Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.4.21.79 (granzyme B)
 3,301 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Cultured natural killer (NK) cells derived from CD3- CD56+ high-density small lymphocytes (HDLs) exhibit similar morphology and high levels of non-major histocompatibility complex-restricted (NK) cytotoxicity equivalent to those of cultured NK cells from CD3- CD56+ low-density large granular lymphocytes (LGLs). To examine the similarities and differences between NK cells from HDLs and NK cells from LGLs, we investigated the expression of three distinct members of the granule serine protease (granzyme) family within cultured CD3- CD56+ LGLs and HDLs. CD3- subpopulations of nonadherent peripheral blood mononuclear cells, LGLs (density < 1.063 g/ml), and HDLs (density > 1.063 g/ml) were stimulated to proliferate in culture. The cultured cells from each population were entirely CD3- CD56+ and were indistinguishable in terms of their increased granularity and size once activated. All cultured CD3- CD56+ LGLs and HDLs displayed cytolytic activity against K562 and immunoglobulin-coated P815. Western analysis detected perforin in both cultured LGL and HDL populations. Cultured HDLs and LGLs both expressed BLT-esterase activity and human granzyme A mRNA. Granzyme B mRNA and protein and Asp-ase activity were detected in unstimulated and cultured LGLs and cultured HDLs. By contrast, unstimulated HDLs did not express significant levels of granzyme B. High levels of Hu-Met-1 granzyme mRNA and Met-ase activity were detected only in cultured LGLs. Thus, despite the development of large granular morphology during proliferation, interleukin-2 cultured CD3- CD56+ HDLs display a different pattern of granzyme expression from CD3- CD56+ LGLs. These data also further suggest an unusually restricted expression of the Hu-Met-1 granzyme in LGLs.
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PMID:Distinct granzyme expression in human CD3- CD56+ large granular- and CD3- CD56+ small high density-lymphocytes displaying non-MHC-restricted cytolytic activity. 753 Feb 84

Natural killer (NK) and cytotoxic T-lymphocytes (CTLs) kill cells within an organism to defend it against viral infections and the growth of tumors. One mechanism of killing involves exocytosis of lymphocyte granules which causes pores to form in the membranes of the attacked cells, fragments nuclear DNA and leads to cell death. The cytotoxic granules contain perforin, a pore-forming protein, and a family of at least 11 serine proteases termed granzymes. Both perforin and granzymes are involved in the lytic activity. Although the biological functions of most granzymes remain to be resolved, granzyme B clearly promotes DNA fragmentation and is directly involved in cell death. Potential natural substrates for Gr B include procaspases and other proteins involved in cell death. Activated caspases are involved in apoptosis. The search continues for natural substrates for the other granzymes. The first granzyme crystal structure remains to be resolved, but in the interim, molecular models of granzymes have provided valuable structural information about their substrate binding sites. The information has been useful to predict the amino acid sequences that immediately flank each side of the scissile peptide bond of peptide and protein substrates. Synthetic substrates, such as peptide thioesters, nitroanilides and aminomethylcoumarins, have also been used to study the substrate specificity of granzymes. The different granzymes have one of four primary substrate specificities: tryptase (cleaving after Arg or Lys), Asp-ase (cleaving after Asp), Met-ase (cleaving after Met or Leu), and chymase (cleaving after Phe, Tyr, or Trp). Natural serpins and synthetic inhibitors (including isocoumarins, peptide chloromethyl ketones, and peptide phosphonates) inhibit granzymes. Studies of substrate and inhibitor kinetics are providing valuable information to identify the most likely natural granzyme substrates and provide tools for the study of key reactions in the cytolytic mechanism.
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PMID:Granzymes (lymphocyte serine proteases): characterization with natural and synthetic substrates and inhibitors. 1070 66

