Flt3L-Derived Antigen-Presenting Cell Transfer in Neonatal NOD Mice Reduces the Incidence of Type 1 Diabetes.

We have reported previously that chronic and systemic administration of a streptococcal preparation (OK-432), an inducer of TNF, or of recombinant hTNF prevented the development of IDDM in the two animal models of IDDM-NOD mice and BB rats. In this study, we examined the effect of LT, which is structurally and functionally related to TNF, on NOD mice with diabetes. The cumulative incidence of diabetes at 30 wk of age was 22 of 40 (55%) in nontreated female NOD mice and was 4 of 8 (50%; NS), 3 of 29 (10%; P < 0.001), and 0 of 8 (0%; P < 0.001) in female mice treated three times a week from 4 to 30 wk of age with 5, 50, or 500 U of recombinant hLT, respectively. Intensity of insulitis was slightly reduced in the long-term LT-treated mice. LT productivity by ConA-stimulated spleen cells was examined in vitro. Although no significant difference was found between NOD mice and the other mouse strains, female NOD mice were slightly but significantly (P < 0.01) lower producers of LT immunoreactivity than male NOD mice, the diabetes incidence of which is lower than that of females. The SMLR as a marker of normal immune response, which was reported to be impaired in autoimmune animals including NOD mice, was significantly lower in female than male NOD mice. However, the low SMLR in female NOD mice was significantly increased by the administration of LT, and the increase was mediated by the responder cells of the LT-treated mice.(ABSTRACT TRUNCATED AT 250 WORDS)

Streptozotocin (STZ), a selective beta-cell cytotoxin, given in multiple low doses to susceptible mouse strains causes insulin-dependent diabetes mellitus (IDDM) with an autoimmune pathology. Studies in the human suggest that environmental factors such as viruses and certain toxins may modulate the expression of the disease in genetically-prone individuals and the effect may also be age-dependent. Here we have examined the effects of graded, low doses of STZ on beta-cell function and insulin and DNA contents in vitro in cultured islets isolated from female IDDM-prone NOD mice at 4 weeks and at 8 weeks. Results were compared with islets from age and sex-matched non-diabetes prone C57BL/Ks mice. No changes in islet DNA or insulin contents were observed after an acute 30 min exposure to STZ (0, 1.1, 2.2 and 4.4 mM) in the two strains at each of the age groups. However, the DNA content in the NOD mouse islets tended to be lower at 8 weeks, being significant at 1.1 mM STZ. At 4 weeks, islets from NOD mice had a higher insulin content than the control mice but this declined at 8 weeks when it became comparable to the control strain. STZ caused a dose-dependent inhibition of islet glucose oxidation rates in all groups. However, at 4 weeks, exposure to 2.2 mM STZ resulted in a significantly greater inhibition in NOD mice than in age-matched control mice. This was reversed at 8 weeks when the islets from NOD mice showed a greater resistance to oxidative impairment than from C57BL/Ks mice. In the presence of 16.7 mM glucose, an inhibitory pattern, similar to the glucose oxidation rate, was also observed for insulin release. In the control mice the relative inhibition of insulin release and glucose oxidation rate was similar at 4 and 8 weeks. These results suggest that islets from the NOD mouse at 4 weeks and prior to insulitis are more sensitive to STZ-induced functional impairment. This enhanced sensitivity suggests that cumulative exposure of diabetes-prone islets to low doses of selective beta cell toxins may be a determinant for later development of IDDM.

Epigenetic modulation of selected immune response genes and altered functions of T lymphocytes and macrophages collectively contribute to autoimmune diabetes protection

Reduced Expression of c-Fos in Female NOD Mouse Thymocytes and Up-Regulation with Human Lymphotoxin

