New, sensitive fluorogenic substrates for human cathepsin G based on the sequence of serpin-reactive site loops.

Cathepsin G has both trypsin- and chymotrypsin-like activity, but studies on its enzymatic properties have been limited by a lack of sensitive synthetic substrates. Cathepsin G activity is physiologically controlled by the fast acting serpin inhibitors alpha1-antichymotrypsin and alpha1-proteinase inhibitor, in which the reactive site loops are cleaved during interaction with their target enzymes. We therefore synthesized a series of intramolecularly quenched fluorogenic peptides based on the sequence of various serpin loops. Those peptides were assayed as substrates for cathepsin G and other chymotrypsin-like enzymes including chymotrypsin and chymase. Peptide substrates derived from the alpha1-antichymotrypsin loop were the most sensitive for cathepsin G with kcat/Km values of 5-20 mM-1 s-1. Substitutions were introduced at positions P1 and P2 in alpha1-antichymotrypsin-derived substrates to tentatively improve their sensitivity. Replacement of Leu-Leu in ortho-aminobenzoyl (Abz)-Thr-Leu-Leu-Ser-Ala-Leu-Gln-N-(2, 4-dinitrophenyl)ethylenediamine (EDDnp) by Pro-Phe in Abz-Thr-Pro-Phe-Ser-Ala-Leu-Gln-EDDnp produced the most sensitive substrate of cathepsin G ever reported. It was cleaved with a specificity constant kcat/Km of 150 mM-1 s-1. Analysis by molecular modeling of a peptide substrate bound into the cathepsin G active site revealed that, in addition to the protease S1 subsite, subsites S1' and S2' significantly contribute to the definition of the substrate specificity of cathepsin G.     

Guinea pig chymase is leucine-specific: a novel example of functional plasticity in the chymase/granzyme family of serine peptidases

To explore guinea pigs as models of chymase biology, we cloned and expressed the guinea pig ortholog of human chymase. In contrast to rats and mice, guinea pigs appear to express just one chymase, which belongs to the alpha clade, like primate chymases and mouse mast cell protease-5. The guinea pig enzyme autolyzes at Leu residues in the loop where human chymase autolyzes at Phe. In addition, guinea pig alpha-chymase selects P1 Leu in a combinatorial peptide library and cleaves Ala-Ala-Pro-Leu-4-nitroanilide but has negligible activity toward substrates with P1 Phe and does not cleave angiotensin I. This contrasts with human chymase, which cleaves after Phe or Tyr, prefers P1 Phe in peptidyl 4-nitroanilides, and avidly hydrolyzes angiotensin I at Phe8 to generate bioactive angiotensin II. The guinea pig enzyme also is inactivated more effectively by alpha1-antichymotrypsin, which features P1 Leu in the reactive loop. Unlike mouse, rat, and hamster alpha-chymases, guinea pig chymase lacks elastase-like preference for P1 Val or Ala. Partially humanized A216G guinea pig chymase acquires human-like P1 Phe- and angiotensin-cleaving capacity. Molecular models suggest that the wild type active site is crowded by the Ala216 side chain, which potentially blocks access by bulky P1 aromatic residues. On the other hand, the guinea pig pocket is deeper than in Val-selective chymases, explaining the preference for the longer aliphatic side chain of Leu. These findings are evidence that chymase-like peptidase specificity is sensitive to small changes in structure and provide the first example of a vertebrate Leu-selective peptidase.     

Inhibition of human chymase by 2-amino-3,1-benzoxazin-4-ones

A series of 2-sec.amino-4H-3,1-benzoxazin-4-ones was evaluated as acyl-enzyme inhibitors of human recombinant chymase. The compounds were also assayed for inhibition of human cathepsin G, bovine chymotrypsin, and human leukocyte elastase. Introduction of an aromatic moiety into the 2-substituent resulted in strong inhibition of chymase, cathepsin G, and chymotrypsin. Extension of the N(Me)CH2Ph substituent by one methylene unit was unfavourable to inhibit these proteases. Towards chymase, 2-(N-benzyl-N-methylamino)-4H-3,1-benzoxazin-4-one (32) and 2-(N-benzyl-N-methylamino)-6-methyl-4H-3,1-benzoxazin-4-one (33) were found to exhibit Ki values of 11 and 17 nM, respectively, and form stable acyl-enzymes with half-lives of 53 and 25 min, respectively. Benzoxazinone 33 also inhibited the human chymase-catalyzed formation of angiotensin 11 from angiotensin I.     

