Purification and characterization of human skin mast cells. Evidence for human mast cell heterogeneity

Our previous studies of human lung and intestinal mast cells failed to show the heterogeneity found among mast cells in murine species. Recently, we and others have developed techniques for the enzymatic dispersion of human neonatal skin mast cells. In addition, we are now able to make single cell suspensions of mast cells from adult skin and to purify these cells to near homogeneity. Comparative studies of mast cells from these several sources have uncovered several major differences among them. Adult and neonatal skin mast cells themselves differ in that the former are 10-fold less sensitive to goat anti-human IgE, with maximal release occurring at 3.0 and 0.3 microgram/ml, respectively. Skin mast cells also differ in optimal temperature for release: adult mast cells respond maximally at 23 to 30 degrees C and neonatal cells at 37 degrees C. Skin mast cells from both sources are dramatically different from lung and intestinal mast cells in two aspects. First, skin mast cells are quite responsive to several stimuli--morphine sulfate (10(-4) to 10(-6) M), substance P (10(-5) to 10(-7) M), compound 48/80 (10 to 0.1 microgram/ml), f-Met peptide (10(-6) M), and C5a (10(-8) M)--to which the other mast cells fail to respond. Second, although stimulated skin mast cells produce prostaglandin D2, little leikotriene C4, if any, is generated, unlike lung or intestinal mast cells. These differences in inflammatory potential among human mast cells from various sites have important implications for the management of allergic and inflammatory responses.     

The fibrinogenolytic activity of purified tryptase from human lung mast cells

The capacity of purified tryptase from human lung mast cells to metabolize human fibrinogen, fibrin, and plasminogen was evaluated. Tryptase (5 micrograms/ml) inactivated the thrombin-induced clotting activity of fibrinogen (100 micrograms/ml) with essentially similar t 1/2 values of 4.6 min in the absence of heparin and 5.8 min in the presence of heparin (20 micrograms/ml) that were not appreciably different than with lysine-Sepharose-purified plasmin (5 micrograms/ml). Fibrinogen treated with tryptase together with heparin lost all detectable clotting activity by 4 hr at 37 degrees C, whereas fibrinogen treated with tryptase alone resulted in destruction of only 80% of fibrinogen clotting equivalents after 16 hr. Tryptase alone was observed to cleave only the alpha-chains of fibrinogen by electrophoresis of tryptase-treated, denatured, and reduced fibrinogen in polyacrylamide gradient gels. Tryptase together with heparin cleaved first the alpha-chain and then the beta-chain, the latter cleavage corresponding to complete loss of fibrinogen clotting activity by 4 hr. No fibrinogen fragments with anticoagulant activity were generated by tryptase. In contrast, plasmin left no residual clotting activity after 4 hr of incubation and generated fibrinogen fragments with anticoagulant activity. Plasmin sequentially cleaved the alpha, beta, and gamma subunits of fibrinogen. Tryptase alone (6 micrograms/ml) or together with heparin (20 micrograms/ml) failed to activate plasminogen (0.6 mg/ml) after a 60-min incubation at 37 degrees C. Addition of urokinase to tryptase-treated or untreated plasminogen resulted in essentially identical plasmin activities (0.32 and 0.34 U/ml, respectively), indicating that tryptase neither activates nor destroys plasminogen. Tryptase (700 ng) also failed to substantially solubilize cross-linked fibrin (2.6 micrograms) or the corresponding amount of fibrinogen bound to plastic microtiter plates with or without heparin. The failure to solubilize fibrinogen and, possibly, fibrin is consistent with the observation that the apparent m.w. by SDS polyacrylamide gel electrophoresis of unreduced fibrinogen is not appreciably altered by prior treatment with tryptase, even though cleavage of alpha-and beta-chains is revealed after reduction. Fibrinogenolysis by tryptase complements other mast cell mediators with anticoagulant properties such as heparin and suggests a significant prevention of coagulation by activated mast cells.     

