Evaluation of equilibrium constants for the binding of N-acetyl-L-tryptophan to monomeric and dimeric forms of alpha-chymotrypsin

The binding of N-acetyl-tryptophan to the monomeric and dimeric forms of alpha-chymotrypsin in I = 0.2 acetate-chloride buffer, pH 3.86, has been studied quantitatively. Equilibrium sedimentation studies in the absence of inhibitor yielded a dimerization constant of 3.5 L/g. This value was confirmed by frontal gel chromatography of the enzyme on Bio-Gel P-30, which was also used to establish that N-acetyl-L-tryptophan binds preferentially to monomeric enzyme. From kinetic studies of competitive inhibition with N-acetyl-L-tryptophan ethyl ester as substrate, an equilibrium constant of 1300 M-1 was determined for the binding of N-acetyl-L-tryptophan to monomeric alpha-chymotrypsin. An intrinsic binding constant of 250 M-1 for the corresponding interaction with dimeric enzyme was calculated on the basis of these results and binding data obtained with concentrated (18.5 g/L) alpha-chymotrypsin. The present results refute earlier claims for exclusive binding of competitive inhibitors to monomer and also those for equivalence of inhibitor binding to monomeric and dimeric forms of alpha-chymotrypsin.     

Stability and activity modulation of chymotrypsins in AOT reversed micelles by protein-interface interaction: interaction of alpha-chymotrypsin with a negative interface leads to a cooperative breakage of a salt bridge that keeps the catalytic active conformation (Ile16-Asp194)

The stability of alpha-chymotrypsin and delta-chymotrypsin was studied in reversed micelles of sodium bis(2-ethylhexyl)sulfosuccinate (AOT) in isooctane. alpha-Chymotrypsin is inactivated at the interface and at the water pool, while delta-chymotrypsin is inactivated only at the water pool. The mechanism of inactivation at the interface is related to the interaction of N-terminal group alanine 149 (absent in delta-chymotrypsin) with the negative interface. The dependence of enzyme activity on water content of these two enzymes in reversed micelles of AOT is also related with the interface interaction, since delta-chymotrypsin does not have a bell-shaped curve as observed for alpha-chymotrypsin.     

N-Acetylbenzotriazole as a protein reagent. Specific behaviour towards delta-chymotrypsin.

When N-[14C] acetylbenzotriazole, presented here as a new agent for the acetylation of proteins, reacted at pH 8 and 25 degrees C with delta-chymotrypsin, 15 amino groups (the epsilon-amino groups of lysing residues and the alpha-amino terminus of half-cystine-1) and two phenolic groups (those of the two exposed tyrosine residues) were acetylated with respective pseudo first-order constants of 0.056 +/- 0.003 and 0.15 +/- 0.03 min(-1). Surprisingly, in contrast with the acetic anhydride reaction, the alpha-amino group of Ile-16 was found to be not acetylated as shown by N-terminus determination and activity measurements: the modified delta-chymotrypsin (or acetylated delta-chymotrypsin) was fully active after neutral dialysis. Only a transient inactivation due to the incorporation of one [14C] acetyl group per mole of catalytic site was observed. The kinetic constant found for reactivation at pH 8.5 was 0.315 +/- 0.005 min(-1) at 25 degrees C. The enzyme-catalyzed hydrolysis of N-acetylbenzotriazole was described by a k(cat) value of 0.093 +/- 0.005 min(-1) at pH 7 and 25 degrees C. Circular dichroism changes observed at 230 nm during the reaction at pH 8.5, of acetylated delta-chymotrypsin with N-acetylbenzotriazole indicated a total conversion of the amount of enzyme molecules which were in the 'inactive' or 'alkaline' conformation at this pH, into the 'active' or 'neutral' one. Benzotriazole alone was unable to induce such a conformational change. The rate constant of the reverse structural process from the 'neutral' to the 'alkaline' conformation was 0.32 +/- 0.02 min(-1): identical to that of the deacetylation of the catalytic site. Thus, the unusual lack of acetylation of Ile-16 alpha-amino group during delta-chymotrypsin treatment with N-acetylbenzotriazole is interpreted as a stabilization of the enzyme 'neutral' conformation where the Ile-16 alpha-amino group is buried, thus inaccessible to the reagent. The properties of the delta-chymotrypsin modification using N-acetylbenzotriazole led to practical uses: direct spectrophotometric titration of chymotrypsin operational normality at pH 7 and rapid preparation of acetylated delta-chymotrypsin. As a protein reagent, N-acetylbenzotriazole is particularly interesting because of its reactivity towards amino and phenolic groups of amino acid residues, its stability at acid pH, i.e., k(hydrolysis=7.38 X 10(-3) min(-1) at 25 degrees C [Ravaux et al. (1971) Tetrahedron Letters, 4013-4015] and its aromaticity, responsible for optical properties.     

