Mature Interleukin-18 Research Articles

Successful immunogene therapy using colon cancer cells (colon 26) transfected with plasmid vector containing mature interleukin-18 cDNA and the Igkappa leader sequence.

IL-18 is a novel cytokine that induces interferon (IFN)-gamma secretion and plays an important role in antitumor immunity. In the present study, we constructed plasmid vectors encoding the murine mature IL-18 cDNA linked with the Igkappa leader sequence and the pro-IL-18 cDNA to estimate the efficacy of the mature IL- 18 vector and to evaluate IL-18--producing tumor cells as a tumor vaccine. Colon 26 cells were transfected with the abovementioned vectors or with vector alone (mock). Reverse transcription-polymerase chain reaction analysis showed increased expression of murine IL-18 cDNA in both mature IL-18 and pro-IL-18 transfectants in comparison to that in mock transfected cells. The ability of the culture supernatants of mature IL-18 transfectants to induce IFN-gamma secretion was extremely high (40-140 pg/10(6) cells) in comparison to that of pro-IL-18 transfectants (4-18 pg/10(6) cells). When injected into syngeneic BALB/c mice, the growth of mature IL-18 transfectants, but not pro-IL-18 transfectants, was significantly less than that in mock transfected cells ( P< .01, by ANOVA and analysis of covariance). In addition, injection of colon 26 or Meth-A cells into mice immunized with a mature IL-18 transfectant revealed acquired immunity. Depletion of natural killer cells did not affect the growth of transfectants. However, the growth inhibitory effects were partially abrogated following treatment with anti-CD4+ and anti-CD8+ antibodies. These data suggest that the rejection of mature IL-18/colon 26 cells was mediated through T-cell activation. Gene therapy using mature IL-18 transfectants containing a plasmid vector and the Igkappa leader sequence may be a useful tumor vaccine.

Activation of intestinal mucosal immunity in tumor-bearing mice by lactoferrin.

We have previously demonstrated that oral administration of bovine lactoferrin (bLF) markedly increases CD4+ and CD8+ T cells and NK (asialoGM1+) cells in the blood of tumor‐bearing mice and enhances anti‐metastatic activity. In this paper, we document that oral administration of bLF and bLF‐hydrolysate (bLFH) is associated with strong increases in CD4+ and CD8+ T, as well as asialoGM1+ cells in lymphoid tissues and lamina propria of the small intestine in mice, especially in tumor‐bearing animals in which Co26Lu cells were implanted subcutaneously. Moreover, IgM+ and IgA+ B cells in lamina propria of the small intestine were also significantly increased by bLF and bLFH. Bovine apo‐transferrin (bTF) did not exhibit such activity. In the colon, only CD8+ cells were significantly increased by treatment with bLF, while asialoGM1+ cells were significantly decreased. bLF and bLFH induced cytokines to activate T, B and asialoGM1+ cells. Administration of bLF and bLFH, but not bTF, increased production of interleukin‐18 (IL‐18), interferon‐gamma (IFN‐γ) and caspase‐1 in the mucosa of the small intestine. Particularly high levels of IL‐18 were found in the epithelial cells of the small intestine. Moreover, administration of bLF and bLFH, but not bTF, induced IFN‐γ presenting cells in the small intestine. Caspase‐1, which processes proIL‐18 to mature IL‐18, was also induced in the epithelial cells of the small intestine following treatment with bLF and bLFH, but not with bTF. These results suggest that enhanced production of IL‐18 and IFN‐γ and caspase‐1 induction by treatment with bLF may be important for elevation of intestinal mucosal immunity.