The allosteric effect of salt on human mast cell tryptase

The inhibitory effect of potassium chloride and ammonium sulphate on purified human skin tryptase and bovine trypsin was studied enzyme-kinetically, using Z-Gly-Pro-Arg-pNA, Z-Gly-Pro-Arg-AMC, benzoyl-L-arginine ethyl ester (BAEE) and tosyl-L-arginine methyl ester (TAME) as substrates. With increasing salt concentrations, the curve of reaction velocity vs. substrate concentration changed from hyperbolic to sigmoidal when anilide substrates (Z-Gly-Pro-Arg-pNA or -AMC) were used. Only the Km value increased, while the Vmax value remained unchanged. The trend was similar with BAEE or TAME as the substrates. However, the effect of salt on the hydrolysis of these ester substrates was not as strong as on the hydrolysis of anilide substrates, and sigmoidal kinetics were not observed even at the highest KCl concentration (0.7 M) used. Heparin, used as a stabilizer, had no influence on this phenomenon, but it did slightly decrease the apparent Km and Vmax values in low-salt conditions. By comparison, trypsin was not as strongly affected by salt as tryptase, and the inhibition type was mixed competitive and non-competitive. The present results indicate that the salt acts on tryptase as an allosteric effector, and this should be carefully considered when enzyme kinetic parameters and enzyme activity of skin tryptase are measured.     

Rat mast cell tryptase

Rat mast cell tryptase is located largely if not totally in the cell's secretory granules. When the active site reagent [3H]diisopropyl fluorophosphate was used to label tryptase and chymase simultaneously, the ratio of tryptase:chymase active sites was determined to be 0.05. In comparison to chymase and tryptase in other species and chymase in the rat, rat tryptase is poorly bound to the granule matrix as evidenced by (1) its release parallel to histamine on induction of secretion and (2) its appearance in the supernatant when isolated granules were stripped of their membranes with hypotonic medium. Tryptase on release from the granule is moderately stable at a pH of 5.0 but unstable at pH 7.5, the pH that the enzyme encounters on secretion from the cell. These several properties indicate that the role of rat mast cell tryptase extracellularly is likely to differ greatly from that of chymase.     

The effect of tryptase from human mast cells on human prekallikrein

Tryptase, the dominant protease in human mast cells, was examined for its effect on human prekallikrein. Tryptase in the presence and absence of heparin failed to activate prekallikrein as shown in a spectrophotometric assay for kallikrein employing benzoy 1-pro-phe-arg-p-nitroanilide. Treated prekallikrein was converted to active kallikrein by bovine trypsin. Prekallikrein cleavage products were analyzed by electrophoresis in polyacrylamide gels under denaturing conditions (+/- reduction). Tryptase caused no apparent cleavage under conditions where trypsin caused complete cleavage. Thus, tryptase, which has previously been shown to lack kallikrein and kininase activities, neither activates nor destroys prekallikrein.     

Interactions of human mast cell tryptase with biological protease inhibitors.

Tryptase from human mast cells has been shown (in vitro) to catalyze the destruction of fibrinogen and high-molecular-weight kininogen as well as the activation of C3a and collagenase. Although large amounts of tryptase are released in tissues by degranulating mast cells and levels as high as 1000 ng/ml have been measured in the circulation following systemic anaphylaxis, no specific physiologic inhibitor has yet been found for the protease. The current work tests several more inhibitors for their effects on tryptase and examines any effect of tryptase on these inhibitors. First, antileukoprotease and low-molecular-weight elastase inhibitor from human lung and hirudin and antithrombin III had no effect on tryptase activity in vitro. Second, the possibility that tryptase, being insensitive to the effects of inhibitors, might instead destroy them was also considered. Tryptase failed to cleave and inactivate antileukoprotease, low-molecular-weight elastase inhibitor, alpha 1 protease inhibitor, alpha 2 macroglobulin, and antithrombin III. Third, based on the knowledge that tryptase stability is regulated by its interaction with heparin, antithrombin III was used as a model heparin-binding protein to demonstrate that a protein competitor for heparin-binding sites, presumably by displacement of tryptase, destabilizes this enzyme. Conversely, tryptase, in excess, blocked the binding of antithrombin III to heparin, thereby attenuating the heparin-mediated inhibition of thrombin by antithrombin III.     

Histochemical heterogeneity of dispersed human lung mast cells.

