Amino acid sequence of rat mast cell protease I (chymase)

The amino acid sequence has been determined for rat mast cell protease I (RMCP I), a product of peritoneal mast cells. The active enzyme contains 227 residues, including three corresponding to the catalytic triad characteristic of serine protease (His-57, Asp-102, and Ser-195 in chymotrypsin). A computer search for homology indicates 73% and 33% sequence identity of RMCP I with rat mast cell protease II from mucosal mast cells and bovine chymotrypsin A, respectively. When the structure of RMCP I is compared to those of cathepsin G from human neutrophils and two proteases expressed in activated lymphocytes, 48-49% of the sequences are identical in each case. RMCP I has six half-cystine residues at the same positions as in RMCP II, cathepsin G, and the two lymphocyte proteases, suggesting disulfide pairs identical with those reported for RMCP II. A disulfide bond near the active site seryl residue and substrate binding site, present in pancreatic and plasma serine proteases, is not found in RMCP I or in the other cellular proteases. These results indicate that RMCP I and other chymotrypsin-like proteases of granulocyte and lymphocyte origin are more closely related to each other than to the pancreatic or plasma serine proteases.     

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.     

The Human Mast Cell Chymase Gene (CMA1): Mapping to the Cathepsin G/Granzyme Gene Cluster and Lineage-Restricted Expression

Genes encoding T-cell-receptor α/δ chains, neutrophil cathepsin G, and lymphocyte CGL/granzymes are closely linked on chromosomal band 14q11.2. The current work identifies the human mast cell chymase gene (CMA1) as the fourth protease in this cluster and maps the gene to within 150 kb of the cathepsin G gene. The gene order is centromere-T cell receptor α/δ-CGL-1/granzyme B-CGL-2/granzyme H-cathepsin G-chymase. Chymase and cathepsin G genes are shown to be cotranscribed in the human mast cell line HMC-1 and in U-937 cells. Other cells transcribe cathepsin G or CGL/granzyme genes, but not chymase genes, suggesting a capacity for independent regulation. Comparison of the 5′ flank of the chymase gene with those of cathepsin G and CGL/granzymes reveals little overall homology. Only short regions of the 5′ flanks of the human and murine chymase genes sequenced to date are similar, suggesting that they are more distantly related than human and rodent CGL-1/granzyme B, the flanks of which are highly homologous. The expression patterns and clustering of genes provide possible clues to the presence of locus control regions that orchestrate lineage-restricted expression of leukocyte and mast cell proteases.     

Characterization of cDNA clones encoding mouse proteinase 3 (myeloblastine) and cathepsin G

 Serine proteases are the most abundant granule constituents of several major hematopoietic cell lineages. Due to their high abundance and their strict tissue specificity they have become important phenotypic cell markers used for studies of various aspects of hematopietic cell development. Using a polymerase chain reaction (PCR)-based strategy for the isolation of trypsin-related serine proteases, we were able to isolate cDNAs for two of the major neutrophil and monocyte serine proteases in the mouse, cathepsin G and mouse protease 3 (myeloblastin). The internal PCR fragments were used as probes to screen a mouse mast cell cDNA library and a cDNA library originating from a mouse monocytic cell line (WEHI-274.1). Full-length cDNAs for mouse cathepsin G and proteinase 3 were isolated and their complete sequences were determined. Northern blot analysis revealed expression of cathepsin G in immature cells of the monocyte macrophage lineage but also in the connective tissue mast cell line MTC. Proteinase 3 was expressed in several cell lines of myelo-monocytic origin and in one B-cell line, but not in any of the other cell lines tested. The isolation of cDNAs for mouse cathepsin G and mouse proteinase 3, together with the previous characterization of the gene for mouse N-elastase, and the entire or partial amino acid sequences for porcine azurocidine, equine N-elastase and proteinase 3, rat, dog, and rabbit cathepsin Gs in evolutionary relatively distantly related mammalian species, indicates that these four members of the serine protease family have been maintained for more than 100 million years of mammalian evolution. This latter finding indicates a strong evolutionary pressure to maintain specific immune functions associated with these neutrophil and monocyte proteases. All amino acid positions of major importance for the cleavage site selection have also been fully conserved between mouse and human proteinase 3 and a few minor changes have occurred between mouse and human cathepsin G. Received: 3 August 1996 / Revised: 24 February 1997     

