The mechanism underlying the differentiation of CD4+ T cells into functionally distinct subsets (Th1 and Th2) is incompletely understood, and hitherto unidentified cytokines may be required for the functional maturation of these cells. Here we report the cloning of a recently identified IFN-gamma-inducing factor (IGIF) that augments natural killer (NK) activity in spleen cells. The gene encodes a precursor protein of 192 amino acids and a mature protein of 157 amino acids, which have no obvious similarities to any peptide in the databases. Messenger RNAs for IGIF and interleukin-12 (IL-12) are readily detected in Kupffer cells and activated macrophages. Recombinant IGIF induces IFN-gamma more potently than does IL-12, apparently through a separate pathway. Administration of anti-IGIF antibodies prevents liver damage in mice inoculated with Propionibacterium acnes and challenged with lipopolysaccharide, which induces toxic shock. IGIF may be involved in the development of Th1 cells and also in mechanisms of tissue injury in inflammatory reactions.
The interleukin-1beta (IL-1beta) converting enzyme (ICE) processes the inactive IL-1beta precursor to the proinflammatory cytokine. ICE was also shown to cleave the precursor of interferon-gamma inducing factor (IGIF) at the authentic processing site with high efficiency, thereby activating IGIF and facilitating its export. Lipopolysaccharide-activated ICE-deficient (ICE-/-) Kupffer cells synthesized the IGIF precursor but failed to process it into the active form. Interferon-gamma and IGIF were diminished in the sera of ICE-/- mice exposed to Propionibacterium acnes and lipopolysaccharide. The lack of multiple proinflammatory cytokines in ICE-/- mice may account for their protection from septic shock.
Interferon‐γ‐inducing factor enhances T helper 1 cytokine production by stimulated human T cells: synergism with interleukin‐12 for interferon‐γ production
The novel cytokine interferon-gamma-inducing factor (IGIF) augments natural killer (NK) cell activity in cultures of human peripheral blood mononuclear cells (PBMC), similarly to the structurally unrelated cytokine interleukin (IL)-12. IGIF has been found to enhance the production of interferon-gamma (IFN-gamma) and granulocyte/macrophage colony-stimulating factor (GM-CSF) while inhibiting the production of IL-10 in concanavalin A (Con A)-stimulated PBMC. In this study, when anti-CD3 monoclonal antibody (mAb)-stimulated human enriched T cells were exposed to IGIF, the cytokine dose-dependently enhanced the proliferation of the cells and this could be completely inhibited by a neutralizing antibody against IL-2 at lower concentrations of IGIF. Neutralizing antibody against IFN-gamma had only insignificant inhibitory effects on T cell proliferation at higher concentrations of IGIF. Enzyme-linked immunosorbent assays (ELISA) revealed that, like PBMC, T cells exposed to IGIF produced large amounts of IFN-gamma; however, changes in the production of IL-4 and IL-10 were minimal. IGIF, but not IL-12, significantly enhanced IL-2 and GM-CSF production in T cell cultures, as determined by CTLL-2 bioassay and ELISA, respectively; however, both IGIF and IL-12 enhanced IFN-gamma production by the T cells. When T cells were exposed to a combination of IGIF and IL-12, a synergistic effect was observed on the production of IFN-gamma, but not on production of IL-2 and GM-CSF. In conclusion, IGIF enhances T cell proliferation apparently through an IL-2-dependent pathway and enhances Th1 cytokine production in vitro and exhibits synergism when combined with IL-12 in terms of enhanced IFN-gamma production but not IL-2 and GM-CSF production. Based on structural and functional differences from any known cytokines, it was recently proposed that this cytokine be designated interleukin-18.
