Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P15088 (mast cell)
 14,925 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Incubation of oat root plasma membrane vesicles in the presence of ATP with trypsin or chymotrypsin increased the rate of ATP hydrolysis and ATP-dependent proton pumping by the plasma membrane H(+)-ATPase. Proton pumping was stimulated more than 200%, whereas ATP hydrolytic activity was stimulated about 30%. The Km (ATP) for both proton pumping and ATP hydrolysis was lowered from about 0.3 mM to below 0.1 mM. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of trypsin-treated plasma membranes revealed a decrease in a 100-kDa band and the appearance of a 93-kDa band. Western blot analysis using antibodies against the H(+)-ATPase showed that both of these bands represented the H(+)-ATPase and suggested that a 7-kDa segment was released. Extensive treatment with carboxypeptidase A also activated the H(+)-ATPase indicating that the 7-kDa segment originated from the C terminus.
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PMID:Proteolytic activation of the plant plasma membrane H(+)-ATPase by removal of a terminal segment. 214 84

The catalytic activity of human tryptase, a mast cell neutral endoprotease, is expressed when the enzyme is in its tetrameric form, but is lost under physiologic conditions concomitant with a quaternary structural alteration involving conversion to a monomeric form. The associated changes in the CD spectra noted in the current study indicate accompanying alterations in the secondary structure of the protein. In particular, the progressive disappearance of the negative minimum centered at 228 nm suggests an effect on beta-sheet structure, which may be important for monomer-monomer interaction and/or stabilization of catalytic activity. Dextran sulfate, like heparin, stabilizes the catalytic activity and quaternary structure of tryptase and also maintains the native secondary structure of the enzyme at and beyond a temperature of 40 degrees C. Dextran sulfate-stabilized tryptase therefore was used as an immunogen to which were produced three murine mAb (B2, C11, and G4) recognizing the catalytically active form of the enzyme. Inactive tryptase bound to plastic microtiter wells was not recognized by any of the newly made antibodies, whereas inactive tryptase in solution was recognized by G4, which when biotinylated, could be used as a detector antibody in a sandwich ELISA for tryptase. Each of the newly made mAb recognized the catalytically active form of tryptase. Thus, alterations in epitopes, perhaps reflecting tertiary structural alterations as well as changes in secondary and quaternary conformations, occur with tryptase inactivation. A pragmatic result of these newly generated antibodies is the affinity purification to homogeneity of active tryptase by sequential chromatography with B2 coupled to CH-Sepharose and heparin-agarose. Tryptase purified by this technique had a specific activity with p-tosyl-L-arginine methyl ester of 117 +/- 9 U/mg and had 3.9 +/- 0.3 active sites per molecule of active enzyme (134,000 m.w.) as titrated with p-nitrophenyl-p'-guanidinobenzoate. The spectral and immunologic data in the current study are consistent with concerted conformational alterations in the secondary and tertiary as well as quaternary structures of tryptase associated with loss of catalytic activity. Failure to reverse any of these alterations with dextran sulfate suggests that the pathway of tetramer assembly in vivo is more complicated than simple subunit association.
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PMID:Immunologic and physicochemical evidence for conformational changes occurring on conversion of human mast cell tryptase from active tetramer to inactive monomer. Production of monoclonal antibodies recognizing active tryptase. 217 9

Three different cDNAs and a gene encoding human skin mast cell tryptase have been cloned and sequenced in their entirety. The deduced amino acid sequences reveal a 30-amino acid prepropeptide followed by a 245-amino acid catalytic domain. The C-terminal undecapeptide of the human preprosequence is identical in dog tryptase and appears to be part of a prosequence unique among serine proteases. The differences among the three human tryptase catalytic domains include the loss of a consensus N-glycosylation site in one cDNA, which may explain some of the heterogeneity in size and susceptibility to deglycosylation seen in tryptase preparations. All three tryptase cDNAs are distinct from a recently reported cDNA obtained from a human lung mast cell library. A skin tryptase cDNA was used to isolate a human tryptase gene, the exons of which match one of the skin-derived cDNAs. The organization of the approximately 1.8-kilobase-pair tryptase gene is unique and is not closely related to that of any other mast cell or leukocyte serine protease. The 5' regulatory regions of the gene share features with those of other serine proteases, including mast cell chymase, but are unusual in being separated from the protein-coding sequence by an intron. High-stringency hybridization of a human genomic DNA blot with a fragment of the tryptase gene confirms the presence of multiple tryptase genes. These findings provide genetic evidence that human mast cell tryptases are the products of a multigene family.
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PMID:Human mast cell tryptase: multiple cDNAs and genes reveal a multigene serine protease family. 218 93

