Kunitz-type protease inhibitor found in rat mast cells. Purification, properties, and amino acid sequence

A low molecular weight serine protease inhibitor, named trypstatin, was purified from rat peritoneal mast cells. It is a single polypeptide with 61 amino acid residues and an Mr of 6610. Trypstatin markedly inhibits blood coagulation factor Xa (Ki = 1.2 x 10(-10) M) and tryptase (Ki = 3.6 x 10(-10) M) from rat mast cells, which have activities that convert prothrombin to thrombin. It also inhibits porcine pancreatic trypsin (Ki = 1.4 x 10(-8) M) and chymase (Ki = 2.4 x 10(-8) M) from rat mast cells, but not papain, alpha-thrombin, or porcine pancreatic elastase. Trypstatin forms a complex in a molar ratio of 1:1 with trypsin and one subunit of tryptase. The complete amino acid sequence of this inhibitor was determined and compared with those of Kunitz-type inhibitors. Trypstatin has a high degree of sequence homology with human and bovine inter-alpha-trypsin inhibitors, A4(751) Alzheimer's disease amyloid protein precursor, and basic pancreatic trypsin inhibitor. However, unlike other known Kunitz-type protease inhibitors, it inhibits factor Xa most strongly.     

Kinetic studies on the inhibitions of mast cell chymase by natural serine protease inhibitors: indications for potential biological functions of these inhibitors

We have found that degranulation from mast cells is specifically inhibited by the inhibitors of chymase (10). Among the natural serine protease inhibitors tested, Bowman-Birk soybean protease inhibitor, Eglin C, and human alpha 1-antichymotrypsin inhibited chymase more strongly than did chymostatin, Kunitz soybean protease inhibitor, and phosphatidylserine. Of the inhibitors tested, Bowman-Birk soybean protease inhibitor was the strongest inhibitor of chymase, its Ki value being 13.2 X 10(-9) M. Kinetic studies showed that these inhibitors were all noncompetitive inhibitors of chymase. Bowman-Birk and Kunitz soybean protease inhibitors inhibited both chymotrypsin-type and trypsin-type serine proteases but Eglin C specifically inhibited chymotrypsin-type proteases.     

Tryptase in rat mast cells: properties and inhibition by various inhibitors in comparison with chymase

Previous studies with trans-4-(guanidinomethyl)cyclohexanecarboxylic acid 4-tert-butylphenyl ester (GMCHA-OPhBut), a trypsin inhibitor, strongly suggested the involvement of a trypsin-like protease in histamine release from mast cells induced by various secretagogues (Takei, M., Matumoto, T., Endo, K. & Muramatu, M. (1988) Agents and Actions, in press; Takei, M., Matumoto, T., Ito, T., Endo, K. & Muramatu, M.; Takei, M., Matumoto, T., Endo, K. & Muramatu, M. and Takei, M., Matumoto, T., Urashima, H., Endo, K. & Muramatu, M., unpublished results). Two serine proteases, chymase (Benditt, E.F. & Arase, M. (1959) J. Exp. Med. 110, 451-460) and tryptase Kido, H., Fukusen, N. & Katunuma, N. (1985) Arch. Biochem. Biophys. 239, 436-443) were demonstrated in rat peritoneal mast cells. Both enzymes were purified and the effects of inhibitors for trypsin and chymotrypsin on these proteases were examined. The trypsin-like protease was found in saline extract and purified by successive chromatographies on Sephadex G-100 and DEAE-cellulose columns. The molecular mass of this protease was apparently 120,000 Da. This protease showed maximal activity at pH 7.1 and was named pH 7 tryptase. Chymase was obtained from 1.5M NaCl extract. pH 7 Tryptase markedly hydrolysed Boc-Phe-Ser-Arg-NH-Mec and Boc-Val-Pro-Arg-NH-Mec among the various substrates containing arginyl and lysyl bonds but did not cleave Tos-Arg-OMe. Tos-Lys-CH2Cl and diisopropylfluorophosphate strongly inhibited this protease. Various inhibitors for trypsin inhibited pH 7 tryptase, and those for chymotrypsin inhibited chymase. Among the esters of GMCHA examined, GMCHA-OPhBut most strongly and competitively inhibited pH 7 tryptase but it had no effect on chymase.     

Mast cell tryptase from pig lungs triggers infection by pneumotropic Sendai and influenza A viruses. Purification and characterization.

