Altered monocyte cyclo-oxygenase response in non-obese diabetic mice.

Monocytes infiltrate islets in non-obese diabetic (NOD) mice. Activated monocyte/macrophages express cyclo-oxygenase-2 (COX-2) promoting prostaglandin-E(2) (PGE(2)) secretion, while COX-1 expression is constitutive. We investigated in female NOD mice: (i) natural history of monocyte COX expression basally and following lipopolysaccharide (LPS) stimulation; (ii) impact of COX-2 specific inhibitor (Vioxx) on PGE(2), insulitis and diabetes. CD11b(+) monocytes were analysed for COX mRNA expression from NOD (n = 48) and C57BL/6 control (n = 18) mice. NOD mice were treated with either Vioxx (total dose 80 mg/kg) (n = 29) or methylcellulose as control (n = 29) administered by gavage at 4 weeks until diabetes developed or age 30 weeks. In all groups, basal monocyte COX mRNA and PGE(2) secretion were normal, while following LPS, after 5 weeks of age monocyte/macrophage COX-1 mRNA decreased (P < 0.01) and COX-2 mRNA increased (P < 0.01). However, diabetic NOD mice had reduced COX mRNA response (P = 0.03). Vioxx administration influenced neither PGE(2), insulitis nor diabetes. We demonstrate an isoform switch in monocyte/macrophage COX mRNA expression following LPS, which is altered in diabetic NOD mice as in human diabetes. However, Vioxx failed to affect insulitis or diabetes. We conclude that monocyte responses are altered in diabetic NOD mice but COX-2 expression is unlikely to be critical to disease risk.

Lack of effect of vitamin D administration during pregnancy and early life on diabetes incidence in the non-obese diabetic mouse.

BACKGROUND AND AIMS: Several studies have suggested that vitamin D supplementation in early life may reduce the risk of developing type 1 diabetes in later life. The non-obese diabetic (NOD) mouse is a model of spontaneous type 1 diabetes currently used for testing hypothesis/compounds aimed at disease prevention. In this study, we tested the effect of vitamin D (16 IU by gavage) on diabetes incidence in NOD/Ba mice treated from conception with olive oil containing vitamin D via maternal dosing up to 10 weeks of age and followed up until 32 weeks of age. METHODS: Twelve breeding pairs were administered olive oil containing vitamin D during pregnancy, 15 days following the birth of the pups and for the next 10 weeks subsequently. The same breeding pairs were bred again after a clearance period of 15 days using a control solution to produce a control litter. This control group received a control solution for the same period of time. Diabetes incidence, degree of insulitis, and insulin content in the pancreas were investigated in the two groups. RESULTS: 12 vitamin D-treated NOD mice developed diabetes compared to 15 animals in the control group (Log rank test p = 0.899, NS). There were no significant differences between the groups in diabetes incidence, time of onset of the disease, degree of insulitis, or the insulin content in the pancreas. CONCLUSION: Vitamin D administered in utero and in the early stages of life at the dosage used does not change the incidence of diabetes or modify the disease process that leads to beta cell destruction in the NOD mouse.

The natural history of insulin content in the pancreas of female and male non-obese diabetic mouse: implications for trials of diabetes prevention in humans.

BACKGROUND: The non-obese diabetic (NOD) mouse is a well-established animal model used to study the pathogenesis of type 1 diabetes. The NOD mouse spontaneously develops an autoimmune form of the disease between 12 and 18 weeks of age, characterized by an infiltration of the endocrine pancreas by autoreactive mononuclear cells. In our colony, all animals showed signs of insulitis, but only approximately 60% of females and 15% of males developed diabetes. The aim of this study was to determine the natural history of insulin content in the pancreas of female and male NOD/Ba mice during their life span. METHODS: Pancreata were collected at two-week intervals, from 4 weeks of age to 30 weeks of age. Four animals at each age as well as 18 diabetic female NOD mice were studied. Pancreata were homogenized, supernatants collected and insulin measured by radioimmunoassay. RESULTS: Female and male non-diabetic NOD mice showed significantly higher levels of insulin in the pancreata in comparison to the diabetic female animals. Pancreata from female (n = 56) animals showed more insulin content than male pancreata (n = 56), suggesting beta-cell hyperactivity as a result of the ongoing beta-cell destruction. However this difference was only significant at an early age (4-12 weeks of age) (p < 0.04). Insulin content in diabetic female NOD pancreas declines with time, and was very low at the age of 25 to 34 weeks. This decline was not observed in male pancreata despite the presence of lymphocytic infiltration. CONCLUSION: We conclude that a reduction in pancreatic insulin content occurs slowly in the natural history of the disease and that such reduction only becomes apparent after diagnosis of hyperglycaemia. Occurrence of extensive lymphocytic infiltration in non-diabetic male mice is not accompanied by a reduction of insulin content in the pancreas. These findings have implications for designing studies in humans which aims to protect residual beta-cell function.

A role for innate immunity in type 1 diabetes?

Two arms of the immune system, innate and adaptive immunity, differ in their mode of immune recognition. The innate immune system recognizes a few highly conserved structures on a broad range of microorganisms. On the other hand, recognition of self or autoreactivity is generally confined to the adaptive immune response. Whilst autoimmune features are relatively common, they should be distinguished from autoimmune disease that is infrequent. Type 1 diabetes is an immune-mediated disease due to the destruction of insulin secreting cells mediated by aggressive immune responses, including activation of the adaptive immune system following genetic and environmental interaction. Hypotheses for the cause of the immune dysfunction leading to type 1 diabetes include self-reactive T-cell clones that (1) escape deletion in the thymus, (2) escape from peripheral tolerance or (3) escape from homeostatic control with an alteration in the immune balance leading to autoimmunity. Evidence, outlined in this review, raises the possibility that changes in the innate immune system could lead to autoimmunity, by either priming or promoting aggressive adaptive immune responses. Hostile microorganisms are identified by genetically determined surface receptors on innate effector cells, thereby promoting clearance of these invaders. These innate effectors include a few relatively inflexible cell populations such as monocytes/macrophages, dendritic cells (DC), natural killer (NK) cells, natural killer T (NKT) cells and gammadelta T cells. Recent studies have identified abnormalities in some of these cells both in patients with type 1 diabetes and in those at risk of the disease. However, it remains unclear whether these abnormalities in innate effector cells predispose to autoimmune disease. If they were to do so, then modulation of the innate immune system could be of therapeutic value in preventing immune-mediated diseases such as type 1 diabetes.