A second cDNA for human tryptase, called beta-tryptase, was cloned from a mast cell cDNA library in lambda ZAP. Its nucleotide sequence and corresponding amino acid sequence were determined and compared with those of a previously cloned tryptase cDNA, now called alpha-tryptase. The 1,142-base sequence of beta-tryptase encodes a 30-amino acid leader sequence of 3,089 D and a 245-amino acid catalytic region of 27,458 D. The amino acid sequence of beta-tryptase is 90% identical with that of alpha-tryptase, the first 20 amino acids of the catalytic portions being 100% identical. This identity, together with recognition of each recombinant protein by monoclonal antibodies directed against purified tryptase validate the tryptase identity of both alpha-tryptase and beta-tryptase cDNA molecules. Modest differences between the nucleic acid sequences of alpha- and beta-tryptase occurred throughout the cDNA molecules except in the 3' noncoding regions, which were identical. Although most highly conserved regions of amino acid sequence in the trypsin superfamily are conserved in both tryptase molecules, beta-tryptase has one carbohydrate binding site compared to two in alpha-tryptase, and one additional amino acid in the catalytic sequence. Regions of the substrate binding pocket in beta-tryptase (DSCQ, residues 218-221; SWG, residues 243-245) differ slightly from those in alpha-tryptase (DSCK, residues 217-220; SWD, residues 242-244). The presence of both alpha- and beta-tryptase sequences in each haploid genome was indicated by finding alpha- and beta-tryptase specific fragments after amplification by PCR of genomic DNA in 10 unrelated individuals. Localization of both alpha- and beta-tryptase sequences to human chromosome 16 was then performed by analysis of DNA preparations from 25 human/hamster somatic hybrids by PCR. It is now possible to assess the expression of each tryptase cDNA by mast cells and the relationship of each gene product to the active enzyme.
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PMID:Cloning and characterization of a second complementary DNA for human tryptase. 220 27

A chromogenic two-stage assay for human tryptase, a specific marker of mast cell activation, was developed based on the tryptase-induced conversion of prothrombin to thrombin. This assay proved to be more sensitive and reliable than measurements of amidolytic activity of tryptase with small synthetic substrates such as Bz-Arg-Nan and was suitable to detect tryptase activity in human body fluids. In addition, the assay was useful for studies of natural and recombinant inhibitors of tryptase.
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PMID:A new, highly sensitive enzymic assay for human tryptase and its use for identification of tryptase inhibitors. 220 44

Human mast cells can be divided into two subsets based on serine proteinase composition: a subset that contains the serine proteinases tryptase and chymase (MCTC), and a subset that contains only tryptase (MCT). In this study we examined both types of mast cells for two additional proteinases, cathepsin G and elastase, which are the major serine proteinases of neutrophils. Because human mast cell chymase and cathepsin G are both chymotrypsin-like proteinases, the properties of these enzymes were further defined to confirm their distinctiveness. Comparison of their N-terminal sequences showed 30% nonidentity over the first 35 amino acids, and comparison of their amino acid compositions demonstrated a marked difference in their Arg/Lys ratios, which was approximately 1 for chymase and 10 for cathepsin G. Endoglycosidase F treatment increased the electrophoretic mobility of chymase on SDS gels, indicating significant N-linked carbohydrate on chymase; no effect was observed on cathepsin G. Immunoprecipitation and immunoblotting with specific antisera to each proteinase revealed little, if any, detectable cross-reactivity. Immunocytochemical studies showed selective labelling of MCTC type mast cells by cathepsin G antiserum in sections of human skin, lung, and bowel. No labeling of mast cells by elastase antiserum was detected in the same tissues, or in dispersed mast cells from lung and skin. A protein cross-reactive with cathepsin G was identified in extracts of human skin mast cells by immunoblot analysis. This protein had a slightly higher Mr (30,000) than the predominant form of neutrophil cathepsin G (Mr 28,000), and could not be separated from chymase (Mr 30,000) by SDS gel electrophoresis because of the size similarity. Using casein, a protein substrate hydrolyzed at comparable rates by chymase and cathepsin G, it was shown that about 30% of the caseinolytic activity in mast cell extracts was sensitive to inhibitors of cathepsin G that had no effect on chymase. Hydrolytic activity characteristic of elastase was not detected in these extracts. These studies indicate that human MCTC mast cells may contain two different chymotrypsin-like proteinases: chymase and a proteinase more closely related to cathepsin G, both of which are undetectable in MCT mast cells. Neutrophil elastase, on the other hand, was not detected in human mast cells by our procedures.
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PMID:Identification of a cathepsin G-like proteinase in the MCTC type of human mast cell. 221 56