PORCINE INTERLEUKIN 18: CLONING, CHARACTERIZATION OF THE cDNA AND EXPRESSION WITH THE BACULOVIRUS SYSTEM

We have isolated and sequenced a cDNA that contains the coding sequence of porcine interleukin 18 (IL-18) and the recombinant protein of porcine IL-18 was expressed using the baculovirus system. The open reading frame (ORF) of the porcine IL-18 cDNA is 579 base pairs (bp) in length and encodes 192 amino acids. The predicted amino acid sequence is 76.7%, 64.7% and 61.6% homologous to the predicted human, murine and rat amino acid sequences, respectively. The porcine precursor and mature IL-18 protein were expressed respectively in Trichoplusia ni -derived (Tn5) cells using the baculovirus Autografha californica nuclear polyhedorosis virus (AcNPV) as a vector. Tn5 cells infected with recombinant virus containing a whole IL-18 protein coding region sequence secreted porcine precursor IL-18 into the culture medium. On the other hand, Tn5 cells infected with recombinant virus containing a mature IL-18 protein coding region sequence expressed several proteins in the cell lysates, but did not secrete mature protein into the culture medium efficiently. Immunoblotting analysis of recombinant protein showed cross-reactivity with anti-human IL-18 polyclonal antibody. The mature form of porcine IL-18 protein induced IFN-γ production in suboptimal doses of anti-CD3 antibody and concanavalin A- (ConA) stimulated porcine peripheral blood mononuclear cells (PBMC), but the precursor form had little effect.

Production of monoclonal antibodies to porcine interleukin-18 and their use for immunoaffinity purification of recombinant porcine interleukin-18

We have recently reported the cloning and expression of porcine interleukin-18 (IL-18). In this study, we describe the production of anti-porcine IL-18 monoclonal antibodies (mAb) and their use in the purification of a large amount of recombinant porcine IL-18 by immunoaffinity column chromatography. Five monoclonal antibodies (2-2-B, 2-5-B, 2-13-C, 3-1-C and 5-3-B) were established and characterized. Three (2-2-B, 3-1-C and 5-3-B) of them were of IgG1 subclass, and the other two were IgMs. Epitope analysis of the three IgG1 mAbs showed that they recognized the same epitope. All five mAbs demonstrated reactivity with baculovirus generated porcine IL-18 by immunoblot analysis. Biologically active porcine IL-18 was obtained by immunoaffinity chromatography using anti-porcine IL-18 mAb at more than 85% purity from culture supernatants of Trichoplusia ni (Tn5) derived cells infected with recombinant baculovirus containing the coding sequence of porcine mature IL-18. These results suggest that the anti-porcine IL-18 mAbs established in this study are useful for one-step purification of porcine mature IL-18 as well as the detection of porcine IL-18 by immunoblotting.

Potent antitumor effects mediated by local expression of the mature form of the interferon-gamma inducing factor, interleukin-18 (IL-18).

IL-18 is produced during the acute immune response by macrophages and immature dendritic cells. IL-18 receptors are induced on T cells and NK cells by IL-12 and together they enhance a cellular immune response. We constructed retroviral and adenoviral vectors encoding the mature bioactive murine IL-18 in order to examine their immune and antitumor effects in murine tumor models. Secretion of bioactive IL-18 from murine tumor cells was facilitated by transfecting them with recombinant viral vectors carrying the prepro leader sequence of human parathyroid hormone fused to the 5' end of the mature murine IL-18 cDNA. Direct injection of the IL-18 recombinant adenoviral vector (Ad.PTH.IL-18) into an established MCA205 murine fibrosarcoma completely eradicated tumor in all animals with concomitant induction of protective systemic immunity. Co-administration of systemic IL-12 provided synergistic antitumor effects when combined with peritumoral injections of Ad.PTH.IL-18 without apparent side-effects as we observed with systemic administration of IL-18. Depletion of asialo GM-1+ cells completely abrogated the antitumor effects of Ad.PTH.IL-18, suggesting a major role for NK cells in mediating the anti-tumor effects of IL-18. Peritumoral injection of Ad.PTH.IL-18 was also associated with reduced numbers of CD8+ cells found within the tumor (HBSS versus Ad.PTH.IL-18, P < 0.0001). This suggests that IL-18 could be utilized as an alternative cancer gene therapy especially when combined with systemic administration of IL-12.