Regulatory T cells (Tregs) play a critical role in controlling autoreactive T cells, and quantitative and/or qualitative deficiencies in Tregs are associated with autoimmune diseases, including type 1 diabetes (T1D), in both humans and mice. Both the incidence of T1D and percentages of peripheral Tregs in NOD mice vary considerably between animal facilities. In our animal facility, the incidence of T1D in NOD mice is high at 90-100% and the percentages of peripheral CD4+Foxp3+ cells in ~9-10-week-old female NOD mice are decreased compared to control (B6) mice shortly before high glucose is first detected (~12 weeks). These data suggest that there is an imbalance between Tregs and potentially pathogenic effector T cells at this age that could have significant impact on disease progression to overt diabetes. The goal of the current study was to investigate mechanisms that play a role in peripheral Treg : T effector cell balance in NOD mice, including differences in persistence/survival, peripheral homeostatic proliferation, and thymic production and output of CD4+ T cells. We found no differences in persistence/survival or homeostatic proliferation of either Tregs or effector T cells between NOD and B6 mice. Furthermore, although the percentages and absolute numbers of CD4+Foxp3+ cells in thymus were not decreased in NOD compared to B6 mice, the percentage of CD4+ recent thymic emigrants (RTE) that were Foxp3+ was significantly lower in 9-week-old NOD mice. Interestingly, the thymic output of CD4+Foxp3+ cells was not lower in NOD mice, whereas the thymic output of CD4+Foxp3− cells was significantly higher in NOD mice at that age compared to B6 mice. These data suggest that the higher thymic output of CD4+Foxp3− T cells contributes, at least in part, to the lower percentages of peripheral CD4+Foxp3+ Tregs in NOD mice and an imbalance between Tregs and T effector cells that may contribute to the development of full-blown diabetes.

Changes in B and T lymphocytes associated with mycobacteria-induced protection of NOD mice from diabetes.

Similar to pancreatic islets, submandibular glands are more rapidly infiltrated in female NOD mice than in males. The present comparative analysis of cellular infiltrations in lacrimal glands, however, revealed the opposite finding. At 12 wk of age, approximately 25% of male lacrimal tissue area is infiltrated, whereas age-matched female NOD mice still lack major signs of inflammation. T cells predominate in early stages of invasion, but B cells accumulate promptly in more advanced stages, and ultimately dominate over T cells. Dacryoadenitis is promoted by sex hormones, as suggested by the reduced infiltrations seen in orchidectomized NOD males (P < 0.01). It is also controlled by the local environment provided by the lacrimal tissue. Splenocytes from 4- and 20-wk-old female NOD mice cause massive lesions upon adoptive transfer into NOD male recipients while, conversely, female recipients develop barely any histological sign of infiltration, even after transfer of splenocytes from 20-wk-old donor males. These observations provide strong evidence for a dacryoadenitis-promoting role of male gonadal hormones in NOD mice, a finding that contrasts the known androgen-mediated protective effects on insulitis and submandibulitis in the same strain and on dacryoadenitis in other animal models of Sjögren's syndrome.

In type 1 diabetes, environmentally induced early-limited beta cell damage may pre-empt the subsequent immune-mediated beta cell destruction. Low doses of streptozotocin (Stz), given early to diabetes-prone mice, may cause limited beta cell destruction during the early phase and precipitate diabetes. Here, we aimed to see if young NOD mice are more diabetes-sensitive to various multiple low doses of Stz than non-diabetes-prone mice. We also determined the molecular pathology of islets following administration of the diabetogen. Female NOD and CD-1 mice received 5 daily doses of Stz at day 21 (20, 30, and 40 mg/kg body weight; 18 mice per group) or diluent, and diabetes was monitored. Pancreas were studied histochemically and immunohistochemically at various time points after Stz administration. Following administration of Stz, NOD mice showed a much earlier onset and increased diabetes rate, at all three doses, than CD-1 mice. By day 80, the final diabetes rates following the 40, 30, and 20 mg dose in NOD mice were 95%, 85%, and 33%, respectively, compared with 33%, 28%, and 5.5%, respectively, in CD-1 mice. However, following the 20 mg dose, only 2 of the 12 remaining NOD mice developed the disease between 90 and 250 days compared with 19 of 24 NOD mice that did not receive Stz at day 21. Stz-administered NOD and CD-1 mice showed an initial loss of beta cells, with redistribution of islet endocrine cells, early macrophage infiltration, and increasing insulitis.

