Rat interleukin-2 immunoglobulin M fusion proteins are cytotoxic in vitro for cells expressing the IL-2 receptor and can abolish cell-mediated immunity in vivo

Suppression of the cell-mediated immune response by a Fas-immunoglobulin fusion protein

INTRODUCTION

Immunosuppressive agents must not only be effective in impairing the host's allo-immune response, but should also be selective in targeting only those elements of the immune system activated by the allograft. The fact that allo-activated T cells express surface protein molecules that are not typically present on resting T cells can be exploited to specifically target this population. Fas ligand is one such molecule whose cell surface expression on T cells is dramatically up-regulated upon activation.

METHODS

We constructed a murine fusion protein by linking the extracellular domain of Fas to the Fc region of IgG2a. The rationale being to selectively target activated T cells via binding of its Fas moiety to cell surface Fas ligand, and then to allow the Fc moiety to invoke its usual effector mechanisms resulting in the destruction of the allo-activated T cell. Here, we describe the design and expression of Fas-IgG2a and characterize several key in vitro and in vivo properties of this fusion protein including its ability to impact on both cell-mediated immune responses and cellular apoptotic activity using a murine model of delayed-type hypersensitivity.

RESULTS

In vitro, our Fas-IgG2a construct bound activated T cells via FasL and invoked cytotoxicity. In vivo, it demonstrated a prolonged half-life characteristic of an immunoglobulin-like molecule. Most significantly, it suppressed the cell-mediated immune response and diminished cellular apoptotic activity in lymphoid tissue in our murine model.

CONCLUSION

Fas-IgG2a is a novel agent for delivering target-specific immunosuppression with potential applicability in the transplant setting.

Protection of trinitrobenzene sulfonic acid-induced colitis by an interleukin 2-IgG2b fusion protein in mice

BACKGROUND & AIMS

We have shown in previous studies that an interleukin 2 (IL-2)-IgG2b fusion protein suppresses both humoral and cellular immune reactions in a murine model of DTH reaction. We now analyze the effects of IL-2-IgG2b in a model of intestinal inflammation in mice induced by the hapten reagent 2,4, 6-trinitrobenzene sulfonic acid (TNBS) that mimics immunologic characteristics of human Crohn's disease.

METHODS

In TNBS-induced colitis, colonic and splenic T-cell subsets were characterized by immunohistochemistry and flow cytometry. Cytokine synthesis was studied by semiquantitative reverse-transcription polymerase chain reaction and intracellular cytokine staining in CD4(+) T cells.

RESULTS

When mice were treated with IL-2-IgG2b, improvement in both wasting disease and histopathologic signs of colonic inflammation was observed. An increase in the number of colonic CD4(+)/CD25(+) T cells and increased synthesis of the immunosuppressive cytokine IL-10 also occurred. The protective role of IL-10 was demonstrated by the finding that neutralization of IL-10 in vivo using IL-10-specific antibodies inhibited the IL-2-IgG2b effects in TNBS-induced colitis.

CONCLUSIONS

These studies show for the first time that the IL-2-IgG2b fusion protein can abrogate experimental colitis by local induction of IL-10-secreting T cells.

Specific enzyme-linked immunosorbent assays for quantitation of antibody-cytokine fusion proteins

Preliminary testing has shown in vitro and in vivo that antitumor activity can be obtained with fusion proteins linking tumor-reactive monoclonal antibodies to cytokines, such as granulocyte-macrophage colony-stimulating factor or interleukin 2 (IL-2). Preclinical and clinical testing of these reagents requires their in vitro and in vivo quantitation and pharmacokinetic evaluation. We have focused on the detection of a fusion protein which links one human IL-2 molecule to the carboxy terminus of each heavy chain of the tumor-reactive human-mouse chimeric anti-GD2 antibody, ch14.18. We have developed enzyme-linked immunosorbent assays (ELISAs) to evaluate intact tumor-reactive fusion proteins. By these ELISAs we can reliably measure nanogram quantities of intact ch14.18-IL-2 fusion protein and distinguish the intact protein from its components (ch14.18 and IL-2) in buffer, mouse serum, and human serum with specificity and reproducibility. The measurement of intact ch14.18-IL-2 fusion protein is not confounded by free IL-2 or free ch14.18 when 100 ng or less of total immunoglobulin per ml is used during the assay procedure. Our results indicate that these ELISAs are suitable for preclinical and clinical testing and with slight modifications are applicable to the analysis of a variety of other fusion proteins.

