Diverse effects of pH on the inhibition of human chymase by serpins

Neuroserpin Differentiates Between Forms of Tissue Type Plasminogen Activator via pH Dependent Deacylation

Tissue-type plasminogen activator (t-PA), initially characterized for its critical role in fibrinolysis, also has key functions in both physiologic and pathologic processes in the CNS. Neuroserpin (NSP) is a t-PA specific serine protease inhibitor (serpin) found almost exclusively in the CNS that regulates t-PA's proteolytic activity and protects against t-PA mediated seizure propagation and blood-brain barrier disruption. This report demonstrates that NSP inhibition of t-PA varies profoundly as a function of pH within the biologically relevant pH range for the CNS, and reflects the stability, rather than the formation of NSP: t-PA acyl-enzyme complexes. Moreover, NSP differentiates between the zymogen-like single chain form (single chain t-PA, sct-PA) and the mature protease form (two chain t-PA, tct-PA) of t-PA, demonstrating different pH profiles for protease inhibition, different pH ranges over which catalytic deacylation occurs, and different pH dependent profiles of deacylation rates for each form of t-PA. NSP's pH dependent inhibition of t-PA is not accounted for by differential acylation, and is specific for the NSP-t-PA serpin-protease pair. These results demonstrate a novel mechanism for the differential regulation of the two forms of t-PA in the CNS, and suggest a potential specific regulatory role for CNS pH in controlling t-PA proteolytic activity.

Expression of recombinant human mast cell chymase with Asn-linked glycans in glycoengineered Pichia pastoris

Recombinant human mast cell chymase (rhChymase) was expressed in secreted form as an active enzyme in the SuperMan5 strain of GlycoSwitch® Pichia pastoris, which is engineered to produce proteins with (Man)5(GlcNAc)2 Asn-linked glycans. Cation exchange and heparin affinity chromatography yielded 5mg of active rhChymase per liter of fermentation medium. Purified rhChymase migrated on SDS-PAGE as a single band of 30 kDa and treatment with peptide N-glycosidase F decreased this to 25 kDa, consistent with the established properties of native human chymase (hChymase). Polyclonal antibodies against hChymase detected rhChymase by Western blot. Active site titration with Eglin C, a potent chymase inhibitor, quantified the concentration of purified active enzyme. Kinetic analyses with succinyl-Ala-Ala-Pro-Phe (suc-AAPF) p-nitroanilide and thiobenzyl ester synthetic substrates showed that heparin significantly reduced KM, whereas heparin effects on kcat were minor. Pure rhChymase with Asn-linked glycans closely resembles hChymase. This bioengineering approach avoided hyperglycosylation and provides a source of active rhChymase for other studies as well as a foundation for production of recombinant enzyme with human glycosylation patterns.

Inhibition of chymotrypsin- and subtilisin-like serine proteases with Tk-serpin from hyperthermophilic archaeon Thermococcus kodakaraensis

A serpin homologue (Tk-serpin) from the hyperthermophilic archaeon Thermococcus kodakaraensis was overproduced in E. coli, purified, and characterized. Tk-serpin irreversibly inhibits Tk-subtilisin (TKS) from the same organism with the second-order association rate constants (k(ass)) of 5.2×10³ M⁻¹ s⁻¹ at 40°C and 3.1×10⁵ M⁻¹ s⁻¹ at 80°C, indicating that Tk-serpin inhibits TKS more strongly at 80°C than at 40°C. It also irreversibly inhibits chymotrypsin, subtilisin Carlsberg, and proteinase K at 40°C with the k(ass) values comparable to that for TKS at 80°C. Casein zymography showed that Tk-serpin inhibits these proteases by forming a SDS-resistant complex, which is typical to inhibitory serpins. The ratio of moles of Tk-serpin needed to inhibit 1 mol of protease (stoichiometry of inhibition, SI) varies from 40 to 80 at 20°C, but decreases to the minimum values of 3-7 as the temperature increases. The inhibitory activities of Tk-serpin for these proteases increase as the stabilities of these proteases decrease, suggesting that a flexibility of the active-site of protease is one of the determinants for susceptibility of protease to inhibition by Tk-serpin. This report showed for the first time that Tk-serpin inhibits both chymotrypsin- and subtilisin-like serine proteases and its inhibitory activity increases as the temperature increases up to 100°C.