Cytocentrifuge preparations of enzymatically dispersed human lung parenchymal mast cells were examined by light microscopy after fixation in either Mota's basic lead acetate or 10% neutral buffered formalin followed by toluidine blue staining at pH 0.5. Fixation in Mota's basic lead acetate allowed detection of all mast cells. However, after formalin fixation only 10.8 +/- 1.3%, range 4.7 to 17%, n = 8 remained detectable (i.e., formalin "resistant"). Therefore, the vast majority of human lung mast cells lose their metachromatic staining after formalin fixation (i.e., are formalin "sensitive"). Mast cells were then separated on the basis of diameter by countercurrent elutriation and on the basis of density by discontinuous Percoll gradients. Histochemically distinct populations of mast cell types emerged in all lungs studied. The proportion of formalin-resistant mast cells increased as a function of diameter: less than 5% at diameters of less than or equal to 11 mu and densities less than or equal to 1.063 g/ml, to 30 to 40% in cells of diameters greater than or equal to 16 mu and densities greater than or equal to 1.100 g/ml. Maximum anti-IgE challenge of nearly homogeneous formalin-sensitive mast cells (94.3 +/- 2.1% purity, n = 6) caused the generation of both leukotriene C4 (64.6 +/- 26.4 pg/mast cell) and PGD2 (114.8 +/- 37.5 pg/mast cell). Six- to eight-fold enrichment of formalin-resistant mast cells did not significantly alter the histamine release response or profiles of arachidonate metabolites. Similar results were obtained for the nonimmunologic stimulus ionophore A23187. We conclude that two histochemically distinct subpopulations, of mast cells are present in human lung suspensions. Although formalin-sensitive cells account for almost 90% of lung mast cells, formalin-resistant cells are separable by their large diameters and higher densities. Both subtypes show similar histamine release responses and arachidonate oxidation profiles.     

Regulation of tryptase from human lung mast cells by heparin. Stabilization of the active tetramer

Tryptase was shown to be stabilized as an enzymatically active tetramer by association with heparin and dissociated to inactive monomers in the absence of heparin at 37 degrees C in physiologic buffer and in plasma. There was a 50% loss of tryptase activity at 37 degrees C by 6-8 min in both physiologic buffer and plasma. When heparin glycosaminoglycan was present, tryptase retained nearly full activity for 2 h in buffer and in plasma. Tryptase activity also decayed under standard assay conditions in the presence of synthetic ester and peptide substrates unless bound to heparin. That tryptase is bound to heparin at the pH and physiologic NaCl concentrations employed was shown by chromatography of tryptase on heparin-agarose, gel filtration, and velocity sedimentation. Elution of tryptase from heparin-agarose occurred at 0.8 M NaCl. Maximal stabilization of tryptase by heparin occurred at a weight ratio to tryptase that was equal to or greater than unity. Kcat/Km ratios for tryptase-heparin at 0.15 M NaCl and 37 degrees C were 0.9 X 10(6) s-1 M-1 for tosyl-L-Gly-Pro-Lys-p-nitroanilide and 1.7 X 10(6) s-1 M-1 for p-tosyl-L-arginine methyl ester and are among the highest reported for tryptic enzymes. The mechanism of heparin-dependent stabilization of tryptase was not due to indirect ion binding properties of heparin and was analyzed by Superose 12 high performance liquid chromatography. Active enzyme eluted with an apparent Mr of 132,000 +/- 10,000 (n = 3, +/- S.D.), whereas tryptase inactivated by incubation without heparin eluted with an apparent Mr of 34,000. The tetrameric structure of diisopropyl fluorophosphate-inhibited tryptase was also preserved after incubation with heparin at 37 degrees C but was reduced to monomeric subunits after incubation without heparin. That no appreciable degradation of tryptase occurs under conditions that cause dissociation of subunits was directly shown by electrophoresis in sodium dodecyl sulfate-polyacrylamide gels. Two different subunits of 34,000 and 33,000 Mr (after reduction) present in the intact enzyme (calculated to be 134,000 Mr) were also detected unchanged after inactivation of tryptase by dissociation of its subunits. Thus, the selective localization and association of heparin and tryptase in the human mast cell secretory granule most likely plays a major role in the regulation of tryptase after secretion.     

