The role of NK cell activity in the pathogenesis of poly I:C accelerated and spontaneous diabetes in the diabetes prone BB rat

Rat Models of Human Type 1 Diabetes

Rat models of human type 1 diabetes have been shown to be of great importance for the elucidation of the mechanisms underlying the development of autoimmune diabetes. The three major well-established spontaneous rat models are the BioBreeding (BB) diabetes-prone rat, the Komeda diabetes-prone (KDP) rat, and the IDDM (LEW.1AR1-iddm) rat. Their distinctive features are described with special reference to their pathology, immunology, and genetics and compared with the situation in patients with type 1 diabetes mellitus. For all three established rat models, a distinctive genetic mutation has been identified that is responsible for the manifestation of the diabetic syndrome in these rat strains.

The BB rat as a model of human type 1 diabetes

The BB rat is an important rodent model of human type 1 diabetes (T1D) and has been used to study mechanisms of diabetes pathogenesis as well as to investigate potential intervention therapies for clinical trials. The Diabetes-Prone BB (BBDP) rat spontaneously develops autoimmune T1D between 50 and 90 days of age. The Diabetes-Resistant BB (BBDR) rat has similar diabetes-susceptible genes as the BBDP, but does not become diabetic in viral antibody-free conditions. However, the BBDR rat can be induced to develop T1D in response to certain treatments such as regulatory T cell (T(reg)) depletion, toll-like receptor ligation, or virus infection. These diabetes-inducible rats develop hyperglycemia under well-controlled circumstances and within a short, predictable time frame (14-21 days), thus facilitating their utility for investigations of specific stages of diabetes development. Therefore, these rat strains are invaluable models for studying autoimmune diabetes and the role of environmental factors in its development, of particular importance due to the influx of studies associating virus infection and human T1D.

Innate immunity and the pathogenesis of type 1 diabetes

Type 1 diabetes mellitus is an autoimmune disease caused by the immune-mediated destruction of insulin-producing pancreatic beta cells occurring in genetically predisposed individuals, with consequent hyperglycemia and serious chronic complications. Studies in man and in experimental animal models have shown that both innate and adaptive immune responses participate to disease pathogenesis, possibly reflecting the multifactorial pathogenetic nature of this autoimmune disorder, with the likely involvement of environmental factors occurring at least in a subset of individuals. As a consequence, components of both innate and adaptive immune response should be considered as potential targets of therapeutic strategies for disease prevention and cure. Here we review the contribution of innate immune response to type 1 diabetes, with a particular emphasis to Toll-like receptors (TLR) and NK cells.

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.

Immune cell infiltration, cytokine expression, and beta-cell apoptosis during the development of type 1 diabetes in the spontaneously diabetic LEW.1AR1/Ztm-iddm rat

The IDDM (LEW.1AR1/Ztm-iddm) rat is a type 1 diabetic animal model characterized by a rapid apoptotic pancreatic beta-cell destruction. Here we have analyzed the time course of islet infiltration, changes in the cytokine expression pattern, and beta-cell apoptosis in the transition from the pre-diabetic to the diabetic state. Transition from normoglycemia to hyperglycemia occurred when beta-cell loss exceeded 60-70%. At the early stages of islet infiltration, macrophages were the predominant immune cell type in the peripherally infiltrated islets. Progression of beta-cell loss was closely linked to a severe infiltration of the whole islet by CD8+ T-cells. With progressive islet infiltration, interleukin-1beta (IL-1beta) and tumor necrosis factor-alpha (TNF-alpha) were expressed in immune cells but not in beta-cells. This proinflammatory cytokine expression pattern coincided with the expression of inducible nitric oxide synthase (iNOS) and procaspase 3 in beta-cells and a peak apoptosis rate of 6.7%. Islet infiltration declined after manifestation of clinical diabetes, yielding end-stage islets devoid of beta-cells and immune cells without any sign of cytokine expression. The observed coincidence of IL-1beta and TNF-alpha expression in the immune cells and the induction of iNOS and procaspase 3 mRNA expression in the beta-cells depicts a sequence of pathological changes leading to apoptotic beta-cell death in the IDDM rat. This chain of events provides a mechanistic explanation for the development of the diabetic syndrome in this animal model of human type 1 diabetes.