A novel trypsin-type serine proteinase, which processes the precursors of the envelope fusion glycoproteins of pneumotropic Sendai and human influenza A viruses, was purified to homogeneity from pig lungs. On SDS/PAGE, the purified enzyme gave a protein band corresponding to about 32 kDa, and has an apparent molecular mass of 120 kDa, as determined by gel permeation chromatography. Immunohistochemical staining with antibodies against this enzyme revealed that the enzyme is located in pig lung mast cells. The N-terminal 44-amino-acid sequence of the enzyme exhibits about 80% identity with those of mast cell tryptases from other species. Of the inhibitors tested, di-isopropyl fluorophosphate, antipain, leupeptin, benzamidine and a few proteinaceous inhibitors, such as mucus protease inhibitor and aprotinin, inhibited this enzyme activity. Heparin stabilized the enzyme, but high-ionic-strength conditions did not, unlike for human mast cell tryptase. The purified enzyme efficiently processed the fusion glycoprotein precursor of Sendai virus and slowly processed hemagglutinin of human influenza A virus, and triggered the infectivity of Sendai virus in a dose-dependent manner, although human mast cell tryptase beta and rat mast cell tryptase (rat MCP-7) from lungs did not process these fusion glycoproteins at all. These results suggest that mast cell tryptase in pig lungs is the possible trigger of the pneumotropic virus infections.     

Chymase and tryptase in dog mastocytoma cells: asynchronous expression as revealed by enzyme cytochemical staining

Mast cell populations can be distinguished by differences in the content and substrate specificity of their two major cytoplasmic granule proteases, the chymases and the tryptases. To explore the origins of differences in the types of proteases present in mast cells, we used a double cytochemical staining technique to reveal both chymase and tryptase in cells from four lines of dog mast cell tumors containing both enzymes. We expected that if chymase and tryptase were expressed together during cell development the relative staining intensity of chymase compared to tryptase would be constant among different cells of each tumor. Instead, we found substantial variation in the relative intensity of chymase and tryptase staining among cells of a given mastocytoma line, each of which contained cells presumed to be monoclonal in origin but heterogeneous with respect to cell development. The overall staining intensity for chymase or tryptase correlated with the amount of protease activity in extracts of tumor homogenates. Staining specificity was established by use of selective inhibitors and competitive substrates and was tested on various types of dog cells obtained by bronchoalveolar lavage. The results suggest that active chymase and tryptase may be expressed differently during mast cell differentiation and support the possibility of a close developmental relationship between mast cells differing in protease phenotype. Moreover, the success of the staining procedures applied to mastocytoma cells suggests that they may be of general utility in phenotyping of mast cells according to the protease activities present in their granules.     

Activation of latent human granulocyte gelatinase by rat mast cell protease

Rat peritoneal mast cell extract contains an activator of latent human granulocyte gelatinase. The activator has been partially purified and characterized. It shows a similarity to rat mast cell chymase in several properties including its molecular weight, substrate specificity and sensitivity to inhibitors. The activation of latent gelatinase with rat mast cell protease is dependent on protease concentration, incubation time and is mediated through the catalytic site of the activator. The significance of mast cell protease in the regulation of collagenolytic enzymes is discussed.     

Biological functions of serine proteases in mast cells in allergic inflammation

Serine proteases in mast cell granules, such as chymase, atypical chymase, and tryptase, which are major proteins in the granules, may play important roles in the process of immunoglobulin E (IgE)-mediated degranulation and in pathobiological alterations in tissues. Indeed, inhibitors of chymase, substrate analogs, and antichymase F(ab')2, but not inhibitors of tryptase, markedly inhibited histamine release induced by IgE-receptor bridging but not that induced by Ca ionophore. In contrast, inhibitors of metalloprotease inhibited histamine release induced not only by IgE-receptor bridging but also by Ca ionophore. These results suggest that chymase and metalloprotease are involved at different steps in the process of degranulation. The extents of inhibition of histamine release were closely correlated with the amounts of the inhibitors of chymase accumulated in the granules. After degranulation, the released proteases may in part contribute to pathobiological alterations in allergic disorders through generations of C3a anaphylatoxin and thrombin by human and rat tryptase, respectively, and those of angiotensin II and a chemotactic factor of neutrophils by human and rat chymase, respectively. Moreover, chymase and atypical chymase from rat were shown to destroy type IV collagen, and human tryptase was found to hydrolyze various plasma proteins, such as fibrinogen and high-molecular-weight kininogen. The biological activities of tryptase and chymase from rat may be regulated by their dissociation from and association with trypstatin, an endogenous inhibitor of these proteases.     