Potency variation of small-molecule chymase inhibitors across species

Chymases (EC 3.4.21.39) are mast cell serine proteinases that are variably expressed in different species and, in most cases, display either chymotryptic or elastolytic substrate specificity. Given that chymase inhibitors have emerged as potential therapeutic agents for treating various inflammatory, allergic, and cardiovascular disorders, it is important to understand interspecies differences of the enzymes as well as the behavior of inhibitors with them. We have expressed chymases from humans, macaques, dogs, sheep (MCP2 and MCP3), guinea pigs, and hamsters (HAM1 and HAM2) in baculovirus-infected insect cells. The enzymes were purified and characterized with kinetic constants by using chromogenic substrates. We evaluated in vitro the potency of five nonpeptide inhibitors, originally targeted against human chymase. The inhibitors exhibited remarkable cross-species variation of sensitivity, with the greatest potency observed against human and macaque chymases, with K(i) values ranging from approximately 0.4 to 72nM. Compounds were 10-300-fold less potent, and in some instances ineffective, against chymases from the other species. The X-ray structure of one of the potent phosphinate inhibitors, JNJ-18054478, complexed with human chymase was solved at 1.8A resolution to further understand the binding mode. Subtle variations in the residues in the active site that are already known to influence chymase substrate specificity can also strongly affect the compound potency. The results are discussed in the context of selecting a suitable animal model to study compounds ultimately targeted for human chymase.

Stability of mutant serpin/furin complexes: dependence on pH and regulation at the deacylation step

Furin proteolytically cleaves a wide variety of proprotein substrates mainly within the trans-Golgi network (TGN) but also at the cell membrane and in endosomal compartments where pH is more acidic. Incorporation of furin recognition sequences within the reactive site loop (RSL) of alpha(1)-antitrypsin (AT) leads to the production of furin inhibitors. In an attempt to design more stable, potent, and specific serpin-based inhibitors, we constructed a series of AT and alpha(1)-antichymotrypsin (ACT) mutants by modifying the P(7)-P(1) region of their RSLs. The biochemical properties of these variants were assessed by evaluating their propensity to establish SDS-resistant complexes with furin in a variety of conditions (pH 6.0-9.0) and by measuring their association rate constants. The effect of pH during the initial steps of complex formation was minimal, suggesting that the acylation step is not rate-limiting. The decrease in stoichiometry of inhibition (SI) values observed in AT variants at high pHs was a result of the reduced pH-dependent deacylation rate, which is rate-limiting in this mechanism and which suggests increased complex stability. Conversely, the SI values for ACT mutants had a tendency to be lower at acidic pH. Transiently transfecting HEK293 cells with these mutants abolished processing of the pro-von Willebrand factor precursor but, interestingly, only the ACT variants were secreted in the media as uncleaved forms. Our results suggest that reengineering the reactive site loops of serpins to accommodate and target furin or other serine proteases must take into account the intrinsic physicochemical properties of the serpin.

The production of collagen and the activity of mast-cell chymase increase in human skin after irradiation therapy