Targeting of antihapten antibodies to activated T cells via an IL-2-hapten conjugate prolongs cardiac graft survival

Antihapten antibodies binding to ligand-hapten conjugates are able to mediate complement mediated lysis in vitro. Based on this observation we propose a new in vivo immunotherapy using molecules that combine a low molecular weight hapten binding to antibodies preexisting in serum and a cell specific ligand. The ligand-hapten conjugates are potential cytotoxic drugs which may (1) be specific for a given target cell, (2) be nonimmunogenic, (3) be of low molecular weight, (4) form soluble complexes with preexisting antibodies resulting in prolonged half life of the drug, and (5) induce a potent antibody mediated rejection of target cells. These novel compounds could be useful for the elimination of certain cell subsets involved in allograft rejection, cancers, infectious diseases, etc., without some of the pitfalls of conventional immunotherapies. The feasibility of this approach was demonstrated in an animal model using a compound consisting of one interleukin 2 and one fluorescein molecule (IL-2-FITC). BALB/c mice (H2d) previously immunized and expressing anti-FITC antibodies were transplanted with a fully mismatched C57BL/6 (H2b) heterotopic heart allograft. Untreated controls rejected their graft by day 9 (MSD = 9 +/- 0.7). Mice with preexisting anti-FITC antibodies treated with IL-2-FITC maintained their grafts for 38.7 +/- 7.1 days (P < 0.02). No prolongation of graft survival was observed in immunized animals that were treated with IL-2 alone (MSD = 10 +/- 1.4). Nonimmunized animals treated with IL-2-FITC rejected their grafts on day 9.4 +/- 1.1. This demonstrates that IL-2-FITC therapy specifically prolonged graft survival in animals with circulating anti-FITC antibodies. The data suggest that a ligand/hapten pair can redirect preexisting antihapten antibodies toward target cells in vivo. Such compounds may be developed for human use as alternatives to polyclonal or monoclonal antibody therapy.

Suppression of cell-mediated and humoral immune responses by an interleukin-2-immunoglobulin fusion protein in mice

Interleukin-2 (IL-2) plays a pivotal role in the cellular and humoral immune responses directed against foreign antigens. We characterized the in vitro and in vivo properties of a chimeric protein consisting of mouse IL-2 fused to the mouse IgG2b Fc domains. This fusion protein binds to IL-2 and Fc receptors and supports IL-2-dependent cell proliferation but does not mediate lysis of IL-2 receptor-positive cells in the presence of murine complement in vitro. However, in vivo the IL2-IgG2b fusion protein suppresses both cellular and humoral immune responses after immunization with sheep erythrocytes. Surprisingly, delayed hypersensitivity is inhibited despite a dramatic increase of splenic CD3+ and NK1.1+ lymphocytes, indicating that altered homing of IL2-IgG2b-activated lymphocytes rather than cytolysis prevents these cells from accumulating in areas of inflammation. Although in vitro the IL2-IgG2b fusion protein does not alter proliferation of B cells in response to mitogenic stimulation, IgM production in response to sheep erythrocytes is profoundly inhibited in mice treated with the IL2-IgG2b fusion protein. Since no side effects are observed, the IL2-IgG2b fusion protein may expand the therapeutic repertoire of reagents used for the treatment of allograft rejection and autoimmune diseases.