Rat mast cell protease 4 is a beta-chymase with unusually stringent substrate recognition profile

Activated mast cells release a variety of potent inflammatory mediators including histamine, cytokines, proteoglycans, and serine proteases. The serine proteases belong to either the chymase (chymotrypsin-like substrate specificity) or tryptase (trypsin-like specificity) family. In this report we have investigated the substrate specificity of a recently identified mast cell protease, rat mast cell protease-4 (rMCP-4). Based on structural homology, rMCP-4 is predicted to belong to the chymase family, although rMCP-4 has previously not been characterized at the protein level. rMCP-4 was expressed with an N-terminal His tag followed by an enterokinase site substituting for the native activation peptide. The enterokinase-cleaved fusion protein was labeled by diisopropyl fluorophosphate, demonstrating that it is an active serine protease. Moreover, rMCP-4 hydrolyzed MeO-Suc-Arg-Ala-Tyr-pNA, thus verifying that this protease belongs to the chymase family. rMCP-4 bound to heparin, and the enzymatic activity toward MeO-Suc-Arg-Ala-Tyr-pNA was strongly enhanced in the presence of heparin. Detailed analysis of the substrate specificity was performed using peptide phage display technique. After six rounds of amplification a consensus sequence, Leu-Val-Trp-Phe-Arg-Gly, was obtained. The corresponding peptide was synthesized, and rMCP-4 was shown to cleave only the Phe-Arg bond in this peptide. This demonstrates that rMCP-4 displays a striking preference for bulky/aromatic amino acid residues in both the P1 and P2 positions.     

Dog mastocytoma tryptase: affinity purification, characterization, and amino-terminal sequence

A tryptic protease with the characteristics of a mast cell tryptase was purified from dog mastocytoma cells propagated in nude mice. Partial amino acid sequence of the mastocytoma tryptase revealed unexpected differences in comparison with other mast cell and leukocyte granule protease sequences. Extraction from mastocytoma homogenates at high ionic strength, followed by gel filtration and benzamidine affinity chromatography yielded a product with several closely spaced bands (Mr 30,000-32,000) on gel electrophoresis and a single N-terminal sequence. Nondenaturing analytical gel filtration revealed an apparent Mr of 132,000, suggesting noncovalent association as a tetramer. Studies with peptide p-nitroanilides indicated pronounced substrate preferences, with P1 arginine preferred to lysine. Benzoyl-L-Lys-Gly-Arg-p-nitroanilide was the best of the substrates screened. Inhibition by diisopropyl fluorophosphate and tosyllysine chloromethyl ketone indicated that the enzyme is a serine protease. Like the tryptases of human mast cells, mastocytoma tryptic protease was inhibited by NaCl, resistant to inactivation by alpha 1-proteinase inhibitor and plasma, and stabilized by heparin. Comparison of the N-terminal 24 residues of mastocytoma tryptase revealed 80% identity with the more limited sequence reported for human lung tryptase, and surprisingly, closer homology to serine proteases of digestion and clotting than to other leukocyte granule proteases sequenced to date, including mast cell chymase. The N-terminal isoleucine is the homolog of trypsinogen Ile-16 which becomes the new N-terminus upon cleavage of the activation peptide. Thus, the tryptase N-terminus is related to the catalytic domain of activated serine proteases, and lacks the N-terminal regulatory domains found in most clotting and complement serine proteases. These findings provide further evidence that tryptases are unique serine proteases and that they may be less closely related in evolution and function than are other leukocyte granule proteases described to date.     

Involvement of tryptase-related cellular protease(s) in human immunodeficiency virus type 1 infection

Trypstatin, a new cellular Kunitz-type protease inhibitor purified from rat mast cells, inhibited syncytium formation in human immunodeficiency virus type 1 (HIV-1)-infected CCRF-CEM and uninfected Molt-4 clone 8 at a concentration of 1 microM. Anti-rat tongue mast cell tryptase antibodies reacted with Molt-4 clone 8 cells, as determined by Western blot and by immunofluorescence. In addition, the antibody inhibited syncytium formation. These findings along with homologous sequences with trypstatin and a neutralizing epitope of gp120 of HIV-1 suggest that a tryptase-like cellular enzyme(s) is involved in HIV-1 infection.     