Cytotoxic lymphocytes (CTLs), the key players of cell mediated immunity, induce apoptosis by engaging death receptors or through exocytosis of cytolytic granules containing granzyme (proteases) and pore-forming protein (perforin). The crystal structure of granzyme B from human (B(h)) and rat (B(r)), as well as that of pro-granzyme K (K(h)) has been reported recently. In the present communication, we describe the homology modeling of granzyme family (in particular Gzm A(h), M(h), B(m), and C(m) from human and mouse) based on the crystal structural coordinates of trypsin, granzyme K (K(h)), and granzyme B (B(h)). These models have been used for establishing phylogenetic relationship as well as identifying characteristic features for designing specific inhibitors. The paper also highlights key residues at the S1, S2, and S2(') binding subsites in all granzyme, which may be involved in the structure-function relationship of this enzyme family. The predicted 3D homology models show a conserved two similar domain structure, i.e., an N-terminal domain and a C-terminal domain comprising predominantly of beta-sheet structure with a little alpha-helical content. Micro-heterogeneities have been observed in the vicinity of the active site in all granzymes as compared to granzyme B(h). For example, in granzyme M(h), valine is present at the S1 subsite instead of arginine. Similarly differences at S2 (Leu-->Phe), S3 (Ser-->Gly), and S4 (Arg-->Asn) subsites are quite apparent and appear to hold the potential for selective designing of inhibitors for possible therapeutic applications. Furthermore, analysis of the electrostatic surface potential on the shape of granzyme-inhibitor binding groove reveals clear differences at the reactive site. Additionally the different posttranslational modification sites such as phosphorylation (e.g., in granzyme M Thr101, Ser109), myristoylation (Gly22, 117, and 131), and glycosylation (Ser160) have been identified, as very little is known about the functional significance of these modifications in the granzyme family. Thus, glycosylation at Ser160 in granzyme M may influence the net charge of the enzyme, resulting in altered substrate binding as compared to granzyme B. Also this modification may influence the rate of complexation and binding affinity with proteoglycans. These studies are expected to contribute towards the basic understanding of functional associations of the granzymes with other molecules and their possible role in apoptosis.
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PMID:Bioinformatics of granzymes: sequence comparison and structural studies on granzyme family by homology modeling. 1292 79

Cell death is mediated by cytotoxic lymphocytes through various granule serine proteases released with perforin. The unique protease activity, restricted expression, and distinct gene locus of granzyme M suggested this enzyme might have a novel biological function or trigger a novel form of cell death. Herein, we demonstrate that in the presence of perforin, the protease activity of granzyme M rapidly and effectively induces target cell death. In contrast to granzyme B, cell death induced by granzyme M does not feature obvious DNA fragmentation, occurs independently of caspases, caspase activation, and perturbation of mitochondria and is not inhibited by overexpression of Bcl-2. These data raise the likelihood that granzyme M represents a third major and specialized perforin-dependent cell death pathway that plays a significant role in death mediated by NK cells.
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PMID:Granzyme M mediates a novel form of perforin-dependent cell death. 1502 22

Tumors have several mechanisms to escape from the immune system. One of these involves expression of intracellular anticytotoxic proteins that modulate the execution of cell death. Previously, we have shown that the serine protease inhibitor (serpin) SPI-6, which inactivates the cytotoxic protease granzyme B (GrB), is capable of preventing cytotoxic T lymphocyte (CTL)-mediated apoptosis. Despite its potent antiapoptotic activity, SPI-6 does not prevent membranolysis induced by cytotoxic lymphocytes. We now provide evidence that several colon carcinoma cell lines do resist membranolysis and that this protection is dependent on SPI-6 but also requires expression of a closely related serpin called SPI-CI (serine protease inhibitor involved in cytotoxicity inhibition). Expression of SPI-CI is absent from normal colon but observed in placenta, testis, early during embryogenesis, and in cytotoxic lymphocytes. SPI-CI encodes a chymotrypsin-specific inhibitor and irreversibly interacts with purified granzyme M. Moreover, SPI-CI can protect cells from purified perforin/GrM-induced lysis. Our data therefore indicate that SPI-CI is a novel immune escape molecule that acts in concert with SPI-6 to prevent cytotoxic lymphocyte-mediated killing of tumor cells.
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PMID:SPI-CI and SPI-6 cooperate in the protection from effector cell-mediated cytotoxicity. 1545 90

Granzyme M is a trypsin-fold serine protease that is specifically found in the granules of natural killer cells. This enzyme has been implicated recently in the induction of target cell death by cytotoxic lymphocytes, but unlike granzymes A and B, the molecular mechanism of action of granzyme M is unknown. We have characterized the extended substrate specificity of human granzyme M by using purified recombinant enzyme, several positional scanning libraries of coumarin substrates, and a panel of individual p-nitroanilide and coumarin substrates. In contrast to previous studies conducted using thiobenzyl ester substrates (Smyth, M. J., O'Connor, M. D., Trapani, J. A., Kershaw, M. H., and Brinkworth, R. I. (1996) J. Immunol. 156, 4174-4181), a strong preference for leucine at P1 over methionine was demonstrated. The extended substrate specificity was determined to be lysine = norleucine at P4, broad at P3, proline > alanine at P2, and leucine > norleucine > methionine at P1. The enzyme activity was found to be highly dependent on the length and sequence of substrates, indicative of a regulatory function for human granzyme M. Finally, the interaction between granzyme M and the serpins alpha(1)-antichymotrypsin, alpha(1)-proteinase inhibitor, and proteinase inhibitor 9 was characterized by using a candidate-based approach to identify potential endogenous inhibitors. Proteinase inhibitor 9 was effectively hydrolyzed and inactivated by human granzyme M, raising the possibility that this orphan granzyme bypasses proteinase inhibitor 9 inhibition of granzyme B.
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PMID:Granzyme M is a regulatory protease that inactivates proteinase inhibitor 9, an endogenous inhibitor of granzyme B. 1549 98

