three inhibitors and the specific cleavage pattern of HPA make it possible to outline the simplest sequence of enzymatic reactions likely involved upon acarbose binding. Prominent features incorporated into the starting structure of acarbose to facilitate the synthesis of the final tightly bound pseudo-pentasaccharide product are the restricted availability of hydrolyzable bonds and the placement of the transition state-like acarviosine group. Additional "in situ" experiments designed to elongate and thereby optimize isoacarbose and acarviosine-glucose inhibition using the activated substrate alphaG3F demonstrate the feasibility of this approach and that the principles outlined for acarbose rearrangement can be used to predict the final products that were obtained.