Purification and identification of two serine class proteinases from dog mast biochemically and immunologically similar to human proteinases tryptase and chymase

Serine class proteinases with trypsin-like and chymotrypsin-like specificity were purified from dog mastocytoma tissue. An antiserum was produced against the chymotrypsin-like proteinase. The antiserum reacted with mast cells in skin sections prepared from normal dogs consistent with the proteinase being a mast cell constituent. The antiserum also cross-reacted with the major chymotrypsin-like proteinase isolated from normal dog skin and partially cross-reacted with human skin chymase. No cross-reaction was detected with rat chymase. The trypsin-like proteinase from dog mastocytoma tissue was similar to tryptase isolated from human skin. It had a similar subunit structure, was not inhibited by many protein proteolytic enzyme inhibitors, bound to heparin, and reacted strongly with antiserum against human tryptase. Antiserum against human tryptase also reacted with mast cells in skin sections prepared from normal dog skin. No immunocytochemical labeling of rat skin mast cells was observed with anti-human tryptase. These studies establish the presence of a trypsin-like and chymotrypsin-like proteinase in dog skin mast cells and provide immunological evidence which suggests that both proteinases are more closely related to human than rat mast cell proteinases. These immunological and biochemical relationships are important when comparing the roles of these proteinases in different animals.     

Structure based design of 4-(3-aminomethylphenyl)piperidinyl-1-amides: novel, potent, selective, and orally bioavailable inhibitors of betaII tryptase

Tryptase is a serine protease found almost exclusively in mast cells. It has trypsin-like specificity, favoring cleavage of substrates with an arginine (or lysine) at the P1 position, and has optimal catalytic activity at neutral pH. Current evidence suggests tryptase beta is the most important form released during mast cell activation in allergic diseases. It is shown to have numerous pro-inflammatory cellular activities in vitro, and in animal models tryptase provokes broncho-constriction and induces a cellular inflammatory infiltrate characteristic of human asthma. Screening of in-house inhibitors of factor Xa (a closely related serine protease) identified beta-amidoester benzamidines as potent inhibitors of recombinant human betaII tryptase. X-ray structure driven template modification and exchange of the benzamidine to optimize potency and pharmacokinetic properties gave selective, potent and orally bioavailable 4-(3-aminomethyl phenyl)piperidinyl-1-amides.     

High degree of conservation of the multigene tryptase locus over the past 150–200 million years of mammalian evolution

Activated mast cells release a number of potent inflammatory mediators including histamine, proteoglycans, cytokines, and serine proteases. The proteases constitute the majority of the mast cell granule proteins, and they belong to either the chymase or the tryptase family. In mammals, these enzymes are encoded by two different loci, the mast cell chymase and the multigene tryptase loci. In mice and humans, a relatively large number of tryptic enzymes are encoded from the latter locus. These enzymes can be grouped into two subfamilies, the group 1 tryptases, with primarily membrane-anchored enzymes, and the group 2 tryptases, consisting of the soluble mast cell tryptases. In order to study the appearance of these enzymes during vertebrate evolution, we have analyzed the dog, cattle, opossum, and platypus genomes and sought orthologues in the genomes of several bird, frog, and fish species as well. Our results show that the overall structure and the number of genes within this locus have been well conserved from marsupial to placental mammals. In addition, two relatively distantly related group 2 tryptase genes and several direct homologues of some of the group 1 genes are present in the genome of the platypus, a monotreme. However, no direct homologues of the individual genes of either group 1 or 2 enzymes were identified in bird, amphibian, or fish genomes. Our results indicate that the individual genes within the multigene tryptase locus, in their present form, are essentially mammal-specific.     

Heparin antagonists are potent inhibitors of mast cell tryptase

Tryptase may be a key mediator in mast cell-mediated inflammatory reactions. When mast cells are activated, they release large amounts of these tetrameric trypsin-like serine proteases. Tryptase is present in a macromolecular complex with heparin proteoglycan where the interaction with heparin is known to be essential for maintaining enzymatic activity. Recent investigations have shown that tryptase has potent proinflammatory activity, and inhibitors of tryptase have been shown to modulate allergic reactions in vivo. Many of the tryptase inhibitors investigated previously are directed against the active site. In the present study we have investigated an alternative approach for tryptase regulation. We show that the heparin antagonists Polybrene and protamine are potent inhibitors of both human lung tryptase and of recombinant mouse tryptase (mouse mast cell protease 6). Protamine inhibited tryptase in a competitive manner whereas Polybrene showed noncompetitive inhibition kinetics. Treatment of tetrameric, active tryptase with Polybrene caused dissociation into monomers, accompanied by complete loss of enzymatic activity. The present report thus suggests that heparin antagonists potentially may be used in treatment of mast cell-mediated diseases such as asthma.     

