Effects of irradiation on diabetes in the BB/Wor rat

Rat models of type 1 diabetes: genetics, environment, and autoimmunity

For many years, the vast amount of data gathered from analysis of nonobese diabetic (NOD) and congenic NOD mice has eclipsed interest in the rat for the study of type 1 diabetes. The study of rat models has continued, however, and recently there has been a reanimation of interest for several reasons. First, genetic analysis of the rat has accelerated. Ian4L1, cblb, and Iddm4 are now known to play major roles in rat autoimmunity. Second, rats are amenable to study the interactions of genetics and environment that may be critical for disease expression in humans. Environmental perturbants that predictably enhance the expression of rat autoimmune diabetes include viral infection, toll-like receptor ligation, and depletion of regulatory T cell populations. Finally, data generated in the rat have correctly predicted the outcome of several human diabetes prevention trials, notably the failure of nicotinamide and low dose parenteral and oral insulin therapies.

Thymectomy and radiation-induced type 1 diabetes in nonlymphopenic BB rats

Spontaneous type 1 diabetes in BB rats is dependent on the RT1(u) MHC haplotype and homozygosity for an allele at the Lyp locus, which is responsible for a peripheral T-lymphopenia. Genetic studies have shown that there are other, as yet unidentified, genetic loci contributing to diabetes susceptibility in this strain. BB rats carrying wild-type Lyp alleles are not lymphopenic and are resistant to spontaneous diabetes (DR). Here we show that thymectomy and exposure to one sublethal dose of gamma-irradiation (TX-R) at 4 weeks of age result in the rapid development of insulitis followed by diabetes in 100% of DR rats. Administration of CD4(+)45RC(-) T-cells from unmanipulated, syngeneic donors immediately after irradiation prevents the disease. Splenic T-cells from TX-R-induced diabetic animals adoptively transfer type 1 diabetes to T-deficient recipients. ACI, WF, WAG, BN, LEW, PVG, and PVG.RT1(u) strains are resistant to TX-R-induced insulitis/diabetes. Genetic analyses revealed linkage between regions on chromosomes 1, 3, 4, 6, 9, and 16, and TX-R-induced type 1 diabetes in a cohort of nonlymphopenic F(2) (Wistar Furth x BBDP) animals. This novel model of TX-R-induced diabetes in nonlymphopenic BB rats can be used to identify environmental and cellular factors that are responsible for the initiation of antipancreatic autoimmunity.

Prediction of diabetes in Biobreeding/Aburahi rats by the measurement of soluble L-selectin

L-selectin was initially identified as a homing receptor, recently soluble L-selectin has been used as a marker of the inflammation. Therefore, we investigated the relation between the development of diabetes and serum L-selectin levels in the Biobreeding (BB) rats. Serum L-selectin were measured from 30 days old to the onset of diabetes or to 90 days old in Biobreeding (BB) rats and Wistar Furth (WF) rats. Significant elevation of L-selectin was found in diabetes prone (DP) rats from 45 days old to the onset of diabetes or through 90 days old. No elevation was found in other strain of rats. In histological study, all of DP rats had insulitis and no other strain of rats had it. Therefore, we conclude that the measurement of serum L-selectin could be useful tool to predict the onset of diabetes or presence of insulitis in BB rats.

T Cell Reconstitution of BB/W Rats After the Initiation of Insulitis Precipitates the Onset of Diabetes

One of the diabetes susceptibility genes of the BB/W (Biobreeding/Worcester) rat maps to the lyp locus on chromosome 4. The BB/W lyp allele is responsible for a severe peripheral T lymphopenia. Correction of this lymphopenia by transfer of normal, histocompatible T cells prevents diabetes, providing T cell reconstitution is initiated before insulitis. We have analyzed this time-dependent regulation of the diabetogenic process by normal T cells. We demonstrate that T cell reconstitution after the initiation of insulitis precipitates the onset of diabetes through the recruitment of donor T cells to the autoimmune process. This inability of normal T cells to regulate primed diabetogenic BB/W T cells and their own autoreactive potential were observed when normal T cells outnumbered pathogenic T cells by approximately 1000-fold. Analysis of donor-derived T cells recovered from BB/W rats that were reconstituted before insulitis, and hence protected from diabetes, demonstrates that early T cell reconstitution of BB/W rats does not result in a long term physical or functional depletion of islet cell-specific T cell precursors among donor cells or in the expansion of T cells that can regulate the activation and expansion of diabetogenic T cells.

