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

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

Identification of a highly specific chymase as the major angiotensin II-forming enzyme in the human heart

Although angiotensin II (Ang II)-forming enzymatic activity in the human left cardiac ventricle is minimally inhibited by angiotensin I (Ang I) converting enzyme inhibitors, over 75% of this activity is inhibited by serine proteinase inhibitors (Urata, H., Healy, B., Stewart, R. W., Bumpus, F. M., and Husain, A. (1990) Circ. Res. 66, 883-890). We now report the identification and characterization of the major Ang II-forming, neutral serine proteinase, from left ventricular tissues of the human heart. A 115,150-fold purification from human cardiac membranes yielded a purified protein with an Mr of 30,000 by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Based upon its amino-terminal sequence, the major human cardiac Ang II-forming proteinase appears to be a novel member of the chymase subfamily of chymotrypsin-like serine proteinases. Human heart chymase was completely inhibited by the serine proteinase inhibitors, soybean trypsin inhibitor, phenylmethylsulfonyl fluoride, and chymostatin. It was partially inhibited by p-tosyl-L-phenylalanine chloromethyl ketone, but was not inhibited by p-tosyl-L-lysine chloromethyl ketone, and aprotinin. Also, human heart chymase was not inhibited by inhibitors of the other three classes of proteinases. Human heart chymase has a high specificity for the conversion of Ang I to Ang II and the Ang I-carboxyl-terminal dipeptide His-Leu (Km = 60 microM; Kcat = 11,900 min-1; Kcat/Km = 198 min-1 microM-1). Human heart chymase did not degrade several peptide hormones, including Ang II, bradykinin, and vasoactive intestinal peptide, nor did it form Ang II from angiotensinogen. The high substrate specificity of human heart chymase for Ang I distinguishes it from other Ang II-forming enzymes including Ang I converting enzyme, tonin, kallikrein, cathepsin G, and other known chymases.     

Rodent alpha-chymases are elastase-like proteases.

Although the alpha-chymases of primates and dogs are known as chymotrypsin-like proteases, the enzymatic properties of rodent alpha-chymases (rat mast cell protease 5/rMCP-5 and mouse mast cell protease 5/mMCP-5) have not been fully understood. We report that recombinant rMCP-5 and mMCP-5 are elastase-like proteases, not chymotrypsin-like proteases. An enzyme assay using chromogenic peptidyl substrates showed that mast cell protease-5s (MCP-5s) have a clear preference for small aliphatic amino acids (e.g. alanine, isoleucine, valine) in the P1 site of substrates. We used site-directed mutagenesis and computer modeling approaches to define the determinant residue for the substrate specificity of mMCP-5, and found that the mutant possessing a Gly substitution of the Val at position 216 (V216G) lost elastase-like activity but acquired chymase activity, suggesting that the Val216 dominantly restricts the substrate specificity of mMCP-5. Structural models of mMCP-5 and the V216G mutant based on the crystal structures of serine proteases (rMCP-2, human cathepsin G, and human chymase) revealed the active site differences that can account for the marked differences in substrate specificity of the two enzymes between elastase and chymase. These findings suggest that rodent alpha-chymases have unique biological activity different from the chymases of other species.     

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

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

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

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

Molecular cloning of the mouse mast cell protease-5 gene. A novel secretory granule protease expressed early in the differentiation of serosal mast cells

cDNAs were isolated that encode mouse mast cell protease-5 (MMCP-5), an approximately 30,000 Mr serine protease stored in the secretory granules of serosal mast cells (SMC) and Kirsten sarcoma virus-immortalized mast cells. Based on the deduced amino acid sequences of these cDNAs, MMCP-5 is synthesized as a 247-amino acid preproenzyme composed of a novel 19-residue hydrophobic signal peptide, a Gly-Glu activation peptide not present in other mast cell chymases, and a 226-amino acid protein that represents the mature enzyme. MMCP-5 possesses a unique Asn residue in the substrate binding cleft at residue 176 and is highly basically charged. The MMCP-5 gene was isolated, sequenced, and found to belong to a distinct subset of chymase genes. Allelic variations of the MMCP-5 gene were also detected. MMCP-5 is expressed in bone marrow-derived mast cells (BMMC), Kirsten sarcoma virus-immortalized mast cells, and SMC, but not in gastrointestinal mucosal mast cells of helminth-infected mice. The abundant levels of MMCP-5 mRNA in immature BMMC indicate that this chymase is expressed relatively early during the differentiation of mast cells. MMCP-5 is the first chymase to be molecularly cloned from progenitor mast cells and is also the first chymase shown to be expressed preferentially in the SMC subclass.     