The NOD mouse, a model for type 1 diabetes, is characterized by resistance to apoptosis in immunocytes. The aim of this study was to investigate a link between apoptosis in NOD thymocytes and autoimmunity. First, we demonstrated that the sexual dimorphism in diabetes incidence in NOD mice (females are more diabetes-prone than males) is reflected by differences in apoptosis. Apoptosis in NOD thymocytes, 24 h after dexamethasone, was decreased in both sexes compared with C57B1/6, but it was lower in female mice (26 +/- 2%) than in male mice (50 +/- 3%, P < 0.001). Further, we demonstrated that sex hormones themselves play a central role in this difference, since castration of NOD male mice, which increases diabetes incidence, decreased apoptosis levels (32 +/- 2%), while treatment of NOD female mice with dihydrotestosterone, which protects against diabetes, restored apoptosis to male levels (42 +/- 1.5%). Finally, we demonstrated that 1,25-dihydroxyvitamin D3, a steroid hormone that prevents diabetes in NOD mice, restored apoptosis levels to C57B1/6 reference levels. This improved apoptosis was seen in male (68 +/- 1 vs. 50 +/- 3% in untreated NOD mice, P < 0.001) but especially in female NOD mice (51 +/- 5 vs. 26 +/- 2% in untreated NOD mice, P < 0.001). Fluorescence-activated cell sorter analysis of thymocyte subsets revealed marked differences, especially in CD4+CD8+ and CD4+ cells. We conclude that the sexual dimorphism in diabetes incidence in NOD mice is paralleled by a dimorphism in resistance to apoptotic signals in NOD thymocytes. This resistance to apoptosis is driven by sex hormones and is corrected by 1,25-dihydroxyvitamin D3.

Immune phenotyping provides insight into disease pathogenesis and prognostic markers. Trajectories from age of 4 to 36 weeks were modeled for insulin autoantibodies and for leukocyte subpopulations in peripheral blood from female NOD (n = 58) and NOR (n = 22) mice. NOD mice had higher trajectories of insulin autoantibodies, CD4+ and CD8+ T lymphocytes, B lymphocytes, IgD+IgM− B lymphocytes, and NK cells and lower trajectories of CD4+CD25+ T lymphocytes, IgM+ B lymphocytes, granulocytes, and monocytes than NOR mice (all p < 0.001). Of these, only the increased IAA trajectory was observed in NOD mice that developed diabetes as compared to NOD mice that remained diabetes-free. Therefore, the profound differences in peripheral blood leukocyte proportions observed between the diabetes-prone NOD mice and the diabetes-resistant mice do not explain the variation in diabetes development within NOD mice and do not provide markers for diabetes prediction in this model.

O196* Aim: Treatment of nondiabetic NOD mice with FTY720 starting at 4 weeks of age, when insulitis has not developed, prevents the onset of overt diabetes. In the present study, we investigated whether FTY720 treatment of NOD mice that harbor established insulitis but remain normoglycemic prevents subsequent development of diabetes. Methods: Beginning from either 14 or 23 weeks of age, nondiabetic female NOD mice were continously given 0.5 mg/kg FTY720 via a gavage needle once a day, five times a week (Monday through Friday). A group of untreated, age-matched female NOD mice served as controls. Mice were monitored twice a week for urine glucose levels. Once urine glucose levels became positive, mice were additionally tested for a nonfasting blood glucose level every 2 – 3 days. Mice with >300 mg/dl blood glucose in 3 consecutive measurements were considered diabetic. Results: Control untreated female NOD mice developed overt diabetes starting at 13 weeks of age and showed diabetes incidence of 65 and 70% at 30 and 40 weeks of age, respectively. Histological examination of the pancreas at 14 and 23 weeks confirmed the presence of insulitis that progressed with age. None of the FTY720-treated NOD mice (8 mice in both groups) developed diabetes regardless of the timing of treatment initiation during the period when FTY720 was given. Intraperitoneal administration of FTY720 was also effective in prevention of diabetes. Light microscopic examination of the pancreases removed from the FTY720-treated diabetes-free mice at 37 or 44 weeks of age revealed islets that were either without lymphocytic infiltrates or with varying degrees of peripheral lymphocytic infiltrates. Invading insulitis was not seen. These islets stained strongly by insulin staining. When oral administration of FTY720 was withdrawn at 37 weeks of age, the majority of mice rapidly developed diabetes. Mice remained diabetes-free when they were continuously treated with FTY720 beyond 37 weeks of age (currently over 44 weeks of age). Conclusion: As generalized immunosuppression is not associated with FTY720, FTY720 may be a safe and benign therapeutic agent that could be used chronically in diabetes prone, yet normoglycemic individuals even after development of insulitis to prevent type 1 diabetes mellitus.