Thymus atrophy and changes in thymocyte subpopulations of BN rats with mercury-induced renal autoimmune disease

Administration of low doses of mercury induces autoantibodies to laminin and autoimmune glomerulonephropathy in BN, MAXX and DZB rats as well as in (BN x LEW)F1 hybrids. LEW strain rats are resistant to these immunotoxic effects. Susceptible rats also show lymphoid hyperplasia in spleen and lymph nodes and severe thymic atrophy. It is still uncertain whether these mercury-induced changes have any role in the induction of autoimmune responses to laminin. In the present study, we have examined the effects of mercury on the thymus of susceptible and resistant rats. Histological analysis of thymuses from BN rats revealed extensive disorganization within 15 days following mercury treatment, with loss of demarcation between cortex and medulla. Numbers of thymus cells were significantly decreased in both BN and (BN x LEW)F1 hybrid rats injected with HgCl2. There was no apparent increase in apoptotic cells in the thymus of these animals. By flow cytometry we detected a relative and absolute loss of double-positive CD4+ CD8+ thymocytes in BN (but not in LEW rats) within 15 days of mercury treatment. There was a corresponding increase in the relative proportion of single-positive (CD4+ or CD8+) and double-negative CD4- CD8- thymocytes in mercury-treated BN rats. Absolute increases in the number of CD4+ single-positive thymocytes were also observed. In contrast, mercury-treated LEW rats had no changes in thymus architecture or significant decreases in cell numbers. Since the thymus is important in both position and negative selection of developing thymocytes, immunotoxic effects of mercury on its structure and thymocyte subpopulations may have multiple consequences. Alternatively, we suggest the hypothesis that autoimmunity (and in particular autoantibodies to laminin) may be responsible for the changes observed in the thymus.

Preservation of GLUT 2 expression in islet beta cells of Kilham rat virus (KRV)-infected diabetes-resistant BB/Wor rats

Loss of GLUT 2, the glucose transporter isoform of pancreatic beta cells, has been reported to accompany the onset and perhaps contribute to the pathogenesis, of insulin-dependent and non-insulin-dependent diabetes mellitus in BB/Wor and Zucker fatty rats. In this study we investigated the effect of Kilham Rat Virus infection on GLUT2 expression in diabetes-resistant BB/Wor rats. Viral antibody-free diabetes-resistant rats do not develop spontaneous diabetes, but inoculation with Kilham Rat Virus induces autoimmune beta-cell destruction and hyperglycaemia. Pancreas sections from normoglycaemic diabetes-resistant BB/Wor rats were obtained 5, 7 and 25 days after inoculation with Kilham Rat Virus and stained for GLUT2 using a rabbit polyclonal antibody. At all time points, beta cells displayed GLUT2 expression comparable to uninfected diabetes-resistant controls. Immunostained insulin content of the beta cells also remained unchanged. Sections were also examined from Kilham Rat Virus inoculated diabetes-resistant rats with lymphocytic insulitis or diabetes. GLUT2 and insulin immunostaining were unchanged in non-diabetic rats with early insulitis. GLUT2 beta-cell staining was variably reduced in diabetic rats with established insulitis and reduced beta-cell insulin immunostaining. Hence, the initial stages of Kilham Rat Virus-induced diabetes in diabetes-resistant rats are not accompanied by a significant reduction in GLUT2 expression. These results suggest that the loss of GLUT2 does not play a significant role in the aetiology of diabetes in the Kilham Rat Virus-infected diabetes-resistant BB/Wor rat.

Role of RT6+ T lymphocytes in mercury-induced renal autoimmunity: experimental manipulations of "susceptible" and "resistant" rats