The susceptibility of connective tissue elements to degradation by human mast cells was explored using purified mast cell tryptase and sonicated mast cell preparations. The R-22 strain of smooth muscle cells from rat heart was used for preparation in vitro of a labelled anchored matrix. Digestion of 11.9 +/- 1.2% (n = 5) of this matrix was observed after overnight incubation with the mast cell sonicates. Pretreatment of the sonicate with a tryptase inhibitor TLCK reduced the digestion by 42%. Digestion of 12 +/- 1% (n = 4) of the matrix was observed with purified tryptase. The susceptible substrate within this anchored insoluble matrix resided in the glycoprotein compartment as defined by enzymatic characterization of the residual matrix. Mast cells may play a role in mediating connective tissue degradation through the release of proteases specifically synthesized by this cell.
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PMID:The mast cell as an effector of connective tissue degradation: a study of matrix susceptibility to human mast cells. 222 42

Tryptase, a mediator secreted by human mast cells during immediate reactions, has demonstrated effects on several pathways in vitro. This enzyme can rapidly inactivate fibrinogen and, as a complex with heparin, may prevent coagulation that may otherwise occur when plasma enters tissues at sites of immediate reactions. Tryptase may also activate prostromelysin, which in turn activates latent collagenase. When canine pulmonary smooth muscle is incubated with canine tryptase, the contractile response to histamine is increased. Tryptase, quantifiable in complex biologic fluids by immunoassay, can serve as a specific indicator of mast cell involvement in certain clinical settings. For example, after bee sting--induced anaphylaxis, tryptase levels in the blood peak at approximately 1 hour, then decline with a half-life of approximately 2 hours. Additionally, elevated tryptase levels in bronchoalveolar lavage fluid of asymptomatic, atopic persons with asthma suggest ongoing mast cell activation, which may relate to adenosine hyperresponsiveness and a persistence of bronchial hyperreactivity. Tryptase levels in bronchial lavage fluid of atopic patients with asthma rise markedly after endobronchial allergen challenge but not after an exercise challenge, suggesting a lack of mast cell involvement in the latter condition.
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PMID:Tryptase, a mediator of human mast cells. 222 22

Two types of mast cells were previously defined based on neutral protease composition and ultrastructurally distinguished by granule morphology. The MCT cell contains tryptase with little, if any, chymase and was noted to have varying numbers of irregularly-shaped granules with discrete scrolls or particulate or beaded material. The MCTC cell contains both tryptase and chymase and was noted to have more regularly-shaped electron-dense granules with characteristic grating or lattice substructures. This study reports the use of electron microscopy and immunogold staining with antibodies against tryptase and chymase to demonstrate in mature unstimulated MCTC cells in situ, the focal occurrence of discrete or complete scrolls in peripheral regions of certain granules where chymase is deficient. these scrolls often appeared to be protruding from the granule. Granules containing discrete scrolls were observed in 10 of 340 mature MCTC cells, accounting for less than 1% of MCTC granules. Other granules in such cells as well as other regions of the granule under consideration, showed strong staining for both tryptase and chymase. These results strengthen the association of morphology with protease composition in human mast cell secretory granules, but weaken the use of morphology alone to identify the MCTC and MCT types of human mast cells. Whether the uncommon occurrence of focal absence of chymase in MCTC cells arises by chance or as a result of factors relating to mast cell development, interconversion, activation, or regranulation will require further clarification. In conclusion, the appearance of grating or lattice structures in mast cells indicates the presence of chymase and tryptase, characteristic of the MCTC phenotype, whereas multiple discrete scrolls in irregularly shaped granules suggests the MCT phenotype.
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PMID:Human MCTC type of mast cell granule: the uncommon occurrence of discrete scrolls associated with focal absence of chymase. 223 9

Tissue mast cells play a central role in immediate hypersensitivity reactions. The clinical manifestations of these reactions appear to be dependent, in large part, on the anatomic location of the stimulated mast cells and the type of mediators released. In vivo and in vitro studies indicate that the tissues in which mast cells reside may greatly influence their biochemical composition, expression of surface receptors, and response to potential stimuli. Although all human mast cells in different organs store similar concentrations of histamine, heparin, and tryptase, cutaneous mast cells appear to be the predominant source of mast cell-derived chymase. Furthermore, at the time of stimulation, human skin mast cells predominantly form PGD2, whereas lung and intestinal mast cells generate LTB4, LTC4, and PGD2. Functional studies indicate that human cutaneous mast cells differ from human lung, heart, and intestinal mast cells. Skin mast cells are responsive to a variety of immunologic and nonimmunologic stimuli in vitro, whereas human pulmonary, cardiac, and intestinal mast cells are relatively refractory to many of these stimulatory signals. Taken together, these observations indicate that mast cells may assume different, and possibly specialized, functions within a specific tissue. Such site-to-site variation potentially could have important clinical significance, to the extent that information gained from mast cells in one organ may not be applicable to a mast cell population in a different tissue. Furthermore, these differences among human mast cells may not be confined to their biochemical composition and responses to various stimuli, but also may extend to the effectiveness of different anti-allergic preparations. Therefore, these observations underscore the importance of continued detailed investigation of human mast cells from different anatomic sites.
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PMID:IgE and immediate hypersensitivity. 224 56


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