Rat pancreatic islet pretreatment with anti-MHC class II monoclonal antibodies and culture: in vitro MLIC test response does not predict islet allograft survival.

Antigen presenting cells (APC) expressing MHC class II antigens have been attributed with stimulatory capacity for initiating islet allograft rejection (direct pathway). Therefore, we evaluated the effect of pretreating isolated islets with different monoclonal antibodies against MHC class II antigens and complement, with and without culture at 22 degrees C or 37 degrees C, on MHC class II antigen expression, on the allogeneic proliferative response in the mixed lymphocyte islet culture (MLIC) and on islet allograft survival in adult rats. Experiments were performed in two different strain combinations incompatible for MHC class II antigens and either incompatible or compatible for MHC class I antigens, in order to elucidate further the impact of class I antigens on islet allograft rejection. In terms of class II antigen suppression, pretreatment with anti-MHC class II antibodies together with complement and a 5-day (37 degrees C) culture period proved most effective. After this procedure 92.7% of the islets of LEW rats and 91.1% of the islets of LEW.1WR2 rats were negative for MHC class II antigens, as demonstrated by indirect immunofluorescence. Transfer of successfully pretreated islets to a MLIC in vitro test system provoked a significantly reduced allogeneic T-cell proliferative response in the case of additional MHC class I disparity (ratio 1.3 vs 4.7) and a response as low as that of a syngeneic setting when stimulator islets and allogeneic responder lymphocytes shared MHC class I antigens (ratio 1.0 vs 1.6).(ABSTRACT TRUNCATED AT 250 WORDS)

Prevention of recurrent autoimmune diabetes in the BB rat by islet transplantation under the renal capsule.

Pancreatic islet grafts transplanted into subjects with spontaneous autoimmune diabetes are threatened by two immune responses, allograft rejection and the recurrence of autoimmune insulitis. To examine the recurrent autoimmune response to transplanted islets it is necessary to exclude islet allograft rejection. The BB rat is a unique model of spontaneous diabetes with clinical and pathological characteristics identical or similar to those found in human insulin dependent diabetes mellitus (IDDM). In this study we demonstrate permanent acceptance of histocompatible islet grafts in chemically induced diabetes and a lack of intracolony tissue antigen rejection in our BB rat colony. Therefore the vigorous destruction of transplanted BB islets in the liver of spontaneously diabetic BB rats is due to recurrence of diabetes. This recurrence can be prevented by transplantation of islets under the renal capsule. This may be important for clinical application in IDDM, particularly with regard to host and donor tissue matching.

A comparative study of antigen expression by skin and pancreas in the prediabetic and diabetic state of the BB rat.

Type 1, insulin-dependent diabetes mellitus is an autoimmune disease with destruction of beta-cells in islets of Langerhans by activated (antigen-positive) infiltrating mononuclear cells accompanied by serological immune phenomena. The pathological mechanism has not yet been clarified in detail, and some inversion in the proportion of epidermal antigen expression has recently been described in spontaneous diabetes. The BB rat is one of the animal models most closely resembling human type 1 diabetes of autoimmune origin. We compared the class I and class II antigen expression in the islets of Langerhans and in the skin of spontaneously diabetic (BBD) and normoglycaemic (BBND) BB rats in the prediabetic, diabetic and non-diabetic states. Class I and class II antigen expression increased significantly in the islets of BBD rats from prediabetes to diabetes and compared with non-diabetic controls. In the same period, the dermal antigen expression (class I and class II) did not decrease and was not lower in BBD than in BBND animals. These results do not support a loss of activated (antigen-positive) dermal cells at the onset of diabetes in the BB rat and do not show a clear correlation with the antigen expression in infiltrated islets of Langerhans.

Major-histocompatibility-complex restricted and nonrestricted autoimmune effector mechanisms in BB rats.

To investigate whether the immunologic mechanisms of autoimmune pancreatic beta-cell destruction are MHC restricted, we examined the relative vulnerability of islet allografts from a panel of MHC-compatible and -incompatible donors to autoimmune damage after transplantation to spontaneously diabetic BB recipients. To circumvent a potentially confounding allograft response to the foreign islet graft, we utilized two strategies: (1) pretransplant in vitro culture of islets to delete intraislet APCs; and (2) induction of islet donor-specific immunologic tolerance in diabetes-prone BB rats. Experiments employing organ culture to prevent rejection demonstrated that MHC-incompatible grafts were significantly less vulnerable to autoimmunity than MHC-compatible grafts. In contrast, when we used the model of immunologic tolerance to exclude rejection, both MHC-compatible and -incompatible islet grafts were equally susceptible to autoimmune damage. The reason for this discrepancy has not been defined fully but may be related to our observation that tolerant BB animals exhibit increased peripheral blood NK-cell activity. NK cells are known to be cytotoxic to islets in vitro and could play a role in a non-MHC-restricted diabetogenic response in vivo. We conclude that both MHC-restricted and nonrestricted mechanisms are capable of contributing to anti-beta-cell autoimmunity in BB rats.