Multiple determinants for the high substrate specificity of an angiotensin II-forming chymase from the human heart

Human heart chymase, a chymotrypsin-like serine proteinase that hydrolyzes the Phe8-His9 bond in angiotensin I (Ang I) to yield the octapeptide hormone angiotensin II (Ang II) and His-Leu, is the most specific, efficient Ang II-forming enzyme described. Other mammalian chymases display a much broader substrate specificity. To better define its substrate specificity, we have mapped the extended substrate-binding site of human heart chymase using Ang I analogs. The enzyme has a preference for aromatic amino acids phenylalanine, tyrosine, and tryptophan at the P1 site. At the S2 subsite there is a significant preference for proline over hydrophobic or hydrophilic amino acids. There is no clear preference for hydrophobic or hydrophilic amino acids at the S'1 and S'2 subsites, but an Ang I analog containing a P'1 proline is not hydrolyzed and one with a P'2 proline is hydrolyzed poorly. An increasing reduction in reactivity occurs when the P position amino acids in Ang I are deleted sequentially from the N terminus. An increase or decrease in the length of the His-Leu leaving group also produces a marked decrease in reactivity. No single determinant in Ang I is preeminently required for efficient catalysis, but several factors acting synergistically appear to be important. Thus, we propose that ideal substrates for human heart chymase should contain the structure nXaa-Pro-[Phe, Tyr, or Trp]-Yaa-Yaa, where n greater than or equal to 6; Xaa = any amino acid; Yaa = any amino acid except proline. This structure exists in Ang I and neurotensin, both of which are good substrates for human heart chymase. These findings indicate that the selection of the scissile bond by the extended substrate-binding site of human heart chymase is more restricted than that in other chymases.     

Cleaved SLPI, a novel biomarker of chymase activity

Secretory leukocyte protease inhibitor (SLPI) is a protease inhibitor of the whey acidic protein-like family inhibiting chymase, chymotrypsin, elastase, proteinase 3, cathepsin G and tryptase. Performing in vitro enzymatic assays using both Western blotting and liquid chromatography/mass spectrometry techniques we showed that, of the proteases known to interact with SLPI, only chymase could uniquely cleave this protein. The peptides of the cleaved SLPI (cSLPI) remain coupled due to the disulfide bonds in the molecule but under reducing conditions the cleavage can be observed as peptide products. Subsequent ex vivo studies confirmed the presence of SLPI in human saliva and its susceptibility to cleavage by chymase. Furthermore, inhibitors of chymase activity are able to inhibit this cleavage. Human saliva from both normal and allergic individuals was analyzed for levels of cSLPI and a correlation between the level of cSLPI and the extent of allergic symptoms was observed, suggesting the application of cSLPI as a biomarker of chymase activity in humans.     

Crystal and molecular structure of the bovine alpha-chymotrypsin-eglin c complex at 2.0 A resolution.

The crystal structure of the complex between bovine alpha-chymotrypsin and the leech (Hirudo medicinalis) protein proteinase inhibitor eglin c has been refined at 2.0 A resolution to a crystallographic R-factor of 0.167. The structure of the complex includes 2290 protein and 143 solvent atoms. Eglin c is bound to the cognate enzyme through interactions involving 11 residues of the inhibitor (sites P5-P4' in the reactive site loop, P10' and P23') and 17 residues from chymotrypsin. Binding of eglin c to the enzyme causes a contained hinge-bending movement around residues P4 and P4' of the inhibitor. The tertiary structure of chymotrypsin is little affected, with the exception of the 10-13 region, where an ordered structure for the polypeptide chain is observed. The overall binding mode is consistent with those found in other serine proteinase-protein-inhibitor complexes, including those from different inhibition families. Contained, but significant differences are observed in the establishment of intramolecular hydrogen bonds and polar interactions stabilizing the structure of the intact inhibitor, if the structure of eglin c in its complex with chymotrypsin is compared with that of other eglin c-serine proteinase complexes.     