Fibrosis is a common complication of radiotherapy. The pathogenesis of radiation-induced fibrosis is not known in detail. There is increasing evidence to suggest that mast cells contribute to various fibrotic conditions. Several mast-cell mediators have been proposed to have a role in fibrogenesis. Tryptase and chymase, the predominant proteins in mast cells, have been shown to induce fibroblast proliferation and collagen synthesis in vitro. In order to explore the role of mast cells in irradiation-induced fibrosis, we analyzed skin biopsies and suction blister fluid (SBF) samples from the lesional and healthy-looking skin of 10 patients who had been treated for breast cancer with surgery and radiotherapy. The biopsies were analyzed histochemically for mast-cell tryptase, chymase, kit receptor, and tumor necrosis factor-alpha. Skin collagen synthesis was assessed by determining the levels of type I and III procollagen amino-terminal propeptides (PINP and PIIINP) in SBF and using immunohistochemical staining for PINP. Immunohistochemical stainings for prolyl-4-hydroxylase reflecting collagen synthesis and chymase immunoreactivity in irradiated and control skin were also performed. The mean level of procollagen propeptides in SBF, which reflects actual skin collagen synthesis in vivo, was markedly increased in irradiated skin compared to corresponding healthy control skin areas. The mean number of PINP-positive fibroblasts was also significantly increased in the upper dermis of radiotherapy-treated skin. The number of cells positive for tryptase, chymase and kit receptor was markedly increased in irradiated skin. In addition, using double-staining techniques, it was possible to demonstrate that in some areas of the dermis, tryptase-positive mast cells and fibroblasts are closely associated. These findings suggest a possible role of mast cells in enhanced skin collagen synthesis and fibrosis induced by radiotherapy.

Enzymatic and Molecular Characteristics of the Efficiency and Specificity of Exfoliative Toxin Cleavage of Desmoglein 1

Exfoliative toxins (ETs) from Staphylococcus aureus blister the superficial epidermis by hydrolyzing a single peptide bond, Glu381-Gly382, located between extracellular domains 3 and 4 of desmoglein 1 (Dsg1). Enzyme activity is dependent on the calcium-stabilized structure of Dsg1. Here we further define the characteristics of this cleavage. Kinetic studies monitoring the cleavage of Dsg1 by ETA, ETB, and ETD demonstrated kcat/Km values of 2-6 x 10(4) m(-1) s(-1), suggesting very efficient proteolysis. Proteolysis by ETA was not efficiently inhibited by broad spectrum serine protease inhibitors, suggesting that the enzyme cleavage site may be inactive or inaccessible before specific binding to its substrate. Using truncated mutants of human Dsg1 and chimeric molecules between human Dsg1 and either human Dsg3 or canine Dsg1, we show that for cleavage, human-specific amino acids from Dsg1 are necessary in extracellular domain 3 upstream of the scissile bond. If these residues are canine rather than human, ETA binds, but does not cleave, canine Dsg1. These data suggest that the exquisite specificity and efficiency of ETA may depend on the enzyme's binding upstream of the cleavage site with a very specific fit, like a key in a lock.

The effects of reactive site location on the inhibitory properties of the serpin alpha(1)-antichymotrypsin

The large size of the serpin reactive site loop (RSL) suggests that the role of the RSL in protease inhibition is more complex than that of presenting the reactive site (P1 residue) to the protease. This study examines the effect on inhibition of relocating the reactive site (Leu-358) of the serpin alpha(1)-antichymotrypsin either one residue closer (P2) or further (P1') from the base of the RSL (Glu-342). alpha(1)-Antichymotrypsin variants were produced by mutation within the P4-P2' region; the sequence ITLLSA was changed to ITLSSA to relocate the reactive site to P2 (Leu-357) and to ITITLS to relocate it to P1' (Leu-359). Inhibition of the chymotrypsin-like proteases human chymase and chymotrypsin and the non-target protease human neutrophil elastase (HNE) were analyzed. The P2 variant inhibited chymase and chymotrypsin but not HNE. Relative to P1, interaction at P2 was characterized by greater complex stability, lower inhibition rate constants, and increased stoichiometry of inhibition values. In contrast, the P1' variant inhibited HNE (stoichiometry of inhibition = 4) but not chymase or chymotrypsin. However, inhibition of HNE was by interaction with Ile-357, the P2 residue. The P1' site was recognized by all proteases as a cleavage site. Covalent-complexes resistant to SDS-PAGE were observed in all inhibitory reactions, consistent with the trapping of the protease as a serpin-acyl protease complex. The complete loss in inhibitory activity associated with lengthening the Glu-342-reactive site distance by a single residue and the enhanced stability of complexes associated with shortening this distance by a single residue are compatible with the distorted-protease model of inhibition requiring full insertion of the RSL into the body of the serpin and translocation of the linked protease to the pole opposite from that of encounter.