Recently, human interleukin 18 (hIL-18) cDNA was cloned, and the recombinant protein with a tentatively assigned NH 2 -terminal amino acid sequence was generated. However, natural hIL-18 has not yet been isolated, and its cellular processing is therefore still unclear. To clarify this, we purified natural hIL-18 from the cytosolic extract of monocytic THP.1 cells. Natural hIL-18 exhibited a molecular mass of 18.2 kDa, and the NH 2 -terminal amino acid was Tyr 37 . Biological activities of the purified protein were identical to those of recombinant hIL-18 with respect to the enhancement of natural killer cell cytotoxicity and interferon-␥ production by human peripheral blood mononuclear cells. We also found two precursor hIL-18 (prohIL-18)-processing activities in the cytosol of THP.1 cells. These activities were blocked separately by the caspase inhibitors Ac-YVAD-CHO and Ac-DEVD-CHO. Further analyses of the partially purified enzymes revealed that one is caspase-1, which cleaves prohIL-18 at the Asp 36 -Tyr 37 site to generate the mature hIL-18, and the other is caspase-3, which cleaves both precursor and mature hIL-18 at Asp 71 -Ser 72 and Asp 76 -Asn 77 to generate biologically inactive products. These results suggest that the production and processing of natural hIL-18 are regulated by two processing enzymes, caspase-1 and caspase-3, in THP.1 cells. Interleukin (IL)1 -18 (originally called IGIF, interferon-␥-inducing factor) is a novel cytokine with multiple biological functions. In 1995 we purified murine IL-18 from the liver extracts of mice sensitized with Propionibacterium acnes followed by elicitation with lipopolysaccaride (1). The cDNA of murine IL-18 was cloned from cDNA libraries prepared from the livers of mice with endotoxin shock (2). Using this as a probe, human IL-18 cDNA was also cloned from a human normal liver cDNA library (3). The recombinant human IL-18 with a tentatively assigned NH 2 -terminal amino acid based on its homology with the natural murine IL-18 sequence was expressed in Escherichia coli, and its biological activities were examined (3).IL-18 has an interleukin 1 (IL-1) signature-like sequence (3) as reported and is similar to the IL-1 family and fibroblast growth factor in terms of their trefoil structures (4, 5). Despite their similarities, IL-18 and IL-1 exhibit different biological activities (2, 3, 6), transmitted through their specific receptors.2 Genetic information suggested that IL-18 is synthesized as an inactive precursor form (prohIL-18) and that this prohIL-18 has no known signal peptide sequence. Therefore, proteolytic cleavage is required for its maturation like IL-1 (2, 3, 7, 8). Gu et al. (7) reported that IL-1-converting enzyme (ICE)/ caspase-1 cleaved murine proIL-18 at the authentic processing site, Asp 35 -Asn 36 , to generate biologically active mature murine IL-18. However, natural hIL-18 had not yet been isolated, and its maturation site remained unclear.In this report, we screened for hIL-18 mRNA-expressing cell lines and purified natural hIL-18 from ...
Objective Interleukin‐18 (IL‐18) is a proinflammatory cytokine that is involved in immunologically mediated tissue damage, but its bioactivity is regulated in vivo by its soluble decoy receptor, IL‐18 binding protein (IL‐18BP). This study was undertaken to determine levels of IL‐18 and IL‐18 binding inhibition in the blood of patients with adult‐onset Still's disease (ASD). Methods Serum concentrations of IL‐18 in ASD patients were compared by enzyme‐linked immunosorbent assay (ELISA) with those in patients with other systemic rheumatic diseases and healthy controls. The biologically active mature protein of IL‐18 was detected by Western blot analysis with anti–IL‐18 antibody and its induction of interferon‐γ (IFNγ) secretion from IL‐18–responding human myelomonocytic KG‐1 cells. The inhibitory activity on IL‐18 binding to its receptor was determined by 125I–IL‐18 binding inhibition assay using the Chinese hamster ovary cell line transfected with a murine IL‐18 receptor (CHO‐K1/mIL‐18R). Results Concentrations of serum IL‐18 were extremely elevated in patients with active ASD compared with those in patients with rheumatoid arthritis, systemic lupus erythematosus, systemic sclerosis, polymyositis/dermatomyositis, Sjögren's syndrome, or healthy individuals. Levels of IL‐18 were found to correlate with serum ferritin values and disease severity in ASD. Western blot analysis revealed that serum samples from patients with active ASD contained an 18‐kd polypeptide of IL‐18, corresponding in size to the mature form. Accordingly, the samples were able to induce IFNγ secretion from KG‐1 cells, which was largely abolished by neutralizing anti–IL‐18 antibody. However, the level of IL‐18 bioactivity was more than 10‐fold weaker than the concentration of IL‐18 protein measured by ELISA. Serum samples from patients with active ASD showed an inhibitory effect on the binding of 125I–IL‐18 to CHO‐K1/mIL‐18R cells, and this activity was associated with elevation of IL‐18. Conclusion These data indicate that systemic overproduction of IL‐18 may be closely related to the pathogenesis of ASD, despite the restriction on its inflammatory activity by IL‐18 binding inhibitors such as IL‐18BP. The disease activity appears to be determined on the basis of the relative levels of IL‐18 and its specific inhibitors.
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