Immunomodulation With SA-FasL Protein as an Effective Means of Preventing Islet Allograft Rejection in Chemically Diabetic NOD Mice

In an effort to study the development of diabetes in NOD mice, our laboratory developed a novel adoptive transfer model using NOD-scid/scid (NOD-scid) mice as recipients of islet-infiltrating lymphocytes from donor prediabetic female NOD mice. We first confirmed previous results that demonstrated that splenocytes of diabetic and prediabetic female NOD mice could transfer diabetes to NOD-scid mice. We demonstrated that the kinetics of disease transfer were dependent on the age of transferred lymphocytes and reiterated the kinetics of diabetes in conventional female NOD mice. We then demonstrated that islet-infiltrating lymphocytes from prediabetic female NOD mice could transfer diabetes. In contrast with the age-dependent transfer of diabetes seen using splenocytes, islet-infiltrating lymphocytes obtained from prediabetic female NOD mice aged > or = 40 days rapidly transferred diabetes to NOD-scid recipients. The time required to transfer insulin-dependent diabetes mellitus (IDDM) using islet-infiltrating lymphocytes from young prediabetic mice (25 +/- 9 days) was not statistically different from the time required to transfer IDDM using splenocytes from overtly diabetic mice (32 +/- 5 days). Cotransfer of splenocyte cells or CD4+, but not CD8+ spleen cells, from 60- to 80-day-old prediabetic female NOD mice together with either splenocytes from diabetic mice or islet-infiltrating lymphocytes from prediabetic NOD mice delayed the rapid transfer of IDDM, suggesting that CD4+ cells mediated immunoregulation. Use of the NOD-scid islet-infiltrating lymphocyte-adoptive transfer model should help elucidate the pathophysiology of the early inflammatory events leading to insulitis and subsequent beta-cell destruction.(ABSTRACT TRUNCATED AT 250 WORDS)

Immunization with streptozotocin-treated NOD mouse islets inhibits the onset of autoimmune diabetes in NOD mice

1,25 dihydroxyvitamin D3, the active form of vitamin D, has immunomodulatory properties in vitro and in vivo. We report that treatment with 1,25 dihydroxyvitamin D3 (5 micrograms/kg on alternate days) prevents the development of clinical diabetes in NOD mice, an animal model of human autoimmune diabetes. Diabetes incidence in female NOD mice at the age of 200 days was reduced to 8% in the 1,25 dihydroxyvitamin D treated group vs 56% in the control group (p < 0.0001). In parallel, treatment with 1,25 dihydroxy-vitamin D3 resulted in a complete normalisation of the capacity to induce suppressor mechanisms in an autologous MLR, which is severely depressed in control NOD mice. The existence of such suppressor cells was confirmed in transfer experiments, whereby cotransfer of splenocytes from 1,25 dihydroxyvitamin D3 treated NOD mice prevented diabetes transfer by splenocytes from diabetic NOD mice into irradiated, 6-8-week-old male NOD mice. Other known immune defects of the NOD mice, such as defective natural killer cell killing of YAC-1 targets and defective thymocyte activation by anti-CD3 were not corrected. The pharmacological doses of 1,25 dihydroxyvitamin D3 were universally well tolerated as reflected by a normal weight gain of the mice. Serum calcium was increased (2.5 +/- 0.2 vs 2.2 +/- 0.2 mmol/l in the control group, p < 0.005), whereas osteocalcin levels nearly doubled and bone calcium content was halved. These findings show that 1,25 dihydroxyvitamin D3 can prevent diabetes in NOD mice, probably through the correction of their defective suppressor function.