Human skin tryptase: purification, partial characterization and comparison with human lung tryptase

Human skin tryptase was isolated using stepwise low- and high-salt extraction and further purified 448-fold with 33% yield using octyl-Sepharose CL-4B hydrophobic affinity chromatography, Sephacryl S-200 gel filtration and finally octyl-Sepharose CL-4B or cellulose phosphate ion exchange chromatography. The skin tryptase, which has an apparent Mr of 120,000 by gel filtration in high-salt buffer, consisted of polypeptide chains of Mr 34,000 and 38,000 when resolved on SDS gels. Both polypeptide chains, labelled with [3H]diisopropyl fluorophosphate, indicated that they were representative of subunits and that the native proteinase was an aggregate of subunits. However, in some preparations only one band with Mr 34,000 was seen. In low-salt buffer the enzyme was labile and at least 1.4 M KCl was needed to keep the enzyme stabile when incubated at 37 degrees C for 30 min. Heparin glycosaminoglycan partially stabilized the tryptase but addition of protein (e.g. albumin, 80 micrograms/ml) to the tryptase-heparin mixture was needed to keep the enzyme stabile. Tryptases purified by exactly the same method from human lung tissue and from human skin had identical molecular size in gel filtration and in SDS-polyacrylamide gel electrophoresis. They also revealed identical enzyme kinetic parameters with several synthetic peptide substrates. The inhibition profile was identical for both enzymes, and they also crossreacted completely in immunodiffusion plates. These studies strongly indicate that mast cells found in skin as well as lung contain closely related, possible identical trypsin-like proteinases.     

Evaluation of human peripheral blood leukocytes for mast cell tryptase

Murine monoclonal and goat polyclonal antibodies against tryptase, the dominant neutral protease and protein component in secretory granules of human mast cells, were used to assess the presence of tryptase in peripheral leukocytes. Carnoy's fluid-fixed cytocentrifuge preparations of enriched populations of lymphocytes, monocytes, eosinophils, and neutrophils showed no reactivity with anti-tryptase antibodies by a sensitive indirect immunoperoxidase procedure. Dispersed human lung mast cells showed strong granular cytoplasmic staining with both antibodies, whereas only approximately 50% of the peripheral blood basophils detectable with Wright's stain were detected with anti-tryptase antibodies, and these showed a staining pattern that was faint, granular, and cytoplasmic at high concentrations of antibody. At lower antibody concentrations mast cell staining was still intense, whereas basophils were not stained. Extracts of neutrophils and lymphocytes of up to 90% purity had undetectable amounts of tryptase by an ELISA sandwich immunoassay, as well as undetectable enzymatic activity with tosyl-L-gly-pro-lys-p-nitroanilide (a sensitive substrate for tryptase) in the presence of soybean trypsin inhibitor. Extracts of basophil-enriched (6 to 50% purity) preparations contained 0.046 +/- 0.013 pg of tryptase per basophil by the immunoassay along with 2 X 10(-9) +/- 0.8 X 10(-9) U of tryptase-like enzyme activity per basophil, compared with corresponding values of 12 pg, 480 X 10(-9) U of tryptase per human lung mast cell. Thus very small amounts of tryptase are present in human basophils (approximately 0.4% of that found in mast cells), but not in other peripheral leukocytes.     

Generation of C3a anaphylatoxin from human C3 by human mast cell tryptase

Tryptase, the dominant neutral protease of human pulmonary mast cell secretory granules, has the capacity in vitro to generate C3a anaphylatoxin from purified human C3. Only the alpha-chain of C3 is cleaved, and major fragments with apparent m.w. of 105,000, 39,500, 34,000, 29,000, and 9000 are detected by sodium dodecyl sulfate (SDS) polyacrylamide gel electrophoresis under reducing conditions. Fragments of 34,000 and 9000 m.w. are detected without reduction. A portion of the 9000 m.w. protein corresponds to C3a by virtue of its co-migration in SDS polyacrylamide gels with purified C3a and with trypsin-generated C3a, by its detection in a radioimmunoassay for C3a, and by its contractile activity on the guinea pig ileum bioassay. In the presence of heparin, another component of the mast cell secretory granule, the rate of appearance and the distribution of C3 cleavage fragments as assessed in SDS polyacrylamide gels are not appreciably changed with the exception that no C3a material can be detected in the SDS polyacrylamide gels or by radioimmunoassay and bioassay of the unresolved reaction mixture. Enhanced catabolism of authentic C3a by tryptase occurs in the presence of heparin and by analogy when C3a is generated from C3 by tryptase in the presence of heparin. Whereas tryptase secreted by activated human mast cells may generate C3a, a potentially important additional mediator of immediate hypersensitivity events, the concomitant release of heparin may serve to down-regulate C3a irrespective of its mechanism of generation.     