Acid proteases. II. Fluorescence study of the interaction of Cladosporium acid protease with glycyl-DL-norleucine methyl ester in the presence of cupric ions.

Glycyl-DL-norleucine methyl ester (GN), a diazoacetyl-DL-norleucine methyl ester (DAN) analog, in the presence of cupric ions was found to partially quench the protein fluorescence of acid protease from Cladosporium sp. No. 45-2, and cupric ions were also found to quench the fluorescence. These quenchings were pH-dependent. GN alone did not quench the fluorescence of the enzyme. The interaction between the enzyme and GN in the presence of cupric ions was studied statically at pH 5.4 in terms of fluorescence change. The dissociation constant, Kd, of the enzyme-GN complex in the presence of a 20-fold molar excess of cupric ions (0.08 mM) determined by fluorescence titration at 30 degrees C (Kd = 1.86 mM) was in good agreement with that obtained for GN from kinetics of inhibition of DAN-induced inactivation in the presence of a 20-fold molar excess of cupric ions at 30 degrees C (KA = 1.94 mM) (Kanazawa, H. (1977) J. Biochem. 81, 1739-1744). At various concentrations of cupric ions, no change of Kd was found. These results suggest that cupric ions are attracted to a negatively charged carboxyl group responsible for the formation of the enzyme-GN complex.     

Comparative studies of the specificities of α-chymotrypsin and subtilisin BPN′. Studies with flexible and `locked'' substrates

Subtilisin BPN' hydrolysed N-acetyl-l-3-(2-naphthyl)-alanine methyl ester, N-acetyl-l-leucine methyl ester and N-acetyl-l-valine methyl ester, faster than alpha-chymotrypsin. Of eight ;locked' substrates tested, only methyl 5,6-benzindan-2-carboxylate was hydrolysed faster by subtilisin, whereas the other esters were better substrates for chymotrypsin. Compared with the values for chymotrypsin, the stereospecific ratios during the hydrolysis of the optically active locked substrates by subtilisin were decreased by one and two orders of magnitude for bi- and tri-cyclic substrates respectively. The polar groups adjacent to the alpha-carbon atom of locked substrates did not contribute significantly to the reactivity of the more active optical isomers, but had a detrimental effect on the less active antipodes during hydrolysis by both the enzymes. These studies show that the binding site of subtilisin BPN' is longer and broader than that of alpha-chymotrypsin.     

Comparative studies of the specificities of α-chymotrypsin and subtilisin BPN′. Studies with flexible substrates

A series of arylalkanoate esters and alpha-acetamidoarylalkanoate esters were tested as substrates for alpha-chymotrypsin and subtilisin BPN'. Chymotrypsin hydrolysed N-acetyl-l-phenylalanine methyl ester and methyl 4-phenylbutyrate faster than their respective higher and lower homologues, whereas methyl 2-acetamido-6-phenylhexanoate and methyl 6-phenylhexanoate were better substrates for subtilisin than their lower homologues. N-Acetyl-l-tryptophan methyl ester and its analogue, N-acetyl-3-(1-naphthyl)-alanine methyl ester, were hydrolysed 23 times faster by chymotrypsin than by subtilisin. These results indicate that the binding site of alpha-chymotrypsin is roughly 1.1nm (11A) long and curved, whereas that of subtilisin is a longer system and less curved. The stereo-specificity during the hydrolysis of typical substrates by both enzymes was found to vary over a wide range. The enhancing effect of the alpha-acetamido group in the l-series of substrates and the detrimental effect in the d-series of substrates also varies considerably.     

Affinity chromatography of chymotrypsin on a sepharose derivative coupled with a chymostatin analogue

A Sepharose derivative coupled with a chymostatin analogue, Gly-Gly-L-Leu-L-phenylalaninal (Pheal), was prepared. A number of native and chemically modified proteases were applied on a column of the adsorbent. Bovine chymotrypsins [EC 3.4.21.1] and Streptomyces griseus protease B were adsorbed strongly at pH 8.2. The affinities of these enzymes under various conditions were measured quantitatively by frontal chromatography in terms of the dissociation constant (Kd) of the enzyme-immobilized ligand complex. The pH dependence of the Kd value of alpha-chymotrypsin was consistent with that of the inhibition constant (Ki) of the enzyme for a corresponding soluble peptide aldehyde. Anhydro-chymotrypsin, in which the active site Ser-195 is converted to dehydroalanine, was not adsorbed. Ser-195 proved to be essential for the binding. The frontal chromatography method also gave the amount of the immobilized ligand that can interact with the enzyme. It was extremely small compared with the amount of the immobilized ligand determined by amino acid analysis. This was explained on the basis of the structural features of the agarose gel.     