Tissue-specific expression of mast cell granule serine proteinases and their role in inflammation in the lung and gut

Serine proteinases with trypsin-like (tryptase) and chymotrypsin-like (chymase) properties are major constituents of mast cell granules. Several tetrameric tryptases with differing specificities have been characterized in humans, but only a single chymase. In other species there are larger families of chymases with distinct and narrow proteolytic specificities. Expression of chymases and tryptases varies between tissues. Human pulmonary and gastrointestinal mast cells express chymase at lower levels than tryptase, whereas rodent and ruminant gastrointestinal mast cells express uniquely mucosa-specific chymases. Local and systemic release of chymases and tryptases can be quantified by immunoassay, providing highly specific markers of mast cell activation. The expression and constitutive extracellular secretion of the mucosa-specific chymase, mouse mast cell proteinase-1 (mMCP-1), is regulated by transforming growth factor-beta1 (TGF-beta1) in vitro, but it is not clear how the differential expression of chymases and tryptases is regulated in other species. Few native inhibitors have been identified for tryptases but the tetramers dissociate into inactive subunits in the absence of heparin. Chymases are variably inhibited by plasma proteinase inhibitors and by secretory leucocyte protease inhibitor (SLPI) that is expressed in the airways. Tryptases and chymases promote vascular permeability via indirect and possibly direct mechanisms. They contribute to tissue remodelling through selective proteolysis of matrix proteins and through activation of proteinase-activated receptors and of matrix metalloproteinases. Chymase may modulate vascular tissues through its ability to process angiotensin-I to angiotensin-II. Mucosa-specific chymases promote epithelial permeability and are involved in the immune expulsion of intestinal nematodes. Importantly, granule proteinases released extracellularly contribute to the recruitment of inflammatory cells and may thus be involved in innate responses to infection.

Evidence for diversity of substrate specificity among members of the chymase family of serine proteases

The term chymase is used to signify a chymotrypsin-like protease stored within the secretory granules of mast cells. Primarily based on amino acid sequence homology, 18 chymases have been identified among different animals. This study, which compares the structure of the primary specificity pocket (S1 subsite), defines a subgroup of four chymases likely to have a substrate specificity with more elastase- than chymotrypsin-like qualities. This difference is due, primarily, to finding a Val instead of a Gly at residue 199, a position corresponding to Gly216 in bovine chymotrypsin and Val216 in neutrophil and porcine elastases. Chymases with Val at 199 are found only in animals expressing multiple chymases, consistent with the premise that their substrate specificity differs from that of chymases with Gly at 199.

Heterogeneity in serpin-protease complexes as demonstrated by differences in the mechanism of complex breakdown

Serpins trap their target proteases in the form of an acyl-enzyme complex. The trap is kinetic, however, and thus serpin-protease complexes ultimately break down, releasing a cleaved inactive serpin and an active protease. The rates of this deacylation process vary greatly depending on the serpin-protease pair with half-lives ranging from minutes to months. The reasons for the diversity in breakdown rates are not clearly understood. In the current study, pH and solvent isotope effects were utilized to probe the mechanism of breakdown for an extremely stable complex and several unstable complexes. Two different patterns for the pH dependence of k(bkdn), the first-order rate constant of breakdown, were found. The stable complex, which breaks down at neutral pH with a half-life of approximately 2 weeks, exhibited a pH-k(bkdn) profile consistent with solvent-hydroxide ion mediated ester hydrolysis. There was no evidence for the participation of the catalytic machinery in the breakdown of this complex, suggesting extensive distortion of the active site. The unstable complexes, which break down with half-lives ranging from minutes to hours, exhibited a bell-shaped pH profile for k(bkdn), typical of the pH-rate profiles of free serine proteases. In the low to neutral pH range k(bkdn) increased with increasing pH in a manner characteristic of His57-mediated catalysis. In the alkaline pH range a decrease in k(bkdn) was observed, consistent with the titration of the Ile16-Asp194 salt bridge (chymotrypsinogen numbering). The alkaline pH dependence was not exhibited in pH-rate profiles of free or substrate-bound HNE, indicating that the salt bridge was significantly destabilized in the complexed protease. These results indicate that breakdown is catalytically mediated in the unstable complexes although, most likely, the protease is not in its native conformation and the catalytic machinery functions inefficiently. However, a mechanism in which breakdown is determined by the equilibrium between distorted and undistorted forms of the complexed protease cannot be completely dismissed. Overall, the results of this study suggest that the protease structure in unstable complexes is distorted to a lesser extent than in stable complexes.