Localization, implications for function, and gene expression of chymotrypsin-like proteinases of cytotoxic RNK-16 lymphocytes

Rat RNK-16 leukemia cells kill YAC-1, which are the cells lysed by rodent natural killer lymphocytes. We found chymotrypsin-like proteinase ('chymase') activity in the RNK-16 dense granules that also contain cytolytic activity. The chymase activity hydrolyzed the thiobenzyl peptide substrate Suc-Phe-Leu-Phe-SBzl and, in comparison to RNK-16 tryptase activity, was selectively inhibited by three different types of serine proteinase inhibitors. The selective inhibitors were the fungal aldehyde chymostatin, the chloromethylketone Z-Gly-Leu-Phe-CH2Cl, and the mechanism-based or 'suicide' inhibitor 7-amino-4-chloro-3-(2-phenylethoxy)isocoumarin. These proteinase inhibitors also blocked RNK-16 granule-mediated cytolysis. Chymostatin, a reversible inhibitor, delayed granule-mediated cytolysis, whereas the irreversible chloromethylketone and isocoumarin proteinase inhibitors completely abrogated granule-mediated cytolysis. The two irreversible inhibitors displayed biphasic inhibition of the chymase activity, indicating that at least two chymases are present in the granules. By Northern blot analysis, we found that RNK-16 mRNA hybridized strongly with a cDNA probe of CCPI, a mouse cytotoxic T lymphocyte serine proteinase gene. These data imply that chymase activity in the cytotoxic granules is important for cytolytic function and is likely to belong to a new subfamily of serine proteinases.     

Species differences in angiotensin II generation and degradation by mast cell chymases

Although chymases are known to exhibit species differences in regard to angiotensin (Ang) II generation and degradation, their properties have never been compared under the same experimental conditions. We analyzed the processing of Ang I by chymases of a variety of species (human chymase, dog chymase, hamster chymase-1, rat mast cell protease-1 [rMCP-1], mouse mast cell protease-4 [mMCP-4]) at physiological ionic strength and under neutral pH conditions. Human chymase generated Ang II from Ang I without further degradation, whereas the chymases of other species generated Ang II, followed by degradation at the Tyr4-Ile5 site in a time-dependent manner. Kinetic analysis showed that in terms of Ang II generating activity (analyzed by cleavage of the Phe8-His9 bond using the model peptide Ang(5-10), Ile5-His6-Pro7-Phe8-His9-Leu10), the chymases ranked as follows: dog > human > hamster > mouse > rat (kcat/Km: 18, 11, 0.69, 0.059, 0.030 microM-1min-1), and that in terms of Ang II degrading activity (i.e., cleavage of the Tyr4-Ile5 bond of Ang II), the order was hamster > rat > mouse > dog (kcat/Km: 5.4, 4.8, 0.39, 0.29 microM-lmin-1). These results suggest species differences in the contribution of chymases to local Ang II generation and degradation.     

Primary structure of human preangiotensinogen deduced from the cloned cDNA sequence

Cloned cDNA sequences for human preangiotensinogen have been isolated from a human liver cDNA library by hybridization with a restriction fragment derived from a previously cloned cDNA for rat preangiotensinogen. Analyses by nucleotide sequence determination, S1 nuclease mapping, and RNA blot hybridization indicate that human preangiotensinogen is encoded by two mRNAs that differ only in the length of the 3'-untranslated region. The deduced amino acid sequence shows that the mature angiotensinogen consists of 452 amino acid residues with the angiotensin sequence at its amino-terminal portion. Two potential initiation sites have been discussed. These are the methionine codon located at the position exactly corresponding to the initiation site of rat preangiotensinogen mRNA and an additional methionine codon positioned nearest the 5' end of the mRNA. The amino acid sequences starting at either of the initiation sites and preceding the angiotensin sequence constitute a large number of hydrophobic amino acid residues, thus representing the signal peptide characteristic of the secretory proteins. Human and rat preangiotensinogens show that 63.6% of the amino acid positions of the two proteins are identical. However, the amino-terminal portions directly distal to angiotensin I diverge markedly between the two proteins and differ in their possible glycosylation sites. These structural differences may contribute to the known species specificity exhibited by renin.     