Amino acid sequence of a mouse mucosal mast cell protease

The amino acid sequence has been determined of a mouse mucosal mast cell protease isolated from the small intestines of mice infected with Trichinella spiralis. The active protease contains 226 residues. Those corresponding to the catalytic triad of the active site of mammalian serine proteases (His-57, Asp-102, and Ser-195 in chymotrypsin) occur in identical positions. A computer search for homology indicates 74.3% and 74.1% sequence identity of the mouse mast cell protease compared to those of rat mast cell proteases I and II (RMCP I and II), respectively. The six half-cystine residues in the mouse mast cell protease are located in the same positions as in the rat mast cell proteases, cathepsin G, and the lymphocyte proteases, suggesting that they all have identical disulfide bond arrangements. At physiological pH, the mouse and rat mucosal mast cell proteases have net charges of +3 and +4, respectively, as compared to +18 for the protease (RMCP I) from rat connective tissue mast cells. This observation is consistent with the difference in solubility between the mucosal and connective tissue mast cell proteases when the enzymes are extracted from their granules under physiological conditions.     

Identification of a subgroup of glycosylphosphatidylinositol-anchored tryptases

The tryptase locus on mouse chromosome 17A3.3 contains 13 genes that encode enzymatically active serine proteases with different tissue expression profiles and substrate specificities. Mouse mast cell protease (mMCP) 6, mMCP-7, mMCP-11/protease serine member S (Prss) 34, tryptase 6/Prss33, tryptase ε/Prss22, implantation serine protease (Isp) 1/Prss28, and Isp-2 are constitutively exocytosed enzymes. We now demonstrate that tryptase 5/Prss32, pancreasin/Prss27, and testis serine protease-1 are inserted into plasma membranes via glycosylphosphatidylinositol (GPI) anchors analogous to Prss21, and that these serine proteases can be released from the cell’s surface by a phosphatidylinositol-specific phospholipase C. These data suggest that the C-terminal residues play key roles in determining where tryptases compartmentalize in cells. GPI-anchored proteins are targeted to lipid rafts. Thus, our identification of a number of GPI-anchored tryptases whose genes reside at mouse chromosome 17A3.3 also implicates important biological functions for this new family of serine proteases on the surfaces of cells.     

Nucleotide sequence and genomic organization of a human T lymphocyte serine protease gene

We have determined the nucleotide sequence of 4508 base pairs of human genomic DNA which contain the human serine esterase gene from cytotoxic T lymphocytes (SECT) (equivalent to the 1-3E cDNA clone) and include 879 bp of 5' flanking DNA and 393 bp of 3' flanking DNA. The gene consists of five exons of 88, 148, 136, 261, and 257 nucleotides separated by four introns of 1043, 455, 205, and 643 nucleotides. The location of introns with respect to protein coding sequences in the SECT gene is identical to that of the human cathepsin G and murine granzyme B genes. Comparison of SECT gene exonic sequences to murine granzyme B-F cDNA sequences indicates similarities of 75 and 72% for granzymes B and C and 61, 59, and 61% for granzymes D, E, and F, respectively. The 5' flanking sequence of the SECT gene showed similarity only to the 5' flanking sequence of the murine granzyme B gene, indicating that these genes are homologous. Comparison of the SECT gene sequence to the human cathepsin G sequence indicated no similarity in the 5' flanking DNA although the exonic sequences show 64% sequence similarity overall and 45% sequence similarity in the respective 3' untranslated regions. These similarities suggest that the SECT and cathepsin G genes are members of the same family of serine protease genes. Evidence from high and low stringency Southern transfer analysis of human genomic DNA indicates the presence of another gene of at least 85% sequence similarity to the SECT gene.     