Interdependency of sequence and positional specificities for cysteine proteases of the papain family

The specificity of cysteine proteases is characterized by the nature of the amino acid sequence recognized by the enzymes (sequence specificity) as well as by the position of the scissile peptide bond (positional specificity, i.e., endopeptidase, aminopeptidase, or carboxypeptidase). In this paper, the interdependency of sequence and positional specificities for selected members of this class of enzymes has been investigated using fluorogenic substrates where both the position of the cleavable peptide bond and the nature of the sequence of residues in P2-P1 are varied. The results show that cathepsins K and L and papain, typically considered to act strictly as endopeptidases, can also display dipeptidyl carboxypeptidase activity against the substrate Abz-FRF(4NO2)A and dipeptidyl aminopeptidase activity against FR-MCA. In some cases the activity is even equal to or greater than that observed with cathepsin B and DPP-I (dipeptidyl peptidase I), which have been characterized previously as exopeptidases. In contrast, the exopeptidase activities of cathepsins K and L and papain are extremely low when the P2-P1 residues are A-A, indicating that, as observed for the normal endopeptidase activity, the exopeptidase activities rely heavily on interactions in subsite S2 (and possibly S1). However, cathepsin B and DPP-I are able to hydrolyze substrates through the exopeptidase route even in absence of preferred interactions in subsites S2 and S1. This is attributed to the presence in cathepsin B and DPP-I of specific structural elements which serve as an anchor for the C- or N-terminus of a substrate, thereby allowing favorable enzyme-substrate interaction independently of the P2-P1 sequence. As a consequence, the nature of the residue at position P2 of a substrate, which is usually the main factor determining the specificity for cysteine proteases of the papain family, does not have the same contribution for the exopeptidase activities of cathepsin B and DPP-I.     

Inactivation of chymotrypsin and human skin chymase: kinetics of time-dependent inhibition in the presence of substrate

The reaction of chymase, a chymotryptic proteinase from human skin, and bovine pancreatic chymotrypsin with a number of time-dependent inhibitors has been studied. An integrated equation, relating product formation with time, has been derived for the reaction of enzymes with time-dependent inhibitors in the presence of substrate. This is based on a two-step model in which a rapidly reversible, non-covalent complex (EI) is formed prior to a tighter, less readily reversible complex (EI)*). The equation depends on the simplifying assumption [I] much greater than [E], but is applicable to reversible and irreversible slow-binding and tight-binding inhibitors whether or not they show saturation kinetics. The method has been applied to the reaction of chymase and chymotrypsin with the tetrapeptide aldehyde, chymostatin, basic pancreatic trypsin inhibitor and Ala-Ala-Phe-chloromethylketone (AAPCK). The irreversible inhibitor, AAPCK, showed the expected saturation kinetics for both enzymes and the apparent first-order rate constants (k2) and dissociation constants (Ki) for the non-covalent complexes were determined. Chymostatin was a much more potent inhibitor which failed to show a saturation effect. The second-order rate constant of inactivation (k2/Ki), the first-order reactivation rate constant (k-2), and the dissociation constant of the covalent complex (Ki*) were determined. Basic pancreatic trypsin inhibitor, a potent inhibitor of chymotrypsin, had similar kinetics to chymostatin but failed to inhibit chymase. The applicability of the two-step model and the integrated equation to slow- and tight-binding inhibitors is discussed in relation to a number of examples from the literature.     