Molecular cloning and expression in Escherichia coli of a cDNA encoding human pancreatic elastase 2

We have cloned a DNA that is complementary to the messenger RNA that encodes human pancreatic elastase 2 from a human pancreatic cDNA library using a cloned cDNA for rat pancreatic elastase 2 messenger RNA. This complementary DNA contains the entire protein coding region of 807 nucleotides which encodes preproelastase of 269 amino acids, and 4 and 82 nucleotides of the 5'- and 3'-untranslated sequences, respectively. When this deduced amino acid sequence was compared with known amino acid sequences it showed 82% homology with rat pancreatic elastase 2. This deduced sequence also contains a 16-amino-acid peptide identical with the N-terminal sequence determined for native human pancreatic proelastase 2. Taking the above findings together, we conclude that the cloned cDNA encodes a mature enzyme of 241 amino acids including 16 and 12 amino acids for a signal peptide and an activation peptide, respectively. Moreover, the predicted key amino acid residues involved in determining the substrate specificity of mammalian pancreatic elastase 2 are retained in the human enzyme. Cloned human pancreatic elastase 2 cDNA was expressed in E. coli as a mature and pro-form protein. Both resulting proteins showed immunoreactivity toward anti-elastase serum and enzymatic activity. We have also cloned and sequenced a porcine pancreatic elastase 2 cDNA.     

Angiotensin II generation by mast cell alpha- and beta-chymases

Mast cells secrete alpha- and beta-chymases. Primate alpha-chymases generate angiotensin (AT) II by selectively hydrolyzing AT I's Phe(8)-His(9) bond. This is distinct from the AT converting enzyme (ACE) pathway. In humans, alpha-chymase is the major non-ACE AT II-generator. In rats, beta-chymases destroy AT II by cleaving at Tyr(4)-Ile(5). Past studies predicted that AT II production versus destruction discriminates alpha- from beta-chymases and that Lys(40) in the substrate-binding pocket determines alpha-chymase Phe(8) specificity. This study examines these hypotheses by comparing AT II generation by human alpha-chymase (containing Lys(40)), dog alpha-chymase (lacking Lys(40)), and mouse mMCP-4 (a beta-chymase lacking Lys(40); orthologous to AT II-destroying rat chymase rMCP-1). The results suggest that human and dog alpha-chymase generate AT II exclusively and with comparable efficiency, although dog chymase contains Ala(40) rather than Lys(40). Furthermore, AT II is the major product generated by degranulation supernatants from cultured dog mast cells, which release tryptases and dipeptidylpeptidase as well as alpha-chymase. In contrast to rMCP-1, mMCP-4 beta-chymase readily generates AT II. Although there is competing AT I hydrolysis at Tyr(4), mMCP-4 does not destroy AT II quickly once it is formed. We conclude (1) that chymases are the dominant AT I-hydrolyzing mast cell peptidases, (2) that residues other than Lys(40) are key determinants of alpha-chymase AT I Phe(8) specificity, (3) that beta-chymases can generate AT II, and (4) that alpha- and beta-chymases are not strictly dichotomous regarding AT I cleavage specificity.     

Extended substrate specificity of rat mast cell protease 5, a rodent alpha-chymase with elastase-like primary specificity

Chymases are mast cell serine proteases with chymotrypsin-like primary substrate specificity. Amino acid sequence comparisons of alpha-chymases from different species indicated that certain rodent alpha-chymases have a restricted S1 pocket that could only accommodate small amino acids, i.e. they may, despite being classified as chymases, in fact display elastase-like substrate specificity. To explore this possibility, the alpha-chymase, rat mast cell protease 5 (rMCP-5), was produced as a proenzyme with a His6 purification tag and an enterokinase-susceptible peptide replacing the natural propeptide. After removal of the purification tag/enterokinase site by enterokinase digestion, rMCP-5 bound the serine-protease-specific inhibitor diisopropyl fluorophosphate, showing that rMCP-5 was catalytically active. The primary specificity was investigated with chromogenic substrates of the general sequence succinyl-Ala-Ala-Pro-X-p-nitroanilide, where the X was Ile, Val, Ala, Phe or Leu. The activity was highest toward substrates with Val or Ala in the P1 position, whereas low activity toward the peptide with a P1 Phe was observed, indicating that the substrate specificity of rMCP-5 indeed is elastase-like. The extended substrate specificity was examined utilizing a phage-displayed random nonapeptide library. The preferred cleavage sequence was resolved as P4-(Gly/Pro/Val), P3-(Leu/Val/Glu), P2-(Leu/Val/Thr), P1-(Val/Ala/Ile), P1'-(Xaa), and P2'-(Glu/Leu/Asp). Hence, the extended substrate specificity is similar to human chymase in most positions except for the P1 position. We conclude that the rat alpha-chymase has converted to elastase-like substrate specificity, perhaps associated with an adoption of new biological targets, separate from those of human alpha-chymase.     