Interaction of methylchymotrypsin with Streptomyces subtilisin inhibitor

The effect of methylation of histidine-57 of alpha-chymotrypsin with Streptomyces subtilisin inhibitor was examined. Methylchymotrypsin was isolated by affinity chromatography on inhibitor-Sepharose, and the interaction of this inactive enzyme with inhibitor was quantitatively analyzed by two different methods: the spectrophotometric titration of difference spectrum resulted in the complex formation and the application of competitive enzyme assay by using substrates of large Km values. The former method gave values of 8.6 . 10(-6) M as dissociation constant (Kd) of methylchymotrypsin . inhibitor complex and 0.91 as the number of binding sites (n) per inhibitor monomer, both of which were almost equivalent to those for native enzyme . inhibitor complex. By the latter novel method, values of 7.9 . 10(-6) M and 1.08 were obtained for Kd and n, respectively, for interaction of inhibitor with alpha-chymotrypsin, and 8 . 10(-6) M as Kd for methylchymotrypsin . inhibitor complex. These results indicate that methylation of histidine-57 of active site in alpha-chymotrypsin molecule does not affect essentially the binding ability to inhibitor and the modified enzyme binds stoichiometrically to inhibitor, as the native enzyme does, with a molar ratio of 1:1 per inhibitor monomer.     

Modification of isoleucine-16 acetylated delta-chymotrypsin.

Activation of acetylated chymotrypsinogen with trypsin leads to catalytically active acetylated delta-chymotrypsin containing NH2-terminal isoleucine. The importance of the cationic terminus to the control of the active conformation of acetylated delta-chymotrypsin has been demonstrated (Oppenheimer, H. L., Labouesse, B., and Hess, G. P. (1966) J. Biol. Chem. 241, 2720). Later studies appeared to suggest that the modification of isoleucine-16 of delta-chymotrypsin is not accompanied by the loss of catalytic activity as measured by the hydrolysis of N-acetyl-L-tyrosine ethyl ester (Agarwal, S. P., Martin, C. J., Blair, T. T., and Marini, M.A. (1971)Biochem. Biophys. Res. Commun. 43, 510; Blair, T. T., Marini, M. A., Agarwal, S. P., and Martin, C. J. (1971) FEBS Lett. 1486) or by the loss of active site content (Ghelis, C., Garel, J. R., and Labouesse, J. (1970) Biochemistry 9, 3902). In the present studies, controlled acetylation of the terminal alpha-aminogroup of acetylated delta-chymotrypsin with acetic anhydride led to a progressive loss of active sites of the enzyme. Determination of the catalytic and kinetic properties of the modified enzyme with the specific ester substrate N-acetyl-L-tyrosine ethyl ester or the nonspecific substrates p-nitrophenyl acetate and cinnamyol imidazole gave nearly identical results. With N-acetyl-L-tyrosine ethyl ester as substrate, the Km (app) values for acetylated delta-chymotrypsin (1.0 plus or minus 0.1 mM) and the modified enzyme (0.67 plus or minus 0.05 mM) are nearly identical and the kcat value is reduced to about 25% in the latter enzyme species. This value correlates well with about 20% of the active sites in this enzyme as measured by the rapid initial liberation of p-nitrophenol. With p-nitrophenyl acetate as substrate, the acylation rate constants (0.13 plus or minus 0.04 s(-1) at pH 6.0, 25 degrees, in 3.3% acetonitrile) and the deacylation rate constants (0.01 s(-1) at pH 8.5, 25 degrees, in 3.3% acetonitrile) are identical for the acetyl isoleucine-16 and the isoleucine-16 enzymes. Furthermore, the residual enzyme activity could be correlated well with the residual NH2-terminal isoleucine content and with the moles of [1--14C]acetyl groups incorporated per mol of the enzyme. The activity associated with the modified enzyme can be attributed to the enzyme species in which isoleucine-16 of acetylated delta-chymotrypsin is not acetylated. These data are in general agreement with the studies of Ghelis et al. (1970) but are in disagreement with the results of Blair et al. (1971) and of Agarwal et al. (1971) and confirm the hypothesis that the final conformation of acetylated delta-chymotrypsin containing an acetylated NH2 terminus is catalytically inactive and resembles acetylated zymogen in many of its physical properties.     

