IL-1 beta-converting enzyme (ICE) cleaves pro-IL-1 beta to generate mature IL-1 beta. ICE is homologous to other proteins that have been implicated in apoptosis, including CED-3 and Nedd-2/lch-1. We generated ICE-deficient mice and observed that they are overtly normal but have a major defect in the production of mature IL-1 beta after stimulation with lipopolysaccharide. IL-1 alpha production is also impaired. ICE-deficient mice are resistant to endotoxic shock. Thymocytes and macrophages from the ICE-deficient animals undergo apoptosis normally. ICE therefore plays a dominant role in the generation of mature IL-1 beta, a previously unsuspected role in production of IL-1 alpha, but has no autonomous function in apoptosis.
Interferon-gamma-inducing factor (IGIF, interleukin-18) is a recently described cytokine that shares structural features with the interleukin-1 (IL-1) family of proteins and functional properties with IL-12. Like IL-12, IGIF is a potent inducer of interferon (IFN)-gamma from T cells and natural killer cells. IGIF is synthesized as a biologically inactive precursor molecule (proIGIF). The cellular production of IL-1beta, a cytokine implicated in a variety of inflammatory diseases, requires cleavage of its precursor (proIL-1beta) at an Asp-X site by interleukin-1beta-converting enzyme (ICE, recently termed caspase-1). The Asp-X sequence at the putative processing site in proIGIF suggests that a protease such as caspase-1 might be involved in the maturation of IGIF. Here we demonstrate that caspase-1 processes proIGIF and proIL-1beta with equivalent efficiencies in vitro. A selective caspase-1 inhibitor blocks both lipopolysaccharide-induced IL-1beta and IFN-gamma production from human mononuclear cells. Furthermore, caspase-1-deficient mice are defective in lipopolysaccharide-induced IFN-gamma production. Our results thus implicate caspase-1 in the physiological production of IGIF and demonstrate that it plays a critical role in the regulation of multiple proinflammatory cytokines. Specific caspase-1 inhibitors would provide a new class of anti-inflammatory drugs with multipotent action.
The caspase family represents a new class of intracellular cysteine proteases with known or suspected roles in cytokine maturation and apoptosis. These enzymes display a preference for Asp in the P1 position of substrates. To clarify differences in the biological roles of the interleukin-1 converting enzyme (ICE) family proteases, we have examined in detail the specificities beyond the P1 position of caspase-1, -2, -3, -4, -6, and -7 toward minimal length peptide substrates in vitro. We find differences and similarities between the enzymes that suggest a functional subgrouping of the family different from that based on overall sequence alignment. The primary specificities of ICE homologs explain many observed enzyme preferences for macromolecular substrates and can be used to support predictions of their natural function(s). The results also suggest the design of optimal peptidic substrates and inhibitors.A growing body of evidence supports important roles for the interleukin-1 converting enzyme (ICE) 1 (1, 2) and its homologs (recently renamed caspases (3)) in cytokine maturation and apoptosis. The caspase gene family, defined by protein sequence homology but also characterized by conservation of key catalytic and substrate-recognition amino acids, includes caspase-2 (4), caspase-3 (5-7), caspase-4 (8 -10), caspase-5 (10), caspase-6 (11), caspase-7 (12-14), caspase-8 (15-17), caspase-9 (18, 19), and caspase-10 (17). Each is an intracellular cysteine protease that shares with the serine protease granzyme B specificity for Asp in the P1 position of substrates. The specific biological roles and interrelationships of these enzymes are for the most part unknown and are areas of active investigation in many laboratories.A role for caspase-1 in inflammation is supported by several lines of evidence. Caspase-1-deficient mice, and cells derived from those animals, are deficient in IL-1 maturation and are resistant to endotoxic shock (20,21). Peptidic inhibitors of caspase-1 can be effective in blocking maturation and release of IL-1 by cultured cells (1) and in whole animals (22, 23) and of inflammation in animal models (24,25). The selectivity of the inhibitors employed in these studies among the caspases has not been demonstrated, and so the precise role of each caspase in inflammation is uncertain. Nevertheless the results uphold the promise of caspase-1 and/or its homologs as targets for anti-inflammatory drug discovery.Caspases play important roles in apoptosis signaling and effector mechanisms. Sequence alignments reveal homology with Ced-3 (26), a nematode cysteine protease (27, 28) that is required for cell death. The viral proteins CrmA and p35 are antiapoptotic and act by inhibition of caspases (29,30). A bacterial invasin induces apoptosis by binding to and activating caspase-1 specifically (31). Caspase-3 is necessary and sufficient for apoptosis in one acellular model (6); however, in mice the essential function of this enzyme is limited to apoptosis in the brain (32). A hallmark of apoptosis is the pr...
Binding of Fas ligand or an agonistic anti-Fas antibody induces apoptosis in Fas-bearing cells. The interleukin-1Beta-converting enzyme (ICE) is a cysteine protease that is involved in apoptosis induced by various stimuli, including Fas-mediated apoptosis. Several ICE homologues have been identified, and these are subdivided into three groups (ICE-, CPP32-, and Ich-1-like proteases). We show here that specific inhibitors of ICE- or CPP32-like proteases can inhibit Fas-mediated apoptosis. Transient ICE-like activity was found in the cytosolic fraction of Fas-activated cells, whereas ICE-dependent, CPP32-like activity gradually accumulated in the cytosol. Cell lysates from mouse lymphoma supplemented with either recombinant ICE or CPP32 induced apoptosis of nuclei. The CPP32 inhibitor inhibited ICE- or CPP32-induced apoptosis in the cell-free system, whereas the ICE-inhibitor only inhibited ICE-induced apoptosis. Cell extracts from thymocytes from ICE-null mice induced apoptosis in the cell-free system when it was supplemented with CPP32. These results indicate that Fas sequentially activates ICE- and CPP32-like proteases, and that downstream CPP32, together with a component(s) in the cytoplasm, causes apoptosis of nuclei.
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