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.     

Inactivation of human high molecular weight kininogen by human mast cell tryptase

Tryptase, the major neutral protease of human pulmonary mast cell secretory granules, rapidly inactivates human high m.w. kininogen (HMWK) in vitro. HMWK (5600 nM) lost 50% of its capacity to release kinin in response to kallikrein after a 5-min incubation with tryptase (31 nM), even though kinin activity was neither generated nor, when bradykinin was incubated with tryptase, destroyed by tryptase. The procoagulant activity of HMWK (51 nM) and the purified procoagulant chain (40 nM) that is derived from HMWK were each 72% inactivated after 7 min of incubation with tryptase (0.04 nM and 0.02 nM, respectively). Human urinary and pancreatic kallikrein did not inactivate this procoagulant activity under conditions in which kinin generation occurs. Complete cleavage of native single-chain HMWK by tryptase occurred in less than 10 min as analyzed by electrophoresis in sodium dodecyl sulfate polyacrylamide slab gels. The major products formed during the initial 2 min were proteins of 100,000 and 95,000 apparent m.w., and by 10 to 30 min were fragments of 74,000 and 67,000 apparent m.w. Reduction of these cleavage products yielded two major fragments of 67,000 and 66,000 apparent m.w. that were both present by 0.17 min. The presence of lower m.w. products, thought to be primarily from the carboxy-terminal procoagulant region of HMWK, were also detected with and without reduction. The capacity of tryptase to inactivate HMWK is consistent with the ability of other mast cell-derived mediators, such as heparin proteoglycan and prostaglandin D2, to suppress blood coagulation and thrombosis, and may play an important role in the biology of mast cell-dependent events in vivo.     

Biology of mast cell tryptase. An inflammatory mediator

In 1960, a trypsin-like activity was found in mast cells [Glenner GG & Cohen LA (1960) Nature 185, 846-847] and this activity is now commonly referred to as 'tryptase'. Over the years, much knowledge about mast cell tryptase has been gathered, and a recent (18 January 2006) PubMed search for the keywords 'tryptase + mast cell*' retrieved 1661 articles. However, still very little is known about its true biological function. For example, the true physiological substrate(s) for mast cell tryptase has not been identified, and the potential role of tryptase in mast cell-related disease is not understood. Mast cell tryptase has several unique features, with perhaps the most remarkable being its organization into a tetrameric state with all of the active sites oriented towards a narrow central pore and its consequent complete resistance towards endogenous macromolecular protease inhibitors. Much effort has been invested to elucidate these properties of tryptase. In this review we summarize the current knowledge of mast cell tryptase, including novel insights into its possible biological functions and mechanisms of regulation.     

Activation of latent rheumatoid synovial collagenase by human mast cell tryptase

The functional role of mast cells in rheumatoid synovium was investigated by assessing the ability of mast cell tryptase to activate latent collagenase derived from rheumatoid synoviocytes. Tryptase, a mast cell neutral protease, was demonstrated in situ to reside in rheumatoid synovial mast cells, by an immunoperoxidase technique using a mouse mAb against tryptase, and in vitro to be released by dispersed synovial mast cells after both immunologic and nonimmunologic challenge. Each rheumatoid synovial mast cell contains an average of 6.2 pg of immunoreactive tryptase and the percent release values of this protease correlated with those of histamine (r = 0.58, p less than 0.01). The ability of purified tryptase to promote collagenolysis was demonstrated in a dose-dependent fashion using latent collagenase derived from rheumatoid synovium, synovial fluid, IL-1-stimulated cultured synoviocytes, and partially purified latent collagenase derived from conditioned media, with between 10 and 92% of the collagen substrate degraded. [3H] Collagen, treated with tryptase-activated latent collagenase, was subjected to electrophoresis on SDS polyacrylamide gels and autoradiography showed the collagen degradation pattern (A, B) characteristically produced by collagenase. Mast cell lysates also activated synovial latent collagenase yielding 24% digestion of collagen substrate. This activator in mast cell lysates could be inhibited by diisopropylflurophosphate or by immunoadsorption of tryptase. Thus, mast cells may activate metalloproteinases and play a role in the catabolism of collagen that occurs in rheumatoid synovium.     