Protease La, the lon gene product, cleaves specific fluorogenic peptides in an ATP-dependent reaction

Protease La is an ATP-dependent protease that catalyzes the rapid degradation of abnormal proteins and certain normal polypeptides in Escherichia coli. In order to learn more about its specificity and the role of ATP, we tested whether small fluorogenic peptides might serve as substrates. In the presence of ATP and Mg2+, protease La hydrolyzes two oligopeptides that are also substrates for chymotrypsin, glutaryl-Ala-Ala-Phe-methoxynaphthylamine (MNA) and succinyl-Phe-Leu-Phe-MNA. Methylation or removal of the acidic blocking group prevented hydrolysis. Closely related peptides (glutaryl-Gly-Gly-Phe-MNA and glutaryl-Ala-Ala-Ala-MNA) are cleaved only slightly, and substrates of trypsin-like proteases are not hydrolyzed. Furthermore, several peptide chloromethyl ketone derivatives that inhibit chymotrypsin and cathepsin G (especially benzyloxycarbonyl-Gly-Leu-Phe-chloro-methyl ketone), inhibited protease La. Thus its active site prefers peptides containing large hydrophobic residues, and amino acids beyond the cleavage site influence rates of hydrolysis. Peptide hydrolysis resembles protein breakdown by protease La in many respects: 1) ADP inhibits this process rapidly, 2) DNA stimulates it, 3) heparin, diisopropyl fluorophosphate, and benzoyl-Arg-Gly-Phe-Phe-Leu-MNA inhibit hydrolysis, 4) the reaction is maximal at pH 9.0-9.5, 5) the protein purified from lon- E. coli or Salmonella typhymurium showed no activity against the peptide, and that from lonR9 inhibited peptide hydrolysis by the wild-type enzyme. With partially purified enzyme, peptide hydrolysis was completely dependent on ATP. The pure protease hydrolyzed the peptide slowly when only Mg2+, Ca2+, or Mn2+ were present, and ATP enhanced this activity 6-15-fold (Km = 3 microM). Since these peptides cannot undergo phosphorylation, adenylylation, modification of amino groups, or denaturation, these mechanisms cannot account for the stimulation by ATP. Most likely, ATP and Mg2+ affect the conformation of the enzyme, rather than that of the substrate.     

Substrate recognition drives the evolution of serine proteases

A method is introduced to identify amino acid residues that dictate the functional diversity acquired during evolution in a protein family. Using over 80 enzymes of the chymotrypsin family, we demonstrate that the general organization of the phylogenetic tree and its functional branch points are fully accounted for by a limited number of residues that cluster around the active site of the protein and define the contact region with the P1-P4 residues of substrate.     

Renin cleavage of a human kidney renin substrate analogous to human angiotensinogen, H-Asp-Arg-Val-Tyr-Ile-His-Pro-Phe-His-Leu-Val-Ile-His-Ser-OH, that is human renin specific and is resistant to cathepsin D

A synthetic tetradecapeptide, H-Asp-Arg-Val-Tyr-Ile-His-Pro-Phe-His-Leu-Val-Ile-His-Ser-OH, which corresponds to the 13 amino terminal residues of human angiotensinogen plus a carboxy terminal serine to replace a suggested site of carbohydrate attachment, has been shown to be a good substrate for human kidney renin. At pH 7.2 and 37 degrees C the KM or Michaelis constant was 8.4 +/- 2.9 microM, and the VM or velocity at infinite tetradecapeptide concentration was 11.3 +/- 2.4 mumol angiotensin I made per hour per milligram renin. The tetradecapeptide was highly resistant to cleavage by mouse submaxillary renin. The tetradecapeptide was also slowly cleaved by human liver cathepsin D, by rabbit lung angiotensin-converting enzyme, and by reconstituted human serum, but did not yield angiotensin I. Thus, this synthetic renin substrate should permit more specific measurement of human kidney renin activity.     