Structure and expression of a cluster of human hematopoietic serine protease genes found on chromosome 14q11.2

We previously identified a cluster of hematopoietic serine protease genes on chromosome 14 at band q11.2. This cluster contains the cathepsin G gene and the two related cathepsin G-like genes CGL-1 and CGL-2. The CGL-1 gene is identical with the cytotoxic T cell serine protease CSP-B (also called SECT, and in mice, CCP1, granzyme B, or CTLA-1). In this report, we determined that CGL-2 is identical with a recently described gene called h-CCPX. The coding sequences of CG, CGL-1, and CGL-2 are 65-75% identical at the DNA level. The intervening sequences are much less conserved, except for introns 3 of the CGL-1 and CGL-2 genes, which are 93% identical. Each of the genes has the same overall organization, with 5 exons and 4 introns, very short 5' untranslated regions, and identical splice phases for all of the introns. Cathepsin G is expressed at high levels in promyelocytes/promonocytes, and CGL-1/CSP-B is expressed at high levels in activated cytolytic T cells, lymphokine-activated killer (LAK), and natural killer (NK) cells. CGL-2/h-CCPX is expressed at much lower levels in activated peripheral blood lymphocytes, LAK and NK cells. To begin to define the regulatory elements that target expression of each of these genes to their specific lineages at specific times, the 5' flanking region of each gene was sequenced. The 5' flanking regions are minimally related and have few conserved consensus elements. Further experiments will be required to determine the critical cis-acting regulatory sequences required for tissue- and development-specific expression of each of these genes.     

Identification and structural analysis of four serine proteases in a monotreme, the platypus, Ornithorhynchus anatinus

To study the emergence of the major subfamilies of serine proteases during vertebrate evolution, we present here the primary structure of four serine proteases expressed in the spleen of a monotreme, the platypus, Ornithorhynchus anatinus. Partial cDNA clones for four serine proteases were isolated by a PCR-based strategy. This strategy is based on the high level of sequence identity between various members of the large gene family of trypsin-related serine proteases, over two highly conserved regions, those of the histidine and the serine of the catalytic triad. The partial cDNA clones were used to isolate full-length or almost full-length cDNA clones for three of these proteases from a platypus spleen cDNA library. By phylogenetic analysis, these three clones were identified as being the platypus homologues of human coagulation factor X, neutrophil elastase, and a protease distantly related to the T-cell granzymes. The remaining partial clone was found to represent a close homologue of human complement factor D (adipsin). The isolation of these four clones shows that several of the major subfamilies of serine proteases had evolved as separate subfamilies long before the radiation of the major mammalian lineages of today, the monotremes, the marsupials, and the placental mammals. Upon comparison of the corresponding proteases of monotremes and eutherian mammals, the coagulation and complement proteases were shown to display a higher degree of conservation compared to the hematopoietic proteases N-elastase and the T-cell granzymes. This latter finding indicates a higher evolutionary pressure to maintain specific functions in the complement and coagulation enzymes compared to many of the hematopoietic serine proteases.     

Expansion of the mast cell chymase locus over the past 200 million years of mammalian evolution

The acidic granules of natural killer (NK) cells, T cells, mast cells, and neutrophils store large amounts of serine proteases. Functionally, these proteases are involved, e.g., in the induction of apoptosis, the recruitment of inflammatory cells, and the remodeling of extra-cellular matrix. Among the granule proteases are the phylogenetically related mast cell chymases, neutrophil cathepsin G, and T-cell granzymes (Gzm B to H and Gzm N), which share the characteristic absence of a Cys₁₉₁–Cys₂₂₀ bridge. The genes of these proteases are clustered in one locus, the mast cell chymase locus, in all previously investigated mammals. In this paper, we present a detailed analysis of the chymase locus in cattle (Bos taurus) and opossum (Monodelphis domestica). The gained information delineates the evolution of the chymase locus over more than 200 million years. Surprisingly, the cattle chymase locus contains two α-chymase and two cathepsin G genes where all other studied chymase loci have single genes. Moreover, the cattle locus holds at least four genes for duodenases, which are not found in other chymase loci. Interestingly, duodenases seem to have digestive rather than immune functions. In opossum, on the other hand, only two chymase locus-related genes have been identified. These two genes are not arranged in one locus, but appear to have been separated by a marsupial-specific chromosomal rearrangement. Phylogenetic analyses place one of the opossum genes firmly with mast cell α-chymases, which indicates that the α-chymase had already evolved as a separate, clearly identifiable gene before the separation of marsupials and placental mammals. In contrast, the second gene in opossum is positioned phylogenetically between granzymes, cathepsin G, and the duodenases. These genes, therefore, probably evolved as separate subfamilies after the separation of placental mammals from marsupials. In platypus, only one chymase locus-like sequence could be identified. This previously published “granzyme” does not cluster clearly with any of the chymase locus gene families, but shares the absence of the Cys₁₉₁–Cys₂₂₀ bridge with the other chymase locus proteases. These findings indicate that all chymase locus genes are derived from a single ancestor that was present more than 200 million years ago.     

