Oral administration of protein can induce antigen-specific immune hyporesponsiveness. However, the utility of oral tolerance to autoantigens in the treatment of autoimmune diseases may be limited when candidate autoantigens cannot be produced by conventional systems in quantities sufficient for clinical studies. Plants may be ideally suited for this purpose, as they can synthesize, glycosylate and assemble mammalian proteins to provide huge quantities of relatively low cost soluble proteins. Furthermore, edible transgenic plants could provide a simple and direct method of autoantigen delivery for oral tolerance. Therefore, the aim of this study was to determine whether a transgenic plant expression system was capable of synthesizing the diabetes-associated autoantigen, glutamic acid decarboxylase (GAD) in an immunogenic form and whether the oral administration of an autoantigen expressed by a plant could directly induce protective immune responses in a mouse model of diabetes. We show that a GAD-expressing transgenic plant, given as a dietary supplement, inhibits the development of diabetes in the non-obese diabetic (NOD) mouse.
We have observed that patients on concurrent cyclosporin and phenytoin therapy required increased doses of cyclosporin to maintain therapeutic concentrations of this novel immunosuppressive drug. We have, therefore, studied the influence of phenytoin on the pharmacokinetics of oral cyclosporin in six healthy male subjects. Cyclosporin concentrations in serum and whole blood were measured by high pressure liquid chromatography (h.p.l.c.) and radioimmunoassay (RIA). Concentrations of cyclosporin in whole blood were consistently higher than corresponding values in serum. Concentrations of cyclosporin determined by RIA were also consistently higher than those determined by h.p.l.c. Irrespective of the biological fluid (serum or whole blood) or the type of drug analysis (h.p.l.c. or RIA), changes in cyclosporin kinetics following phenytoin administration exhibited similar patterns. Phenytoin significantly reduced the maximum concentration and the area under the concentration‐time curve and significantly increased total body clearance of cyclosporin. There was a statistically significant reduction of cyclosporin half‐life (t 1/2) in whole blood using h.p.l.c. analysis. However, there was no significant change in cyclosporin t 1/2 in serum following phenytoin administration, using either form of drug analysis. Cyclosporin metabolites 17 and 18 were measured by h.p.l.c. in whole blood samples only, since these metabolites were found almost entirely in red blood cells. Phenytoin significantly reduced the Cmax and AUC of both metabolites, but no significant change was observed in the t 1/2 of either. Phenytoin enhanced the metabolism of antipyrine which was co‐administered with cyclosporin to assess oxidative enzyme activity. We conclude that patients undergoing organ transplantation should be carefully monitored if they require phenytoin or other drugs known to accelerate oxidative metabolism.
One hundred thirty-six patients with multiple sclerosis and several control groups were studied for measles antibodies using several different antigens. Measles antibodies were higher in the multiple sclerosis population, but siblings also had higher titers than matched and random controls. The elevation in antibody titers (complement fixation) was found in female multiple sclerosis patients and male patients with HL-A types 3, 7, and W-18. Male patients not carrying these HL-A antigens had, as a group, relatively normal antibody levels. These data confirm a familial factor in elevated measles antibody titers. We suggest that HL-A antigens are linked to one of the factors that determines measles antibody titers in multiple sclerosis patients.
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