Serpins of oat (Avena sativa) grain with distinct reactive centres and inhibitory specificity

Most proteinase inhibitors from plant seeds are assumed to contribute to broad-spectrum protection against pests and pathogens. In oat (Avena sativa L.) grain the main serine proteinase inhibitors were found to be serpins, which utilize a unique mechanism of irreversible inhibition. Four distinct inhibitors of the serpin superfamily were detected by native PAGE as major seed albumins and purified by thiophilic adsorption and anion exchange chromatography. The four serpins OSZa-d are the first proteinase inhibitors characterized from this cereal. An amino acid sequence close to the blocked N-terminus, a reactive centre loop sequence, and the second order association rate constant (ka') for irreversible complex formation with pancreas serine proteinases at 24 degrees C were determined for each inhibitor. OSZa and OSZb, both with the reactive centre scissile bond P1-P1' Thr downward arrow Ser, were efficient inhibitors of pancreas elastase (ka' > 105M-1 s-1). Only OSZb was also an inhibitor of chymotrypsin at the same site (ka' = 0.9 x 105M-1 s-1). OSZc was a fast inhibitor of trypsin at P1-P1' Arg downward arrow Ser (ka' = 4 x 106M-1 s-1); however, the OSZc-trypsin complex was short-lived with a first order dissociation rate constant kd = 1.4 x 10-4 s-1. OSZc was also an inhibitor of chymotrypsin (ka' > 106M-1 s-1), presumably at the overlapping site P2-P1 Ala downward arrow Arg, but > 90% of the serpin was cleaved as substrate. OSZd was cleaved by chymotrypsin at the putative reactive centre bond P1-P1' Tyr downward arrow Ser, and no inhibition was detected. Together the oat grain serpins have a broader inhibitory specificity against digestive serine proteinases than represented by the major serpins of wheat, rye or barley grain. Presumably the serpins compensate for the low content of reversible inhibitors of serine proteinases in oats in protection of the grain against pests or pathogens.     

Inhibitory plant serpins with a sequence of three glutamine residues in the reactive center

Serpins appear to be ubiquitous in eukaryotes, except fungi, and are also present in some bacteria, archaea and viruses. Inhibitory serpins with a glutamine as the reactive-center P1 residue have been identified exclusively in a few plant species. Unique serpins with a reactive center sequence of three Gln residues at P3-P1 or P2-P1' were isolated from barley and wheat grain, respectively. Barley BSZ3 was an irreversible inhibitor of chymotrypsin, with a second-order association rate constant for complex formation k(a)' of the order of 10(4) M(-1) s(-1); however, only a minor fraction of the serpin molecules reacted with chymotrypsin, with the majority insensitive to cleavage in the reactive center loop. Wheat WSZ3 was cleaved specifically at P8 Thr and was not an inhibitor of chymotrypsin. These reactive-center loops may have evolved conformations that are optimal as inhibitory baits for proeinases that specifically degrade storage prolamins containing Gln-rich repetitive sequences, most likely for digestive proteinases of insect pests or fungal pathogens that infect cereals. An assembled full-length amino acid sequence of a serpin expressed in cotton boll fiber (GaZ1) included conserved regions essential for serpin-proteinase interaction, suggesting inhibitory capacity at a putative reactive center P2-P2' with a sequence of four Gln residues.     

Engineering the substrate and inhibitor specificities of human coagulation Factor VIIa

The remarkably high specificity of the coagulation proteases towards macromolecular substrates is provided by numerous interactions involving the catalytic groove and remote exosites. For FVIIa [activated FVII (Factor VII)], the principal initiator of coagulation via the extrinsic pathway, several exosites have been identified, whereas only little is known about the specificity dictated by the active-site architecture. In the present study, we have profiled the primary P4-P1 substrate specificity of FVIIa using positional scanning substrate combinatorial libraries and evaluated the role of the selective active site in defining specificity. Being a trypsin-like serine protease, FVIIa had P1 specificity exclusively towards arginine and lysine residues. In the S2 pocket, threonine, leucine, phenylalanine and valine residues were the most preferred amino acids. Both S3 and S4 appeared to be rather promiscuous, however, with some preference for aromatic amino acids at both positions. Interestingly, a significant degree of interdependence between the S3 and S4 was observed and, as a consequence, the optimal substrate for FVIIa could not be derived directly from a subsite-directed specificity screen. To evaluate the role of the active-site residues in defining specificity, a series of mutants of FVIIa were prepared at position 239 (position 99 in chymotrypsin), which is considered to be one of the most important residues for determining P2 specificity of the trypsin family members. This was confirmed for FVIIa by marked changes in primary substrate specificity and decreased rates of antithrombin III inhibition. Interestingly, these changes do not necessarily coincide with an altered ability to activate Factor X, demonstrating that inhibitor and macromolecular substrate selectivity may be engineered separately.     