Expression of serine protease inhibitors (serpins) is one of the mechanisms used by tumour cells to escape immune surveillance. Previously, we have shown that expression of serpins SPI-6 and SPI-CI, respectively, renders tumour cells resistant to granzyme B (GrB)-mediated death and granzyme M (GrM)-mediated death. To obtain better insight into the interaction between serpins and their target proteases, we investigated the roles of protease inhibitor (PI)-9 and SPI-6 in the resistance to GrB-mediated and CD95-mediated death in further detail. Neither human PI-9 nor its murine orthologue SPI-6 was capable of preventing CD95-induced apoptosis in murine or human cells, indicating that these serpins do not inhibit the activation of apical caspases in this pathway. High expression of PI-9 or SPI-6 did prevent apoptosis induced by human GrB. Strikingly, only SPI-6, and not PI-9, was capable of inhibiting murine GrB, suggesting that a difference in enzymatic specificity exists between the mouse and the human granzymes. In agreement with this suggestion, murine GrB was clearly less effective in inducing apoptosis in human cells. Similar species specificity was also observed for SPI-CI and GrM when either their capacity to associate or the effectiveness of GrM-induced cytotoxicity was analysed. Our findings therefore indicate a species diversity that has a clear effect on mixed in vitro effector target settings.
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PMID:Serpins prevent granzyme-induced death in a species-specific manner. 1640 55

Natural killer (NK) cells kill virus-infected or transformed target cells by delivering cytotoxic proteases called granzymes to the target cell cytosol. One of these proteases, granzyme M, is specifically expressed in NK cells and is thought to instigate a form of cell death distinct from that mediated by granzyme A or granzyme B. However, the mechanism of granzyme M-induced cell death is unclear at present, and few substrates for this granzyme have been reported to date. Here we show that the abundant nucleolar phosphoprotein, nucleophosmin (NPM), is cleaved and inactivated by granzyme M. NPM is essential for cell viability as RNA interference-mediated ablation of NPM expression in human cells resulted in spontaneous apoptosis. Significantly, overexpression of wild-type NPM rescued cells treated with NPM small interference RNA, whereas overexpression of the granzyme M-cleaved form of NPM did not. Because NPM is essential for cell viability, these data suggest that targeting of NPM by granzyme M may contribute to tumor cell eradication by abolishing NPM function.
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PMID:Nucleophosmin is cleaved and inactivated by the cytotoxic granule protease granzyme M during natural killer cell-mediated killing. 1910 89

The granule-exocytosis pathway is the major mechanism for cytotoxic lymphocytes to kill tumor cells and virus-infected cells. Cytotoxic granules contain the pore-forming protein perforin and a set of structurally homologues serine proteases called granzymes. Perforin facilitates the entry of granzymes into a target cell, allowing these proteases to initiate distinct cell death routes by cleaving specific intracellular substrates. The family of granzymes consists of multiple members, of which granzyme A and granzyme B have been studied most extensively. Since the cloning of the granzyme M cDNA in the early 1990s, it has remained an "orphan" granzyme for many years and only during the past few years the interest in this protease has increased. Granzyme M appears to be a potent inducer of tumor cell death with morphological hallmarks that are unique among all granzymes. In this review, we summarize the characteristics of granzyme M that are currently known, including its cellular expression, substrate specificity, physiological functions, and inhibitors.
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PMID:Biology of granzyme M: a serine protease with unique features. 1967 85

Lymphocyte perforin and serine protease granzymes are well-recognized extrinsic mediators of apoptosis. We now demonstrate that cytotoxic lymphocyte granule components profoundly augment the myeloid cell inflammatory cytokine cascade in response to TLR4 ligation. Whereas caspase-1-deficient mice were completely resistant to LPS, reduced serum cytokine production and resistance to lethal endotoxicosis were also obtained with perforin-deficient mice, indicating a role for granzymes. Consistently, a lack of granzyme M (GrzM) resulted in reduced serum IL-1alpha, IL-1beta, TNF, and IFN-gamma levels and significantly reduced susceptibility to lethal endotoxicosis. These altered responses were also observed in granzyme A-deficient but not granzyme B-deficient mice. A role for APC-NK cell cross-talk in the inflammatory cascade was highlighted, as GrzM was exclusively expressed by NK cells and resistance to LPS was also observed on a RAG-1/GrzM-double deficient background. Collectively, the data suggest that NK cell GrzM augments the inflammatory cascade downstream of LPS-TLR4 signaling, which ultimately results in lethal endotoxicosis. Most importantly, these data demonstrate that granzymes should no longer be considered solely as mediators of apoptosis, but additionally as potential key regulators of inflammation.
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PMID:A role for granzyme M in TLR4-driven inflammation and endotoxicosis. 2058 36


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