The mast cell-restricted tryptase mMCP-6 has a critical immunoprotective role in bacterial infections

Although it has been shown that mast cell-deficient mice have diminished innate immune responses against bacteria, the most important immunoprotective factors secreted from activated mast cells have not been identified. Mouse mast cell protease 6 is a tetramer-forming tryptase. This serine protease is abundant in the secretory granules and is exocytosed upon bacterial challenge. Here we have described the generation of a mast cell protease-6-null mouse. Our discovery that mice lacking this neutral protease cannot efficiently clear Klebsiella pneumoniae from their peritoneal cavities reveals an essential role for this serine protease, and presumably its human ortholog, in innate immunity.     

Anaphylatoxin binding and degradation by rat peritoneal mast cells. Mechanisms of degranulation and control.

Incubation of radiolabeled human C3a with rat peritoneal mast cells resulted in high levels of uptake and extensive degradation of the ligand. Both cell-bound and free radiolabeled human C3a underwent extensive degradation by rat mast cells even at 0 degrees C. We examined several protease inhibitors for their ability to prevent degradation of radiolabeled human C3a by the rat mast cells. The inhibitors PMSF, chymostatin, and soybean trypsin inhibitor were most effective in preventing radiolabeled human C3a degradation. Degradation of the cell-bound ligand was totally inhibited only by PMSF. These compounds are effective inhibitors of a chymotrypsin-like enzyme (chymase) extracted from rat mast cells. Chemical cross-linking of radiolabeled human C3a to surface components on the rat mast cells, in the presence of PMSF, revealed one major and two minor bands. The mast cell component in both the major and minor bands proved to be chymase-associated based on a direct comparison with purified chymase isolated from rat mast cells. However, neither antichymase antibody nor chymase inhibitors influenced the degranulating activity of C3a on rat mast cells that occur independently of the C3a-chymase interactions. We conclude that there are neither specific C3a-binding sites on rat mast cells nor specific receptors whose occupancy leads to cellular activation. Although human C3ades Arg is inactive on guinea pig ileal and lung tissue, it binds to and induces degranulation of rat mast cells, as well as enhances vascular permeability in rat skin, at concentrations nearly identical to that of intact C3a. The fact that both C3a and C3ades Arg stimulated mast cell activation, at concentrations in excess of 10(-6) M, argues against specific binding sites for the anaphylatoxin on rat mast cells. It is proposed that the cationic C3a molecule activates rat mast cells in a secretory and nonlytic manner by a nonspecific mechanism similar to that of other polybasic compounds.     

Activation of paracrine TGF-beta1 signaling upon stimulation and degranulation of rat serosal mast cells: a novel function for chymase.

As a source of transforming growth factor beta1 (TGF-beta1), mast cells have been implicated as potential effector cells in many pathological processes. However, the mechanisms by which mast cells express, secrete, and activate TGF-beta1 have remained vague. We show here by means of RT-PCR, immunoblotting, and immunocytochemistry that isolated rat peritoneal mast cells synthesize and store large latent TGF-beta1 in their chymase 1-containing secretory granules. Mast cell stimulation and degranulation results in rapid secretion of the latent TGF-beta1, which is converted by chymase 1 into an active form recognized by the type II TGF-beta serine/threonine kinase receptor (TbetaRII). Thus, mast cells secrete active TGF-beta1 by a unique secretory mechanism in which latent TGF-beta1 and the activating enzyme chymase 1 are coreleased. The activation of latent TGF-beta1 specifically by chymase was verified using recombinant human latent TGF-beta1 and recombinant human chymase. In isolated TbetaRI- and TbetaRII-expressing peritoneal macrophages, the activated TGF-beta1 induces the expression of the plasminogen activator inhibitor 1 (PAI-1), whereas in the mast cells, the levels of TbetaRI, TbetaRII, and PAI-1 expression were below detection. Selective stimulation of mast cells in vivo in the rat peritoneal cavity leads to rapid overexpression of TGF-beta1 in peritoneal mast cells and of TbetaRs in peritoneal macrophages. These data strongly suggest that mast cells can act as potent paracrine effector cells both by secreting active TGF-beta1 and by enhancing its response in target cells.     