Transesterification of phenylalanine by means of chymotrypsin in a continuous fixed bed reactor.

An enzymic transesterification was carried out in a continuously operated fixed bed reactor. The reaction system consisted of immobilized alpha-chymotrypsin (E.C. 3.4.21.1) catalysing the transfer of the L-phenylalanine radical from the racemic propyl ester to 1,4-butanediol, yielding L-phenylalanine 4-hydroxybutyl ester. The desired reaction was accompanied by alcoholysis due to the presence of 1-propanol liberated during the reaction and by hydrolysis of both the propyl and the hydroxybutyl ester. The problem of shifting pH during the reaction due to ester hydrolysis was overcome by adjusting the initial pH of the substrate feed solution appropriately in order to obtain a sufficiently high buffer capacity provided by the free amino group of the esters. Thus, it was possible to work with shifting pH, an obvious disadvantage for operating reactors of low backmixing for this kind of reaction system. The overall reaction scheme was characterized by the appearance of a maximum ester yield as a function of the operating time in case of batch reactors. Surprisingly, the yield was found to become constant as a function of space-time for continuous operation due to a steeper pH drop. The maximum productivity achieved with respect to the hydroxybutyl ester was about 65 mol d-1 l-1 referred to the catalyst volume.     

The behaviour of trypsin towards α-N-methyl-α-N-toluene-p-sulphonyl-l-lysine β-naphthyl ester. A new method for determining the absolute molarity of solutions of trypsin

1. alpha-N-Methyl-alpha-N-toluene-p-sulphonyl-l-lysine beta-naphthyl ester (MTLNE) was synthesized as its hydrobromide and shown to be slowly hydrolysed by bovine pancreatic trypsin. The acylation step, however, is so much faster than deacylation of the acyl-enzyme that spectrophotometric measurement of the ;burst' of beta-naphthol provides a convenient method for determining the absolute molarity of trypsin solutions. 2. By using the same stock solution of trypsin, application of this method at pH4.0 and pH7.0 as well as that of Bender et al. (1966) at pH3.7 gave concordant results. 3. Provided that [S](0)>[E](0), the size of the ;burst' is independent of substrate concentration. 4. In the trypsin-catalysed hydrolysis of alpha-N-toluene-p-sulphonyl-l-arginine methyl ester, MTLNE functions as a powerful non-competitive inhibitor. 5. There is no detectable reaction between MTLNE and either bovine pancreatic alpha-chymotrypsin at pH4.0 or bovine thrombin at pH6.0.     

Reinvestigation of the reaction of chymotrypsin with N-furylacryloyltryptophan derivatives at acidic pH.

The reaction of alpha-chymotrypsin with N alpha-3-(2-furyl)acryloyl-L-tryptophan methyl ester (FA-Trp-OMe) and amide has been investigated in aqueous and dimethylsulphoxide cryosolvent solutions from pH2 to 7 and over a wide temperature range. Previous reports have suggested that an intermediate preceding the acyl-enzyme can be detected spectrophotometrically in the reaction with methyl esters of FA-Trp and FA-Tyr at low pH [Yu & Viswanatha (1969) Eur. J. Biochem. 11, 347--352), and that this intermediate is an oxazolinone [Coletti-Previero et al. (1970) FEBS Lett. 11, 213--217]. We show that the previous interpretations of the time-dependent spectral changes were incorrect, and that the only detected intermediate is the acyl-enzyme. This may be isolated by gel filtration at pH less than 2.5, 1 degree C, owing to its relative stability. The pH-dependence of the rates of acylation and deacylation from pH 8.5 to 2.0 are consistent with a single ionization of pK congruent to 7.0 in both aqueous and cryosolvent solutions.     