Endocrine pancreas histology of congenic BB-rat strains with reduced diabetes incidence after genetic manipulation on chromosomes 4, 6 and X

Congenic BB.SHR rat strains were established by crossing of spontaneously diabetic BB/OK rats and diabetes-resistant SHR rats. Chromosomal regions on which the genes Iddm 4 (BB.6s), Iddm6 (BB.Xs) and Iddm 2 (BB.LL) are located were exchanged. As a result of genetic manipulation diabetes incidence was markedly reduced from 80% in BB/OK to 50% in BB.SHR (Chr. X), to 14% in BB.SHR (Chr. 6) and to 0% in BB.LL rats. Pancreata of these newly generated BB.SHR rats were investigated histologically. In newly diagnosed diabetic rats of congenic strains pancreatic insulin content (BB.6s: p < 0.05; BB.Xs p < 0.01) and relative volume of insulin-positive cells (BB.Xs: p < 0.001) were significantly higher than in BB/OK rats. The degree of insulitis was not different in 90-day-old and newly diagnosed diabetic animals. Surprisingly, in 30-day-old rats we observed an increase of the degree of insulitis with decreasing diabetes incidence. We suppose that by an earlier occurrence of the immunological beta-cell destruction, a part of the animals is able to develop a secondary diabetes resistance. The exchange of the BB-lymphopenia gene by that of SHR-rats prevented the development of hyperglycaemia without altering the auto-reactive immune response, which could be observed in all animals investigated.

Double-stranded RNA regulates IL-4 expression

dsRNA, as genomic fragment, replicative intermediate, or stem and loop structure in cells infected by viruses, can act to signal the immune system of the presence of viral infections. Although most viral infections are associated with strong Th1 immune responses, Th2-type responses have also been observed. In this study, we characterize the effects of dsRNA on the induction of Th2 responses in human lymphocytes. We report that in addition to the well-known Th1-inducing capabilities of dsRNA, treatment of human lymphocytes with low concentrations of dsRNA (0.1-1 microg/ml) leads to the expression of the prototypic Th2 cytokine IL-4. This induction was accompanied with the concentration-dependent activation of NF-kappaB and NF-AT2 but not NF-AT1. In addition, dsRNA can directly activate an IL-4 promoter-driven chloramphenicol acetyltransferase reporter gene in transiently transfected Jurkat cells. These results are the first demonstration of a non-TCR-associated activator of NF-AT in human cells and suggest that dsRNA directly influences IL-4 gene expression through its effect on NF-AT activation. Our data provide support for the idea that dsRNA at low concentrations in vivo may induce a Th2-dominant response that is not optimal for protective immunity to the virus.

Gamma interferon prevents diabetes in the BB rat

The BB rat model of human insulin-dependent diabetes mellitus (IDDM) spontaneously develops diabetes through an autoimmune process. Gamma interferon (IFN-gamma) is thought to play an important pathogenic role. This study examined if IFN-gamma administration can, paradoxically, prevent diabetes in BB rats. Diabetes-prone BB rats were initially injected intraperitoneally with murine recombinant IFN-gamma (rIFN-gamma) at doses of 0.5 x 10(4) to 40 x 10(4) U three times a week for 6 weeks beginning at 35 days of age. The effects of altering the duration of treatment (2 to 6 weeks) and the age at which injections were initiated (45 through 65 days) were also assessed. rIFN-gamma administration prevented the development of diabetes in a dose-dependent manner. The optimal treatment condition resulted in a 9.1% incidence of diabetes versus a 90% incidence in control rats. This diabetes-sparing effect was long lasting and continued to 7 months of age. A 4- to 6-week course resulted in maximal inhibition. Treatment initiated as late as 55 days of age, when insulitis is already present, was effective in preventing diabetes. Islet inflammation was dramatically lower in rIFN-gamma- versus saline-injected rats (P < 0.01). Total leukocyte count and subpopulations of peripheral mononuclear cells were unaltered by rIFN-gamma. In summary, rIFN-gamma paradoxically and potently prevents diabetes in BB rats in a dose-dependent fashion by inhibiting islet inflammation. This diabetes-sparing effect occurs even when injections are initiated after evidence of the diabetic process is already present.