Resolution of Michaelis complex, acylation, and conformational change steps in the reactions of the serpin, plasminogen activator inhibitor-1, with tissue plasminogen activator and trypsin

Michaelis complex, acylation, and conformational change steps were resolved in the reactions of the serpin, plasminogen activator inhibitor-1 (PAI-1), with tissue plasminogen activator (tPA) and trypsin by comparing the reactions of active and Ser 195-inactivated enzymes with site-specific fluorescent-labeled PAI-1 derivatives that report these events. Anhydrotrypsin or S195A tPA-induced fluorescence changes in P1'-Cys and P9-Cys PAI-1 variants labeled with the fluorophore, NBD, indicative of a substrate-like interaction of the serpin reactive loop with the proteinase active-site, with the P1' label but not the P9 label perturbing the interactions by 10-60-fold. Rapid kinetic analyses of the labeled PAI-1-inactive enzyme interactions were consistent with a single-step reversible binding process involving no conformational change. Blocking of PAI-1 reactive loop-beta-sheet A interactions through mutation of the P14 Thr --> Arg or annealing a reactive center loop peptide into sheet A did not weaken the binding of the inactive enzymes, suggesting that loop-sheet interactions were unlikely to be induced by the binding. Only active trypsin and tPA induced the characteristic fluorescence changes in the labeled PAI-1 variants previously shown to report acylation and reactive loop-sheet A interactions during the PAI-1-proteinase reaction. Rapid kinetic analyses showed saturation of the reaction rate constant and, in the case of the P1'-labeled PAI-1 reaction, biphasic changes in fluorescence indicative of an intermediate resembling the noncovalent complex on the path to the covalent complex. Indistinguishable K(M) and k(lim) values of approximately 20 microM and 80-90 s(-1) for reaction of the two labeled PAI-1s with trypsin suggested that a diffusion-limited association of PAI-1 and trypsin and rate-limiting acylation step, insensitive to the effects of labeling, controlled covalent complex formation. By contrast, differing values of K(M) of 1.7 and 0.1 microM and of k(lim) of 17 and 2.6 s(-1) for tPA reactions with P1' and P9-labeled PAI-1s, respectively, suggested that tPA-PAI-1 exosite interactions, sensitive to the effects of labeling, promoted a rapid association of PAI-1 and tPA and reversible formation of an acyl-enzyme complex but impeded a rate-limiting burial of the reactive loop leading to trapping of the acyl-enzyme complex. Together, the results suggest a kinetic pathway for formation of the covalent complex between PAI-1 and proteinases involving the initial formation of a Michaelis-type noncovalent complex without significant conformational change, followed by reversible acylation and irreversible reactive loop conformational change steps that trap the proteinase in a covalent complex.

The release of histamine is associated with the inactivation of mast cell chymase during immediate allergic wheal reaction in the skin

BACKGROUND

Chymase released by mast cells can participate in the immediate allergic wheal. However, chymase may be susceptible to inactivation by protease inhibitors during degranulation.

OBJECTIVE

To study the inactivation of chymase and the release of histamine in the immediate allergic wheal reaction.

METHODS

Ten sensitive atopic subjects were prick-tested with the cow dander allergen, and skin biopsies were taken from the control skin and from the challenge site at 30 and 120 min. Tryptase (Tact) and chymase (Cact) activities in mast cells were measured enzyme-histochemically. Sequential double-staining was used to demonstrate the activity and immunoreactivity (Cprot) of chymase in the same mast cell as well as alpha1-proteinase inhibitor (alpha1-PI) and alpha1-antichymotrypsin (alpha1-AC) in Tact+ cells. Skin microdialysis was used to monitor histamine release after the allergen challenge for up to 120 min