The effect of islet cell culture in vitro at 24 degrees C on graft survival and MHC antigen expression.

A period of in vitro culture prior to transplantation has been shown to prolong the survival of many types of MHC-incompatible endocrine grafts. The effectiveness of this strategy has been attributed to a selective depletion of intragraft antigen-presenting cells. We report that in vitro culture at 24 degrees C results in a significantly better survival of rat isolated islet allografts than does culture at 37 degrees C. Using in vitro assays of APC activity, we were unable to detect differences in the quantity of residual intraislet APCs between 24 degrees C and 37 degrees C culture preparations. In contrast, islet endocrine cells cultured at 24 degrees C evidenced a reduced level of cell surface class I MHC antigen expression and were significantly less vulnerable to lysis in vitro by CTL. These findings suggest that culture at 24 degrees C produces islet alterations other than APC depletion, and that its beneficial effect on graft survival correlates with a reduction in endocrine cell class I MHC antigen expression.

Effects of ganglioside (Cronassial) treatment on MHC Ia antigen expression and allograft survival of pancreatic islets in diabetic rats.

Streptozotocin-diabetic BdII rats were treated daily with 20 mg/kg body weight gangliosides for ten days beginning two days before transplantation. This treatment did not prolong allograft survival of untreated Lewis islets. Culture treatment of isolated Lewis islets with gangliosides (100 micrograms/ml in RPMI 1640) for one day resulted in a significant reduction of MHC Ia antigen positive cells but not of class I antigens within the islets. Transplantation of the ganglioside pretreated islets into non-immunosuppressed BdII recipients prolonged allograft survival to 12 days only in one of five animals.

Fish oil-enriched diet and reduction of low-dose streptozocin-induced hyperglycemia. Inhibition of macrophage activation.

Repeated low doses of streptozocin (STZ; 40 mg/kg, 5 injections/day) induce hyperglycemia in certain strains of mice after a latency of 1 wk. Omega-3 polyunsaturated fatty acids (omega 3FA) have been reported to suppress immune processes by blockade of the cyclooxygenase pathway of arachidonic acid metabolism. We investigated the effects of diets high in omega 3FA on the development of diabetes in the low-dose STZ-induced diabetes (LDSTZ-D) model. Male C57BL/6J mice were on a fish oil diet (FOD) as a source of omega 3FA 8 wk before STZ injection. Controls received laboratory chow only or a coconut oil diet (COD). Blood glucose levels in FOD mice were reduced (12.5 vs. 28 mM for COD mice, P less than .001) 60 days after STZ injection with a diet in which 20% of the calories were from fish oil. In FOD mice, immunohistology showed reduced numbers of class II antigen-expressing cells in pancreatic islets followed by a decreased extent of insulitis. FOD significantly decreased the number of Fc receptor-negative dendritic cells in cytospin preparations of islets isolated from diabetic mice. Interleukin 1-like activity of peritoneal exudate cell supernatants isolated from mice on FOD was reduced. FOD did not improve insulin secretion of isolated islets from LDSTZ-D mice. These data indicate a beneficial effect of FOD on the immune component of the mouse LDSTZ-D model.

Ciamexon in the low dose streptozotocin induced diabetes of mice.

This article is concerned with suppression of the development of diabetes experimentally induced by multiple injections of subdiabetogenic doses of streptozotocin (4 x 45 mg/kg/d) in mice (CD 1 and C57B16). Streptozotocin injections were followed by hyperglycemia and mononuclear cell infiltration of islets (insulitis). Ciamexon is a new immuno-modulating agent with promising effects in experimental models of autoimmune diseases and practically no toxic side effects. When Ciamexon was given before streptozotocin treatment blood glucose levels in the parenteral glucose tolerance test were suppressed in a dose dependent way. 60 days after streptozotocin application the percentage of islets showing insulitis or even necrosis was reduced in the Ciamexon treated group compared to the streptozotocin only group. In contrast, Cyclosporin A had a detrimental effect on diabetes in this model although blood levels were proved to be in the therapeutic range. From these results we conclude that Ciamexon should be tested for its effect in human type I diabetes.

Gamma interferon induces novel expression of Ia antigens by rat pancreatic islet endocrine cells.

Pancreatic endocrine cells normally express only Class I gene products of the major histocompatibility complex (MHC). Recently it has been shown that in both patients with recent onset type I diabetes and acutely diabetic BB rats, residual islet beta cells express Class II MHC antigens. In an attempt to define a potential inducer of this aberrant Class II antigen expression, we have investigated the effect of in vitro incubation of rat isolated pancreatic islets with the lymphokine gamma interferon (IFN-gamma) on MHC antigen expression. Our results demonstrate that in vitro exposure to IFN-gamma induces novel expression of Class II antigens on the surface of rat islet endocrine cells and increases the level of pre-existing Class I antigen expression.