Synthesis and characterization of a selenium-containing substrate of alpha-chymotrypsin. Selenium-77 nuclear magnetic resonance observation of an acyl-alpha-chymotrypsin intermediate

The selenium-containing ester p-nitrophenyl (phenylselenyl)acetate, C6H5SeCH2C(O)-OC6H4-p-(NO2), has been synthesized, characterized as a substrate for alpha-chymotrypsin (k2/KM = 15.2 X 10(3) M-1 s-1, KMapp = 5.16 X 10(-6) M, pH 7.77, 33% CH3CN, 25 degrees C), and shown to be an active-site titrant for the enzyme. A synthesis of the selenium-77 enriched p-nitrophenyl (phenylselenyl)acetate in 53% yield from 94.4% elemental selenium-77, followed by its reaction with alpha-chymotrypsin (pH 5.0, 0-3 degrees C), permitted the observation of the (phenylselenyl)acetyl-alpha-chymotrypsin reaction intermediate by selenium-77 NMR spectroscopy. This acyl-enzyme species had a chemical shift of 275.1 ppm relative to dimethyl selenide. Accompanying this resonance was a lower intensity, pH-dependent resonance that is assigned to (phenylselenyl)acetate on the basis of a pH titration of the model compound. Deacylation in the presence of hydrazine sulfate produced a resonance at 332.3 ppm in addition to the 302.2 ppm resonance of (phenylselenyl)acetate at pH 7.85. Denaturation of the acyl-enzyme resulted in a shift of the 275.1 ppm resonance to 334.6 ppm at pH 4.90, in good agreement with the selenium-77 chemical shift of the model compound, methyl (phenylselenyl)acetate, in CDCl3 (333.3 ppm). The large shielding observed for the native acyl-enzyme in comparison to the denatured species can be attributed to a resonance-perturbed ester linkage and/or steric compression at a nonbonding orbital of the selenium nucleus.     

Kinetics of alpha-chymotrypsin catalyzed hydrolysis in equilibrium. II. Comparison of ester and amide substrates

Kinetic of the alpha-chymotrypsin catalyzed reversible hydrolytic reaction of methyl N-acetyl-L-phenylalaninate and N-acetyl-L-phenylalanylglycinamide at pH 5.5 and equilibrium conditions has been studied. The rates of the labeled reaction products incorporated into the substrate a different methanol concentrations shows that the reaction proceeds by a compulsory mechanism with the formation of N-acetyl-L-phenylalanine-alpha-chymotrypsin complex. For the amide substrate the data obtained are also in agreement with the compulsory mechanism of its hydrolysis. Equilibrium kinetics of ester and amide substrates hydrolysis has been compared.     

Enzyme-based high-performance liquid chromatography supports as probes of enzyme activity and inhibition: the immobilization of trypsin and alpha-chymotrypsin on an immobilized artificial membrane high-performance liquid chromatography support.

Immobilized artificial membrane (IAM) HPLC supports have been used to immobilize the enzymes alpha-chymotrypsin and trypsin. The enzymes were trapped in hydrophobic cavities on the support and were not covalently attached to the IAM surface. The resulting IAM-enzyme supports retained the hydrolytic activity of the immobilized enzymes: the IAM-trypsin support catalyzed the hydrolysis of N alpha-benzoyl-DL-arginine-p-nitroanilide (BAPNA), and the IAM-alpha-chymotrypsin support (IAM-ACHT) catalyzed the hydrolysis of a number of substrates, including tryptophan methyl ester. The activities of both supports were decreased by known enzyme inhibitors and the activity of the IAM-ACHT was affected by changes in pH and temperature. When a substrate was chromatographed on an IAM-ACHT HPLC, the hydrolytic activity of the immobilized enzyme could be determined from the resulting substrate/product ratios. These data were obtained either directly from the IAM-ACHT chromatogram or from the chromatogram produced by a coupled column system. The results of this study indicate that IAM-immobilized alpha-chymotrypsin and trypsin can be used as chromatographic probes for the qualitative determination of enzyme/substrate and enzyme/inhibitor interactions.     

(S)-Thiirancarboxylic acid as a reactive building block for a new class of cysteine protease inhibitors

For (S)-thiirancarboxylic acid a second-order rate constant of k2nd = 222 M(-1) min(-1) for the irreversible inhibition of papain was determined. The ethyl and methyl ester do not inhibit the enzyme time-dependently. An improved synthesis of enantiomerically pure thiirancarboxylic acid is described. It is shown that thiirancarboxylates can be substrates for serine proteases (alpha-chymotrypsin) and esterases (pig liver esterase) and even for metallo proteases (thermolysin).     

The inhibition of proteolytic enzyme activity by humic acids]

The inhibitory effect of peat humic acids on the hydrolysis of N-acetyl-L-tyrosine ethyl ester and N-benzoyl-L-leucine methyl ester by alpha-chymotrypsin and subtilism has been studied. Samples of humic acids with M(W) approximately 18,000 have been used in experiments. The results of kinetic studies indicates the mixed type of inhibition of proteinase activity by humic acids. The meanings of inhibition constants under the action of humic acids on alpha-chymotrypsin and subtilism have been calculated.     