RESULTS

The numbers of Tact+ and Cact+ cells were already maximally decreased at 30 min by 37 +/- 17% and 61 +/- 31%, respectively (mean +/- SD, P < 0.0001). At the same time the Cact+/Cprot+ ratio decreased from 82 +/- 15% to 43 +/- 16% (P < 0.0001). The cumulative histamine release at 30 min correlated negatively with the Cact+/Tact+ (P = 0.047) and Cact+/Cprot+ (P = 0.024) ratios, but positively with the decrease in the number of Cact+ cells (P = 0.024). These data indicate that the higher the histamine release the lower the chymase activity. Also the number of Tact+ cells in the control skin correlated positively with the cumulative histamine release at 120 min (P = 0.043). In the control skin, 95 +/- 6% and 76 +/- 8% of the Tact+ cells displayed alpha1-AC and alpha1-PI, respectively.

CONCLUSION

In addition to extensive degranulation of mast cells, chymase is also rapidly inactivated after the allergen challenge, possibly by pre-existing chymase inhibitors in the mast cells. This inactivation is associated with the release of histamine.

Evidence that translocation of the proteinase precedes its acylation in the serpin inhibition pathway

The inhibition of proteinases by serpins involves cleavage of the serpin, acylation, and translocation of the proteinase. To see whether acylation precedes or follows translocation, we have investigated the pH dependence of the interaction of fluorescein isothiocyanate-elastase with rhodamine alpha(1)-proteinase inhibitor (alpha(1)PI) using two independent methods: (i) kinetics of fluorescence energy transfer which yields k(2,f), the rate constant for the fluorescently detected decay of the Michaelis-type complex (Mellet, P., Boudier, C., Mély, Y., and Bieth, J. G. (1998) J. Biol. Chem. 273, 9119-9123); (ii) kinetics of elastase-catalyzed hydrolysis of a substrate in the presence of alpha(1)PI, which yields k(2,e), the rate constant for the conversion of the Michaelis-type complex into irreversibly inhibited elastase. Both rate constants were found to be pH-independent and close to each other, indicating that acylation, a pH-dependent phenomenon, does not govern the decay of the Michaelis-type complex and, therefore, follows translocation. On the other hand, anhydro-elastase reacts with alpha(1)PI to form a Michaelis-type complex that translocates into a second complex with a rate constant close to that measured with active elastase, confirming that acylation is not a prerequisite for translocation. Moreover, the anhydro-elastase-alpha(1)PI complex was found to be thermodynamically reversible, suggesting that translocation of active elastase might also be reversible. We propose that serpins form a Michaelis-type complex EI(M), which reversibly translocates into EI(tr) whose acylation yields the irreversible complex EI(ac). [see text]

Antichymotrypsin interaction with chymotrypsin. Intermediates on the way to inhibited complex formation

Serpins form enzymatically inactive covalent complexes (designated E*I*) with their target proteinases, corresponding most likely to the acyl enzyme that resembles the normal intermediate in substrate turnover. Formation of E*I* involves large changes in the conformation of the reactive center loop (residues P17 to P9') and of the serpin molecule in general. The "hinge" region of the reactive center loop, including residues P10-P14, shows facile movement in and out of beta-sheet A, and this movement appears to be crucial in determining whether E*I* is formed (the inhibitor pathway) or whether I is rapidly hydrolyzed to I* (the substrate pathway). Here, we report stopped-flow and rapid quench studies investigating the pH dependence of the conversion of the alpha1-antichymotrypsin.alpha-chymotrypsin encounter complex, E.I, to E*I*. These studies utilize fluorescent derivatives of cysteine variants of alpha1-antichymotrypsin at the P11 and P13 residues. Our results demonstrate three identifiable intermediates, EIa, EIb, and EIc, between E.I and E*I* and permit informed speculation regarding the nature of these intermediates. Partitioning between inhibitor and substrate pathways occurs late in the process of E*I* formation, most likely from a species occurring between EIc and E*I*.