An elastase inhibitor from equine leukocyte cytosol belongs to the serpin superfamily. Further characterization and amino acid sequence of the reactive center

Horse leukocyte elastase inhibitor rapidly forms stable, equimolar complexes with both human leukocyte elastase and cathepsin G, porcine pancreatic elastase, and bovine alpha-chymotrypsin. Formation of the inhibitor-pancreatic elastase complex results in peptide bond cleavage at the reactive site of the inhibitor so that a small peptide fragment representing the carboxyl-terminal sequence of the inhibitor is released. Sequence analysis of both this peptide, as well as that of an overlapping peptide obtained by enzymatic inactivation of native inhibitor with either Staphylococcus aureus metalloproteinase, Pseudomonas aeruginosa elastase, or cathepsin B, yields data which indicate that the reactive site encompasses a P1-P1' Ala-Met sequence. However, unlike the human endothelial plasminogen activator inhibitor, which also has a Met residue in the P1' position, oxidation of the horse inhibitor only slightly reduces its association rate constant with either of the elastolytic enzymes tested or with chymotrypsin. Comparison of the amino acid sequence at or near the reactive site of the horse inhibitor (P2-P18') with members of the serpin superfamily of proteinase inhibitors indicates that it not only belongs in this class but also represents the first example of a functionally active intracellular serpin.     

Reactive site mutants of recombinant protein C inhibitor

Protein C inhibitor (PCI) is a heparin-binding serine proteinase inhibitor (serpin) which is thought to be a physiological regulator of activated protein C (APC). The residues F353-R354-S355 (P2-P1-P1′) constitute part of the reactive site loop of PCI with the R-S peptide bond being cleaved by the proteinase. Changing the reactive site P1 and P2 residues to those of either proteinase nexin-1, α₁-proteinase inhibitor or heparin cofactor II resulted in a decrease in inhibitory activity towards thrombin and APC. Changing the P2 residue F353 → P generated a rPCI which was a better thrombin inhibitor, but was 10-fold less active with APC. While these results support the concept that the P1 and P2 residues are important in the specificity of PCI, they suggest that the reactive site residues are not the only determinant of serpin specificity. Kinetic analysis of the rPCI variants was consistent with PCI operating by a mechanism similar to that proposed for other serpins. In this model an intermediary complex forms between inhibitor and proteinase that can proceed to either cleavage of the inhibitor as substrate or formation of an inactive complex.     

Selective inhibition of the collagenolytic activity of human cathepsin K by altering its S2 subsite specificity

The primary specificity of papain-like cysteine proteases (family C1, clan CA) is determined by S2-P2 interactions. Despite the high amino acid sequence identities and structural similarities between cathepsins K and L, only cathepsin K is capable of cleaving interstitial collagens in their triple helical domains. To investigate this specificity, we have engineered the S2 pocket of human cathepsin K into a cathepsin L-like subsite. Using combinatorial fluorogenic substrate libraries, the P1-P4 substrate specificity of the cathepsin K variant, Tyr67Leu/Leu205Ala, was determined and compared with those of cathepsins K and L. The introduction of the double mutation into the S2 subsite of cathepsin K rendered the unique S2 binding preference of the protease for proline and leucine residues into a cathepsin L-like preference for bulky aromatic residues. Homology modeling and docking calculations supported the experimental findings. The cathepsin L-like S2 specificity of the mutant protein and the integrity of its catalytic site were confirmed by kinetic analysis of synthetic di- and tripeptide substrates as well as pH stability and pH activity profile studies. The loss of the ability to accept proline in the S2 binding pocket by the mutant protease completely abolished the collagenolytic activity of cathepsin K whereas its overall gelatinolytic activity remained unaffected. These results indicate that Tyr67 and Leu205 play a key role in the binding of proline residues in the S2 pocket of cathepsin K and are required for its unique collagenase activity.     