Molecular cloning and expression of human bile acid beta-glucosidase

A novel microsomal beta-glucosidase was recently purified and characterized from human liver that catalyzes the hydrolysis of bile acid 3-O-glucosides as endogenous compounds. The primary structure of this bile acid beta-glucosidase was deduced by cDNA cloning on the basis of the amino acid sequences of peptides obtained from the purified enzyme by proteinase digestion. The isolated cDNA comprises 3639 base pairs containing 524 nucleotides of 5'-untranslated and 334 nucleotides of 3'-untranslated sequences including the poly(A) tail. The open reading frame predicts a 927-amino acid protein with a calculated M(r) of 104,648 containing one putative transmembrane domain. Data base searches revealed no homology with any known glycosyl hydrolase or other functionally identified protein. The cDNA sequence was found with significant identity in the human chromosome 9 clone RP11-112J3 of the human genome project. The recombinant enzyme was expressed in a tagged form in COS-7 cells where it displayed bile acid beta-glucosidase activity. Northern blot analysis of various human tissues revealed high levels of expression of the bile acid beta-glucosidase mRNA (3.6-kilobase message) in brain, heart, skeletal muscle, kidney, and placenta and lower levels of expression in the liver and other organs.     

Purification, molecular cloning, and immunohistochemical localization of dipeptidyl peptidase II from the rat kidney and its identity with quiescent cell proline dipeptidase

We purified dipeptidyl peptidase II (DPP II) to homogeneity from rat kidney and determined its physicochemical properties, including its molecular weight, substrate specificity, and partial amino acid sequence. Furthermore, we screened a rat kidney cDNA library, isolated the DPP II cDNA and determined its structure. The cDNA was composed of 1,720 base pairs of nucleotides, and 500 amino acid residues were predicted from the coding region of cDNA. Human quiescent cell proline dipeptidase (QPP) cloned from T-cells is a 58-kDa glycoprotein existing as a homodimer formed with a leucine zipper motif. The levels of amino acid homology were 92.8% (rat DPP II vs. mouse QPP) and 78.9% (rat DPP II vs. human QPP), while those of nucleotide homology were 93.5% (rat DPP II vs. mouse QPP) and 79.4% (rat DPP II vs. human QPP). The predicted amino acid sequences of rat DPP II and human and mouse QPP possess eight cysteine residues and a leucine zipper motif at the same positions. The purified DPP II showed similar substrate specificity and optimal pH to those of QPP. Consequently, it was thought that DPP II is identical to QPP. Northern blot analysis with rat DPP II cDNA revealed prominent expression of DPP II mRNA in the kidney, and the order for expression was kidney > testis > or = heart > brain > or = lung > spleen > skeletal muscle > or = liver. In parallel with Northern blot analysis, the DPP II antigen was detected by immunohistochemical staining in the cytosol of epithelial cells in the kidney, testis, uterus, and cerebrum.     

Sequence of the 3''-noncoding and adjacent coding regions of human gamma-globin mRNA.

In cloning human fetal globin cDNA in bacterial plasmids, we obtained a recombinant which contained a fragment of gammg-globin cDNA corresponding to the region from amino acid 99 to the poly A. We determined a sequence of 169 nucleotides which included the complete 3' non-coding region of the gamma-globin mRNA. The codon for amino acid 136 was GCA, indicating that this cloned fragment was derived from the Agamma-globin gene. In conjunction with the surrounding sequences, the GCA codon provides the Agamma-species with a unique CTGCAG hexanucleotide that is recognized by the restriction enzyme Pst I. The 3'-untranslated region of the gamma-globin mRNA consists of 90 nucleotides, and shares little homology with that of the human beta-globin mRNA. As in other mammalian mRNAs, a symmetrical sequence and the hexanucleotide AAUAAA are present.     