Inhibitory specificity of the anti-inflammatory myxoma virus serpin, SERP-1

SERP-1 is a myxoma virus-encoded serpin, secreted from infected cells, that is required for virulence and has anti-inflammatory activity. We report that purified recombinant SERP-1 forms SDS-stable complexes with urokinase-type plasminogen activator (uPA), tissue-type plasminogen activator (tPA), plasmin, thrombin, and factor Xa. N-terminal sequencing confirmed Arg319-Asn320 as the site of reaction. Mutation of these residues to Ala-Ala abolished inhibitory activity but had no effect on the specific cleavage at Thr315-Leu316 seen with elastase and with cathepsin G. Kinetic analysis of the reactions with uPA, tPA, plasmin, thrombin, Xa, and C1s showed second-order rate constants to vary over 3 logs, from kinh = 3 x 10(5) M-1 s-1 with thrombin to approximately 600 M-1 s-1 with C1s, while steady-state inhibition constants ranged from KI = 10 pM with thrombin to approximately 100 nM with C1s. Stoichiometries of inhibition varied between SI = 1.4 +/- 0.1 for uPA to SI = 13 +/- 3 for thrombin. Analysis of the variations in inhibition kinetics shows that when serpins act at low concentrations, comparable with the target protease or with KI (as appears likely for SERP-1 in vivo), inhibitory specificity becomes less dominated by kinh and is increasingly dependent on partitioning within the branched reaction mechanism and on the lifetime of the inhibited complex.

Antichymotrypsin interaction with chymotrypsin. Reactions following encounter complex formation

Serpins, serine proteinase inhibitors, form enzymatically inactive, 1:1 complexes (denoted E*I*) with their target proteinases, that only slowly release I*, in which the P1-P1' linkage is cleaved. Recently we presented evidence that the serpin antichymotrypsin (ACT, I) reacts with the serine proteinase chymotrypsin (Chtr, E) to form an E*I* complex via a three-step mechanism, E + I <==> E .I <==> EI' <==> E*I* in which EI', which retains the P1-P1' linkage, is formed in a partly or largely rate-determining step, depending on temperature (O'Malley, K. H, Nair, S. A., Rubin, H., and Cooperman, B. S. (1997) J. Biol. Chem. 272, 5354-5359). Here we extend these studies through the introduction of a new assay for the formation of the postcomplex fragment, corresponding to ACT residues 359 (the P1' residue) to 398 (the C terminus), coupled with rapid quench flow kinetic analysis. We show that the E.I encounter complex of wild type-rACT and Chtr forms both E*I* and postcomplex fragment with the same rate constant, so that both species arise from EI' conversion to E*I*. These results support our earlier conclusion that the P1-P1' linkage is preserved in EI' and imply that E*I* corresponds to a covalent adduct of E and I, either acyl enzyme or the tetrahedral intermediate formed by water attack on acyl enzyme. Furthermore, we show that the A347R (P12) variant of rACT, which is a substrate rather than an inhibitor of Chtr, has a rate constant for postcomplex fragment formation from the E.I complex very similar to that observed for WT-rACT, implying that EI' is the common intermediate from which partitioning to inhibitor and substrate pathways occurs. These results are used to elaborate a proposed scheme for ACT interaction with Chtr that is considered in the light of relevant results from studies of other serpin-serine proteinase pairs.

Recombinant expression of human mast cell proteases chymase and tryptase

Expression of recombinant human chymase and tryptase was achieved in a baculovirus-insect cell system using a fusion protein construct. Recombinant baculovirus was produced with DNA coding for a NH2-ubiquitin-chymase-COOH or NH2-ubiquitin-tryptase-COOH fusion protein inserted immediately downstream of the signal sequence for the secreted envelope protein, glycoprotein 67. In each construct, the natural prepropeptide sequence of the protease was replaced by the amino acid sequence for the enterokinase cleavage site of trypsinogen. High Five insect cells infected with either of the modified baculovirus produced mg quantities of each fusion protein per liter of culture. Treatment of the chymase-fusion protein with enterokinase or the tryptase-fusion protein with enterokinase in the presence of a highly charged polysaccharide (dextran sulfate or heparin) produced enzymatically active proteases with properties of the native enzymes. A procedure for the purification of mg quantities of recombinant chymase from infected-cell medium is presented.