Brown Norway (BN) rats, "susceptible" to the autoimmune effects of mercury, experience a decrease of peripheral RT6.2+ T lymphocytes after the injection of relatively low doses of mercuric chloride. This change coincides with the appearance of circulating autoantibodies to renal antigens (e.g., laminin). Lewis (LEW) rats, "resistant" to the autoimmune effects of mercury, do not show significant decreases of RT6+ T cells. It is possible that BN rats are particularly sensitive to stress induced by mercury and that secretion of adrenocortical hormones decreases levels of RT6+ T cells in this rat strain. Alternatively, mercury may induce a graft-versus-host-like syndrome in BN rats, resulting in higher levels of corticosteroids capable of affecting RT6+ lymphocytes. To eliminate the possible influence of adrenocortical hormones, we have adrenalectomized BN rats prior to administration of mercury. Autoimmune responses to renal antigens were not affected by this experimental manipulation. Similarly, adrenalectomized rats exposed to mercury showed a significant decrease of RT6+ T lymphocytes in cervical lymph nodes. Overall, these observations do not support the hypothesis that increases in adrenocortical hormones play a major role in mercury-induced changes of RT6+ T cells. We have also explored whether experimental depletion of RT6+ T lymphocytes would result in autoimmunity. Gamma irradiation of BN rats led to a decrease of RT6+ T splenocytes, but by itself (i.e., without exposure to mercury) did not cause autoimmune responses to renal antigens. In addition, gamma-irradiated BN rats treated with mercury had autoimmune responses similar to those observed in mercury-treated nonirradiated controls. Depletion of RT6+ T cells in LEW rats through the use of a monoclonal antibody against the RT6.1 alloantigen did not by itself cause renal autoimmunity in this "resistant" strain. Depletion followed by administration of mercury also failed to induce renal autoimmunity. The lack of autoimmune effects in RT6-depleted BN and LEW rats suggests that a combination of several factors may be necessary to break self-tolerance and cause mercury-induced autoimmunity. Such factors likely comprise both environmental (mercury) and endogenous, genetically determined components. The latter include regulatory T cells (possibly RT6+), major histocompatibility complex (MHC), and T-cell receptors (TCR). Thus, BN rats with decreased percentages of immunoregulatory RT6+ T lymphocytes require additional immunotoxic and/or toxic effects of mercury for autoimmunity to occur. On the other hand, LEW rats depleted of regulatory T cells may still be unable to develop renal autoimmunity after exposure to mercury because they lack the appropriate MHC and TCR.

Lack of disease recurrence in diabetic BB/Pfd rats after syngeneic islet transplantation

Restimulation of autoreactivity in two different BB rat sublines of the same origin (Ottawa, Canada) was investigated by syngeneic islet transplantation into diabetic animals. Despite identical methods and conditions recurrence of hyperglycaemia was observed in BB/OK rats (Karlsburg, Germany) but not in BB/Pfd rats (Leuven, Belgium). Pancreatic morphology at the time of transplantation revealed significant differences in islet volume density and the degree of insulitis. Additionally, marked differences in the phenotypical composition of cells infiltrating the islets were observed. A loss of autoimmune memory in BB/Pfd rats is discussed as a probable reason for the lack of disease recurrence in those animals.

Reduction of the RT6.2+ subset of T lymphocytes in brown Norway rats with mercury-induced renal autoimmunity

Chemically induced autoimmunity is a recently recognized environmental hazard that may affect individuals genetically predisposed to autoimmune disease and chronically exposed to certain chemicals. For example, moderate concentrations of mercury may lead to renal autoimmune disease in a small but significant percentage of the exposed population. Mercury also induces autoimmune glomerulonephritis in susceptible Brown Norway (BN) and MAXX inbred strain rats. Autoimmune responses, directed to epitopes of the renal glomerular basement membrane (GBM), are rapid in onset and have a self-limiting course in mercury-treated rats. Both regulatory T cells and idiotype-anti-idiotype network have been implicated in the resolution of this autoimmune process. In our investigations of immune regulation of mercury-induced autoimmune glomerulonephritis, we have used flow cytometry to quantitate lymphocyte subpopulations in the spleen and lymph nodes of mercury-treated and control BN rats. Of particular interest was the RT6+ T cell subset, that appears to have important immunoregulatory properties in a rat model of autoimmune insulin-dependent diabetes mellitus. Spleen and lymph nodes from control BN rats contained 22 and 52%, respectively, RT6+ cells. Spleens from mercury-treated animals contained 21% RT6+ cells on Day 10 of treatment, 13% on Day 17, 16% on Day 24 and 20% on Day 30. Lymph nodes from the same rats had 36% RT6+ cells on Day 10, 23% on Day 17, 29% on Day 24, and 28% on Day 30. The decrease in RT6+ cells correlated inversely with autoimmune responses to GBM, which peaked on Days 17-24 and declined by Day 30. Moreover, autoimmune responses were also associated with elevated RT6-:RT6+ T cell ratios. Similar results were obtained in two additional groups of BN rats, comprising both younger and older animals, sacrificed at Day 18 of mercury treatment. Analysis of other lymphocyte subpopulations demonstrated a decrease of CD4+ and CD5+ cells, whereas B cells as well as CD8+, IL-2 receptor+, and MHC class II+ subsets showed no consistent correlation with the onset or resolution of the autoimmune process. These findings suggest that mercury-induced changes in RT6+ T lymphocytes may be related to the development of renal autoimmune disease in genetically predisposed BN rats.