Immunotherapy of experimental autoimmune myasthenia gravis: selective effects of CTLA4Ig and synergistic combination with an IL2-diphtheria toxin fusion protein.

We examined the effects of CTLA4Ig treatment in an experimental model of myasthenia gravis (EAMG) induced by immunizing Lewis rats with purified Torpedo acetylcholine receptor (AChR). During a primary response, CTLA4Ig treatment inhibited AChR antibody production profoundly, and induced a shift of AChR antibody isotypes from the normally predominant IgG2 isotype pattern toward an IgG1 response. Challenge of rats previously treated with CTLA4Ig produced markedly lower AChR antibody responses compared to untreated controls, persistent inhibition of the IgG2b isotype, and no development of EAMG. Treatment of a secondary AChR response with CTLA4Ig or with DAB389IL2 (which kills lymphocytes expressing IL2 receptors) inhibited AChR antibody responses, and clinical EAMG moderately. In contrast, combined treatment with CTLA4Ig plus DAB389IL2 strikingly inhibited AChR antibody levels, and completely prevented EAMG. Our results suggest that the therapeutic benefit of CTLA4Ig may be due to overall inhibition of AChR antibody production as well as a shift in the antibody isotype repertoire.

Epidermal growth factor receptor-targeted cytotoxin inhibits neointimal hyperplasia in vivo. Results of local versus systemic administration.

Smooth muscle cell accumulation is a key feature of restenosis that may be inhibited by the delivery of receptor-targeted cytotoxins. DAB389EGF is a recombinant fusion protein in which the receptor-binding domain of diphtheria toxin has been replaced by human epidermal growth factor (EGF). We investigated the effectiveness of DAB389EGF to inhibit neointimal hyperplasia in the balloon-injured rat carotid artery. Incubation of rat carotid arteries with 125I-labeled EGF revealed extensive EGF binding sites in the neointima of balloon-injured arteries. Sixty rats subsequently received either saline or DAB389EGF (total dose, 0.15 mg) delivered immediately following balloon injury either systemically, via 14-day continuous osmotic pump infusion, or locally, via 30-minute intraluminal incubation. The effect of both treatment strategies was measured 2 weeks after injury by cross-sectional morphometric analysis of intimal area, the ratio of intimal/medial area (I/M), and the percent luminal narrowing (%LN). In addition, proliferative activity was assessed by immunostaining for the presence of the proliferating cell nuclear antigen (PCNA). Compared with controls, systemic delivery of fusion toxin significantly reduced intimal area, I/M, and %LN by 40%, 40%, and 29%, respectively. However, these rats exhibited 2% weight loss, indicating mild systemic toxicity. Local, intraluminal administration of DAB389EGF yielded a more pronounced reduction in intimal area, I/M, and %LN by 74%, 79%, and 72%, respectively. This inhibitory effect was preserved at 3 weeks postinjury, and PCNA immunostaining of locally treated arteries revealed a virtual absence of proliferative activity in the neointima and media at this timepoint. In contrast to systemically treated rats, rats receiving fusion toxin locally gained weight at a rate similar to controls, indicating avoidance of systemic toxicity. We conclude that DAB389EGF is a potent inhibitor of neointimal hyperplasia in vivo and that whereas an inhibitory effect may be achieved by systemic delivery, local delivery appears to be more potent, avoids systemic toxicity, and thus represents a feasible strategy to preempt restenosis.

Prevention of smooth muscle cell outgrowth from human atherosclerotic plaque by a recombinant cytotoxin specific for the epidermal growth factor receptor.

Smooth muscle cell proliferation in the intima of arteries is a principal event associated with vascular narrowing after balloon angioplasty and bypass surgery. Techniques for limiting smooth muscle cell proliferation, however, have not as yet yielded any therapeutic benefit for these conditions. This may reflect the present lack of sufficiently potent and specific inhibitors of smooth muscle cell proliferation. DAB389 EGF is a genetically engineered fusion protein in which the receptor-binding domain of diphtheria toxin has been replaced by human epidermal growth factor. We evaluated the effect of this fusion toxin on human vascular smooth muscle cells in culture. Incubation of proliferating cells with DAB389 EGF yielded a dose-dependent inhibition of protein synthesis, as assessed by uptake of [3H]leucine, with an IC50 of 40 pM. The cytotoxic effect was inhibited in the presence of excess EGF or with monoclonal antibody to the EGF receptor. We further studied the effect of the fusion toxin on smooth muscle cell outgrowth from human atherosclerotic plaque. Outgrowth was markedly inhibited after as little as 1 h of exposure to the fusion protein. Furthermore, complete inhibition of proliferation of cells within the plaque could be attained. These results demonstrate that DAB389 EGF is highly cytotoxic to human smooth muscle cells proliferating in culture and can prevent smooth muscle cell outgrowth from "growth-stimulated" human atherosclerotic plaque. DAB389 EGF may therefore be of therapeutic value in vascular diseases characterized by smooth muscle cell accumulation.

Impact of interleukin-2-receptor-targeted cytotoxins on a unique model of murine interleukin-2-receptor-expressing malignancy.

DAB486IL-2 is a genetically engineered fusion protein consisting of a portion of diphtheria toxin fused to human IL-2. It is specifically cytotoxic for tumor cells which bear high-affinity IL-2 receptors (IL-2R). DAB389IL-2 is a similarly constructed hybrid protein which is smaller than DAB486IL-2 and is slightly more potent in vitro. We have developed a murine model of IL-2R-expressing malignancy to study the in vivo efficacy of these genetically engineered cytotoxins. Following intravenous administration of CP3 cells, C57BL/6 mice develop tumors which are lymphatic in distribution. When mice are injected i.v. with 10(6) CP3 cells, 90% of the animals show signs of observable tumor by day 10 to 20; death occurs in 50% of untreated animals by day 30. Intravenous treatment of mice with DAB486IL-2 (10 micrograms daily for 10 days), beginning 24 hr after administration of CP3 cells, increases mean survival time by approximately 50%. In comparative studies, DAB389IL-2 is more potent in vivo than DAB486IL-2, with approximately 90% of treated animals with no evidence of tumor at 60 days. The mechanism of action of tumor inhibition by DAB486IL-2 is specific, since treatment of animals which have IL-2R-negative EL4 tumors has not resulted in increased survival time. In addition, treatment of such tumors with DAglu53B486IL-2, a fusion protein which can bind to the IL-2R but is incapable of inhibiting protein synthesis, is ineffective.