Identification of a cathepsin G-like proteinase in the MCTC type of human mast cell

Human mast cells can be divided into two subsets based on serine proteinase composition: a subset that contains the serine proteinases tryptase and chymase (MCTC), and a subset that contains only tryptase (MCT). In this study we examined both types of mast cells for two additional proteinases, cathepsin G and elastase, which are the major serine proteinases of neutrophils. Because human mast cell chymase and cathepsin G are both chymotrypsin-like proteinases, the properties of these enzymes were further defined to confirm their distinctiveness. Comparison of their N-terminal sequences showed 30% nonidentity over the first 35 amino acids, and comparison of their amino acid compositions demonstrated a marked difference in their Arg/Lys ratios, which was approximately 1 for chymase and 10 for cathepsin G. Endoglycosidase F treatment increased the electrophoretic mobility of chymase on SDS gels, indicating significant N-linked carbohydrate on chymase; no effect was observed on cathepsin G. Immunoprecipitation and immunoblotting with specific antisera to each proteinase revealed little, if any, detectable cross-reactivity. Immunocytochemical studies showed selective labelling of MCTC type mast cells by cathepsin G antiserum in sections of human skin, lung, and bowel. No labeling of mast cells by elastase antiserum was detected in the same tissues, or in dispersed mast cells from lung and skin. A protein cross-reactive with cathepsin G was identified in extracts of human skin mast cells by immunoblot analysis. This protein had a slightly higher Mr (30,000) than the predominant form of neutrophil cathepsin G (Mr 28,000), and could not be separated from chymase (Mr 30,000) by SDS gel electrophoresis because of the size similarity. Using casein, a protein substrate hydrolyzed at comparable rates by chymase and cathepsin G, it was shown that about 30% of the caseinolytic activity in mast cell extracts was sensitive to inhibitors of cathepsin G that had no effect on chymase. Hydrolytic activity characteristic of elastase was not detected in these extracts. These studies indicate that human MCTC mast cells may contain two different chymotrypsin-like proteinases: chymase and a proteinase more closely related to cathepsin G, both of which are undetectable in MCT mast cells. Neutrophil elastase, on the other hand, was not detected in human mast cells by our procedures.     

Pericellular substrates of human mast cell tryptase: 72,000 dalton gelatinase and fibronectin.

Migrating cells degrade pericellular matrices and basement membranes. For these purposes cells produce a number of proteolytic enzymes. Mast cells produce two major proteinases, chymase and tryptase, whose physiological functions are poorly known. In the present study we have analyzed the ability of purified human mast cell tryptase to digest pericellular matrices of human fibroblasts. Isolated matrices of human fibroblasts and fibroblast conditioned medium were treated with tryptase, and alterations in the radiolabeled polypeptides were observed in autoradiograms of sodium dodecyl sulphate polyacrylamide gels. It was found that an M(r) 72,000 protein was digested to an M(r) 62,000 form by human mast cell tryptase while the plasminogen activator inhibitor, PAI-1, was not affected. Cleavage of the M(r) 72,000 protein could be partially inhibited by known inhibitors of tryptase but not by aprotinin, soybean trypsin inhibitor, or EDTA. Fibroblastic cells secreted the M(r) 72,000 protein into their medium and it bound to gelatin as shown by analysis of the medium by affinity chromatography over gelatin-Sepharose. The soluble form of the M(r) 72,000 protein was also susceptible to cleavage by tryptase. Analysis using gelatin containing polyacrylamide gels showed that both the intact M(r) 72,000 and the M(r) 62,000 degraded form of the protein possess gelatinolytic activity after activation by sodium dodecyl sulphate. Immunoblotting analysis of the matrices revealed the cleavage of an immunoreactive protein of M(r) 72,000 indicating that the protein is related to type IV collagenase. Further analysis of the pericellular matrices indicated that the protease sensitive extracellular matrix protein fibronectin was removed from the matrix by tryptase in a dose-dependent manner. Fibronectin was also susceptible to proteolytic degradation by tryptase. The data suggest a role for mast cell tryptase in the degradation of pericellular matrices.