Characterization of recombinant human adipocyte-derived leucine aminopeptidase expressed in Chinese hamster ovary cells

Adipocyte-derived leucine aminopeptidase (A-LAP) is a recently identified novel member of the M1 family of zinc-metallopeptidases. Transfection of the A-LAP cDNA into COS-7 cells resulted in the secretion of the enzyme. In this study, recombinant A-LAP was expressed in Chinese hamster ovary cells, purified to homogeneity and its enzymatic properties were characterized. The purified enzyme was active towards a synthetic substrate, L-leucyl-p-nitroanilide, yielding a V(max) of 3.55 micromol/min/mg and a K(m) of 1.28 mM, and was shown to be a monomeric protein with molecular mass of 120 kDa in solution. By monitoring the sequential N-terminal amino acid liberation, it was found that the enzyme hydrolyzes a variety of bioactive peptides, including angiotensin II and kallidin. Immunohistochemical analysis indicated that the enzyme is expressed in the cortex of the human kidney, where tissue kallikrein is localized. Taken together, these results indicate that A-LAP possesses a broad substrate specificity towards naturally occurring peptide hormones and suggest that it plays a role in the regulation of blood pressure through the inactivation of angiotensin II and/or the generation of bradykinin in the kidney.     

Mutations in Arg143 and Lys192 of the Human Mast Cell Chymase Markedly Affect the Activity of Five Potent Human Chymase Inhibitors

Chymotrypsin-like serine proteases are found in high abundance in mast cell granules. By site-directed mutatgenesis, we have previously shown that basic amino acids in positions 143 and 192 (Arg and Lys respectively) of the human mast cell chymase are responsible for an acidic amino acid residue preference in the P2'' position of substrates. In order to study the influence of these two residues in determining the specificity of chymase inhibitors, we have synthesized five different potent inhibitors of the human chymase. The inhibitory effects of these compounds were tested against the wild-type enzyme, against two single mutants Arg143Gln and Lys192Met and against a double mutant, Arg143Gln+Lys192Met. We observed a markedly reduced activity of all five inhibitors with the double mutant, indicating that these two basic residues are involved in conferring the specificity of these inhibitors. The single mutants showed an intermediate phenotype, with the strongest effect on the inhibitor by the mutation in Lys192. The Lys192 and the double mutations also affected the rate of cleavage of angiotensin I but did not seem to affect the specificity in the cleavage of the Tyr₄-Ile₅ bond. A more detailed knowledge about which amino acids that confer the specificity of an enzyme can prove to be of major importance for development of highly specific inhibitors for the human chymase and other medically important enzymes.     

Purification and characterization of dog mastocytoma chymase: identification of an octapeptide conserved in chymotryptic leukocyte proteinases

We isolated and characterized a chymotryptic serine proteinase from dog mastocytomas. Chymotryptic activity extracted at high ionic strength from mastocytomas propagated in nude mice was separated from tryptic activity by gel filtration and rapidly purified by sequential high-performance hydrophobic interaction and cation-exchange chromatography. The purified enzyme had an Mr of 27,000-30,000 by both analytical gel filtration and SDS-polyacrylamide gel electrophoresis, and a single amino-terminal sequence by automated Edman degradation. Like chymases from rat and human mast cells, the mastocytoma enzyme exhibited a high kcat/Km (1.1.10(5) M-1.s-1) employing succinyl-L-Val-Pro-Phe-p-nitroanilide, the best of several p-nitroanilide substrates screened. It was inhibited by diisopropyl fluorophosphate and soybean trypsin inhibitor, but not by aprotinin, distinguishing it from the otherwise closely related neutrophil enzyme, cathepsin G. The amino-terminal 25 residues of mastocytoma chymase were found to be 72 and 68% identical to the corresponding sequences of chymases from rat peritoneal and mucosal mast cells, respectively; they were also closely related to human cathepsin G and to proteinase sequences from mouse cytotoxic T-lymphocytes. The mastocytoma chymotryptic enzyme contained an octapeptide sequence which is common to all chymotryptic leukocyte proteinases sequenced to date from four mammalian species; this feature distinguishes chymases and other chymotryptic leukocyte proteinases from serine proteinases of coagulation and digestion.