The human mast cell tryptase tetramer: a fascinating riddle solved by structure

Tryptases, the predominant proteins of human mast cells, have been implicated as pathogenetic mediators of allergic and inflammatory conditions, most notably asthma. Until recently, the fascinating properties that distinguish tryptases among the serine proteinases, particularly their activity as a heparin-stabilized tetramer, resistance to most proteinaceous inhibitors, and preference for peptidergic over macromolecular substrates presented a riddle. This review solves this riddle with the help of the crystal structure of the human beta(2)-tryptase tetramer, but also indicates controversies between the unique quaternary architecture and some experimental data.     

Human lung mast cell tryptase fails to activate procollagenase or degrade proteoglycan

Pig synovial and human skin fibroblast procollagenases were treated with highly purified tryptase, the major proteinase of human mast cells, to determine whether this trypsin-like proteinase could activate the latent form of collagenase and so be involved in connective tissue breakdown. No significant activation of either human or pig procollagenase was found, but the highest concentration of tryptase partially destroyed procollagenase. Tryptase did not degrade type I collagen or proteoglycan. These data indicate that human mast cell tryptase does not contribute to connective tissue breakdown via procollagenase activation or via proteoglycan degradation.     

Expression and characterization of recombinant mast cell tryptase

Tryptase, a serine protease, is the major protein component in mast cells. In an animal model of asthma, tryptase has been established as an important mediator of inflammation and late airway responses induced by antigen challenge. Human tryptase is notable for its tetrameric structure, requirement of heparin for stability, and resistance to endogenous inhibitors. Human protryptase was expressed as a recombinant protein in Pichia pastoris. The recombinant protein consisted of two forms of protryptase, one containing the entire propeptide and the other containing only the Val-Gly dipeptide at its amino terminus. Isolation of active recombinant tryptase required a two column purification protocol and included a heparin- and dipeptidyl peptidase I-dependent activation step. Purified recombinant tryptase migrated as a tetramer on a gel filtration column and displayed kinetic parameters identical to those of a native tryptase obtained from HMC-1 cells, a human mast cell line. Recombinant and HMC-1 tryptase exhibited comparable sensitivities to an array of protein and low-molecular-weight inhibitors, including one that is highly specific for tryptase (APC-1167). Similarly, the recombinant enzyme cleaved both alpha- and beta-chains of fibrinogen to generate fibrinogen fragments indistinguishable from those generated by HMC-1-derived tryptase. Thus, recombinant tryptase expressed in P. pastoris displays physical and enzymatic properties essentially identical to the native enzyme. This system provides a cost-effective and easy to manipulate expression system that will enable the functional characterization of this unique enzyme.     

Enzyme histochemistry of rat mast cell tryptase

Fixation and staining conditions for rat mast cell tryptase and its histochemical distribution in different rat tissues were investigated. Prostate, skin, lung, gut, stomach and salivary glands were fixed in either aldehyde or Carnoy fixatives and then frozen or embedded in paraffin wax. Preservation of tryptase enzymic activity against peptide substrates required aldehyde fixation and frozen sectioning. Of the peptide substrates examined, z-Ala-Ala-Lys-4-methoxy-2-naphthylamide and z-Gly-Pro-Arg-4-methoxy-2-naphthylamide proved the most effective for the demonstration of tryptase. Double staining by enzyme cytochemistry followed by immunological detection of tryptase showed that, in all tryptase-containing mast cells, the enzyme is at least in part active. Conventional dye-binding histochemistry was used to confirm the identity of mast cells. Aldehyde-fixed mucosal mast cells required a much shorter staining time with Toluidine Blue if tissue sections were washed directly in t-butyl alcohol. Double staining by enzyme cytochemistry and dye binding showed that tryptase is absent from mucosal and subepidermal mast cells, which are also smaller in size and appear to contain fewer granules than connective tissue mast cells. This study demonstrates that rat mast cell tryptase, unlike tryptases in other species, is a soluble enzyme. It is stored in an active form and is absent from some mast cell subpopulations in mucosa, skin and lung. © 1998 Chapman & Hall