Mast cell restricted mouse and human tryptase·heparin complexes hinder thrombin-induced coagulation of plasma and the generation of fibrin by proteolytically destroying fibrinogen

The mouse and human TPSB2 and TPSAB1 genes encode tetramer-forming tryptases stored in the secretory granules of mast cells (MCs) ionically bound to heparin-containing serglycin proteoglycans. In mice these genes encode mouse MC protease-6 (mMCP-6) and mMCP-7. The corresponding human genes encode a family of serine proteases that collectively are called hTryptase-β. We previously showed that the α chain of fibrinogen is a preferred substrate of mMCP-7. We now show that this plasma protein also is highly susceptible to degradation by hTryptase-β· and mMCP-6·heparin complexes and that Lys(575) is a preferred cleavage site in the protein α chain. Because cutaneous mouse MCs store substantial amounts of mMCP-6·heparin complexes in their secretory granules, the passive cutaneous anaphylaxis reaction was induced in the skin of mMCP-6(+)/mMCP-7(-) and mMCP-6(-)/mMCP-7(-) C57BL/6 mice. In support of the in vitro data, fibrin deposits were markedly increased in the skin of the double-deficient mice 6 h after IgE-sensitized animals were given the relevant antigen. Fibrinogen is a major constituent of the edema fluid that accumulates in tissues when MCs degranulate. Our discovery that mouse and human tetramer-forming tryptases destroy fibrinogen before this circulating protein can be converted to fibrin changes the paradigm of how MCs hinder fibrin deposition and blood coagulation internally. Because of the adverse consequences of fibrin deposits in tissues, our data explain why mice and humans lack a circulating protease inhibitor that rapidly inactivates MC tryptases and why mammals have two genes that encode tetramer-forming serine proteases that preferentially degrade fibrinogen.     

Endogenous thiol protease inhibitor from rat liver

A thiol protease inhibitor was purified from rat liver by a rapid procedure involving heat treatment of the post-lysosomal fraction, affinity chromatography on papain-Sepharose 4B and Sephadex G-75. The purified inhibitor appeared homogeneous on sodium dodecyl sulfate electrophoresis. The inhibitor had a molecular weight of about 11,500 and consisted of three forms (pI 4.9, 5.2 and 5.6). The preparation inhibited thiol proteases, such as papain, cathepsin H, cathepsin B and cathepsin L, but not serine proteases (trypsin, chymotrypsin, mast cell protease and cathepsin A) or cathepsin D.     

Isolation and molecular characterization of cathepsin L-like cysteine protease cDNAs from western flower thrips (Frankliniella occidentalis)

Cysteine proteases are predominant in thrips guts (TGs) and, therefore, a suitable target for selecting effective protease inhibitors against western flower thrips (Frankliniella occidentalis). We report the isolation of four full-length cysteine protease cDNA clones from thrips in a two-step PCR approach with degenerate oligonucleotides designed on conserved cathepsin L domains. At the deduced amino acid level, the clones possessed all functional and structural characteristics of cathepsin L, and showed high mutual identity and strong similarity with cathepsin L-like cysteine proteases from other insects and arthropods. Southern analysis indicated that a family of four closely related and 10-12 less-related genes encode the cathepsin L-like cysteine proteases in the thrips genome. Partial sequencing of genomic DNA demonstrated the presence of three introns in the coding DNA.