Conformation and stability of the chymotrypsin inhibitor from winged bean seed (Psophocarpus tetragonolobus (L.) DC)

Spectrophotometric measurement was found to be a sensitive method for evaluating the stability of the chymotrypsin inhibitor from the winged bean. The thermal stability of this protein in aqueous solution was much greater at pH 3 than at pH 8 or pH 11. Evidence from u.v. absorption and from circular dichroism indicated that irreversible conformation changes occurred at higher temperature (greater than 70 degrees). Circular dichroism and optical rotatory dispersion studies at pH 8 show that the inhibitor is rich in beta-structure and virtually devoid of alpha-helix in aqueous solution. We conclude from experiments with denaturing solvents that the inhibitor is very stable and that high concentrations of denaturant are required before unfolding occurs. Chemical modification experiments with tetranitromethane were consistent with a tight stable structure; even in 6M guanidine hydrochloride only three of the five tyrosine residues in the inhibitor molecule were nitrated. However, tyrosine does not seem to be implicated at the reactive site of the inhibitor. Interaction of the inhibitor with alpha-chymotrypsin and chymotrypsin B was also followed by difference spectroscopy in the ultraviolet region. Difference spectra were detected that were characteristic of changes in the environment of both tyrosine and tryptophan chromophores. Comparison of the spectral data obtained for the interaction of the inhibitor with bovine alpha-chymotrypsin and with chymotrypsin B indicated that a tryptophan residue may be involved at the reactive site of the inhibitor. Spectral changes were also detected for the interaction between the chymotrypsin inhibitor and trypsin, although it is well established that the specificity of this inhibitor is restricted to the chymotrypsins.(ABSTRACT TRUNCATED AT 250 WORDS)     

Binding rates, O--S substitution effects, and the pH dependence of chymotrypsin reactions.

The pH dependence for acylation of alpha-chymotrypsin by N-acetyltryptophan p-nitrophenyl-, p-nitrothiophenyl-, ethyl-, and thiolethyl esters has been studied by the stopped-flow technique. Values for the acylation rate constant, k2, and the binding constant, KS, were obtained by using measurements of phenolate release, for the p-nitrophenyl esters, and proflavin displacement, for the ethyl esters. The oxygen esters tested have slightly higher k2 values, and substantially higher KS values relative to the analogous thiol esters. Whereas k2/KS for the thiolethyl ester is higher than that for the analogous oxygen ester, the k2/KS values for oxy- and thio-p-nitrophenyl esters are nearly identical. These data are interpreted to indicate rate-determining formation of a tetrahedral intermediate in acylation of alpha-chymotrypsin by p-nitrophenyl esters, and rate-determining breakdown of such an intermediate in the case of the ethyl esters. It is also concluded that the oxygen to sulfur substitution causes a substantial increase in the proportion of nonproductive binding in these substrates. pH dependent k2 and KS values were used to calculate values for k1 and k-1, the binding and debinding rate constants for the two p-nitrophenyl compounds. This is the first such calculation based on experimentally determined acylation rate constants.     

Purification and partial characterization of an alpha-chymotrypsin-like protease of rat peritoneal mast cells.

An alpha-chymotrypsin-like enzyme was isolated from mast cells of the rat peritoneal cavity by extraction with 0.8 M potassium phosphate, 2 per cent protamine sulfate followed by affinity chromatography on hen ovoinhibitor-agarose and adsorption on barium sulfate. This procedure yielded over 9 mg of protease from the peritoneal lavage fluid of 100 rats, equivalent to 44 per cent of the initial activity. The purified protein was homogeneous as judged by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, analytical isoelectric focusing, and amino-terminal sequence analysis. The protease contains no covalently bound carbohydrate and has a molecular weight of approximately 26,000. The enzyme molecule is a single polypeptide chain with an amino-terminal sequence homologous to that of the B chain of bovine alpha-chymotrypsin. The kinetic parameters, Km and kcat, for the hydrolysis of N-benzoyl-L-tyrosine ethyl ester were determined at pH 8.0 and 25 degrees C as 1.1 X 10(-3) M and 84 sec-1, respectively. The value of the second-order rate constant for inactivation of mast cell protease by diisopropylphosphofluoridate was 300 times lower than for bovine alpha-chymotrypsin.