Substrate Specificity of the Highly Alkalophilic Bacterial Proteinase Esperase: Relation to the X-Ray Structure

Esperase is a highly alkalophilic bacterial proteinase produced by Bacillus lentus. The enzyme hydrolyzes peptide bonds comprising the carboxylic groups of hydrophobic as well as hydrophilic residues in the oxidized insulin B chain. Some of these bonds are not attacked by other alkaline microbial proteinases. P1-P4 specificity was determined by a series of peptide nitroanilides. The S1 recognition loop exhibits a preference for Phe. The "cleft" of the smallest subsite S2 prefers Ala and exhibits low affinity for the larger chain of Leu. S3 is more open than the other subsites and can accept a variety of residues. Hydrophobic interactions predominate in the S4-P4 interactions because S4 can accommodate Phe very well. The results characterize Esperase as an endopeptidase with a broader specificity in comparison with other microbial serine proteinases. This is probably owing to a more flexible substrate binding site.     

Coevolution of insect trypsins and inhibitors

Many plant proteinase inhibitors have lysine at the P1 position, presumably to avoid hydrolysis by insect trypsins. Lepidopteran trypsins appear to have adapted to resist proteinase inhibitors through increased inhibitor hydrolysis and decreased binding to inhibitor hydrophilic reactive sites. Lepidopteran digestive trypsins prefer lysine at the P1 position and have substrate binding subsites more hydrophobic than trypsins from insects in other orders. All available sequences of sensitive and inhibitor-insensitive insect trypsins were aligned with porcine trypsin, for which interactions with Kunitz and Bowman-Birk inhibitor are known. After discounting conserved positions and positions not typical of sensitive or insensitive trypsins, the following residues were considered important to insect trypsin-PI interactions (chymotrypsin numbering): 60, 94, 97, 98, 99, 188, 190, 213, 215, 217, 219, 228. These residues support the Neighbor Joining analysis tree branches separating sensitive and insensitive trypsin sequences. Primary sequences interacting with PIs are around the active site, with some forming part of the S1 (188, 217, 219 and 228) or S4 (99, 215) pockets.     

Mammalian chymotrypsin-like enzymes. Comparative reactivities of rat mast cell proteases, human and dog skin chymases, and human cathepsin G with peptide 4-nitroanilide substrates and with peptide chloromethyl ketone and sulfonyl fluoride inhibitors

The extended substrate binding sites of several chymotrypsin-like serine proteases, including rat mast cell proteases I and II (RMCP I and II, respectively) and human and dog skin chymases, have been investigated by using peptide 4-nitroanilide substrates. In general, these enzymes preferred a P1 Phe residue and hydrophobic amino acid residues in P2 and P3. A P2 Pro residue was also found to be quite acceptable. The S4 subsites of these enzymes are less restrictive than the other subsites investigated. The substrate specificity of these enzymes was also investigated by using substrates which contain model desmosine residues and peptides with amino acid sequences of the physiologically important substrates angiotensin I and angiotensinogen and alpha 1-antichymotrypsin, the major plasma inhibitor for chymotrypsin-like enzymes. These substrates were less reactive than the most reactive tripeptide reported here, Suc-Val-Pro-Phe-NA. The thiobenzyl ester Suc-Val-Pro-Phe-SBzl was found to be an extremely reactive substrate for the enzymes tested and was 6-171-fold more reactive than the 4-nitroanilide substrate. The four chymotrypsin-like enzymes were inhibited by chymostatin and N-substituted saccharin derivatives which had KI values in the micromolar range. In addition, several potent peptide chloromethyl ketone and substituted benzenesulfonyl fluoride irreversible inhibitors for these enzymes were discovered. The most potent sulfonyl fluoride inhibitor for RMCP I, RMCP II, and human skin chymase, 2-(Z-NHCH2CONH)C6H4SO2F, had kobsd/[I] values of 2500, 270, and 1800 M-1 s-1, respectively. The substrates and inhibitors reported here should be extremely useful in elucidating the physiological roles of these proteases.