S. Reddy

Dietary prevention of diabetes in the non-obese diabetic mouse

SummaryDiabetes prone NOD female mice were fed diets containing different proteins from just before weaning. Only mice receiving meat meal or casein as the protein source developed diabetes at the rate expected from this colony. Lactalbumin and gluten did not precipitate diabetes except in a small number. Casein hydrolysate in lieu of protein protects against overt diabetes, but only if introduced early. The animals which did not show overt diabetes nevertheless had intermittent trace glycosuria and the majority showed mild degrees of peninsular lymphocytic infiltration.

Ontogeny of islet cell antibodies, insulin autoantibodies and insulitis in the non-obese diabetic mouse

SummaryThe predictive value of insulitis, islet cell cytoplasmic antibodies and insulin autoantibodies for insulin-dependent diabetes was studied in young female non-obese diabetic mice. The ontogeny of the three markers was examined cross-sectionally at days 15, 25, 40 and 90 while islet cell antibodies and insulin autoantibodies were studied longitudinally from day 35 or day 144–168 until approximately day 250. Insulitis was first observed at day 40 (50%) and subsequently at day 90 (70%). Islet cell antibodies and insulin autoantibodies were present at day 15 in 46% and 54% of the animals respectively. The rate of islet cell antibodies was slightly higher at day 25 (60%) than at day 40 (40%) and day 90 (54%) whereas antibodies to insulin were present in all samples from day 25–90. At day 40 and day 90 insulitis and insulin autoantibodies were present together in 42% and 70% of the animals, respectively, while insulitis and islet cell antibodies had a lower rate of concordance (17% and 42%, respectively; diabetes rate, 30%). The concordance rates for islet cell antibodies and insulin autoantibodies were 42% at day 40 and 54% at day 90. Concordance for all three markers was first observed at day 40 (17%) which increased to 38% at day 90. In longitudinal studies, islet cell antibodies and insulin autoantibodies were often present together whether or not diabetes supervened. In the islet cell antibody procedure, immunoreactive cells were shown immunohistochemically to correspond with insulin and/or glucagon cells. However, this staining was not suppressible with insulin- or glucagon- absorbed sera, implying the presence of non-hormonal autoantigens. We conclude that the three markers investigated are expressed early after birth and well before clinical symptoms appear in this animal model. Both islet cell antibodies and insulin autoantibodies preceded insulitis but the prevalence rate for each marker or their degree of concordance was different from the anticipated rate of diabetes in our colony. Consequently, the early expression of the three markers alone is not predictive of diabetes although concordance for the two, or all three markers may be of some value. However, no animal developed diabetes without the prior appearance of both islet cell antibodies and insulin autoantibodies.

Tetracycline Treatment Retards the Onset and Slows the Progression of Diabetes in Human Amylin/Islet Amyloid Polypeptide Transgenic Mice

OBJECTIVE Aggregation of human amylin/islet amyloid polypeptide (hA/hIAPP) into small soluble β-sheet–containing oligomers is linked to islet β-cell degeneration and the pathogenesis of type 2 diabetes. Here, we used tetracycline, which modifies hA/hIAPP oligomerization, to probe mechanisms whereby hA/hIAPP causes diabetes in hemizygous hA/hIAPP-transgenic mice. RESEARCH DESIGN AND METHODS We chronically treated hemizygous hA/hIAPP transgenic mice with oral tetracycline to determine its effects on rates of diabetes initiation, progression, and survival. RESULTS Homozygous mice developed severe spontaneous diabetes due to islet β-cell loss. Hemizygous transgenic animals also developed spontaneous diabetes, although severity was less and progression rates slower. Pathogenesis was characterized by initial islet β-cell dysfunction followed by progressive β-cell loss. Islet amyloid was absent from hemizygous animals with early-onset diabetes and correlated positively with longevity. Some long-lived nondiabetic hemizygous animals also had large islet-amyloid areas, showing that amyloid itself was not intrinsically cytotoxic. Administration of tetracycline dose-dependently ameliorated hyperglycemia and polydipsia, delayed rates of diabetes initiation and progression, and increased longevity compared with water-treated controls. CONCLUSIONS This is the first report to show that treating hA/hIAPP transgenic mice with a modifier of hA/hIAPP misfolding can ameliorate their diabetic phenotype. Fibrillar amyloid was neither necessary nor sufficient to cause diabetes and indeed was positively correlated with longevity therein, whereas early- to mid-stage diabetes was associated with islet β-cell dysfunction followed by β-cell loss. Interventions capable of suppressing misfolding in soluble hA/hIAPP oligomers rather than mature fibrils may have potential for treating or preventing type 2 diabetes.

Immunoexpression of Interleukin-1β in Pancreatic Islets of NOD Mice during Cyclophosphamide-accelerated Diabetes: Co-localization in Macrophages and Endocrine Cells and its Attenuation with Oral Nicotinamide

During insulin-dependent diabetes mellitus, islet invading immune cells destroy beta cells over a prolonged asymptomatic pre-diabetic period. Cytokines synthesised and secreted by specific immune cells within the islet infiltrate may be crucial effectors of beta cell destruction or protection during the disease. Interleukin-1β may be a key cytokine which may act in concert with other cytokines in initiating and/or promoting beta cell destruction. We have examined this hypothesis in NOD mice by assessing the intra-islet expression and co-localization of interleukin-1β at different time-points following cyclophosphamide administration. We have also tested the effects of long-term oral nicotinamide given to NOD mice in suppressing intra-islet expression of the cytokine in this accelerated model.Cyclophosphamide was administered to day 95 female NOD mice. Pancreatic tissues were examined by dual-label confocal immunofluorescence microscopy for the expression and co-localization of interleukin-1β at days 0, 4, 7, 11 and at onset of diabetes (day 14). Diabetes developed in 7/11 mice 14 days after administration of cyclophosphamide while nicotinamide completely prevented the disease. At day 0, interleukin-β immunolabelling was observed in selective intra-islet macrophages, several somatostatin cells and in a few beta cells. However, at day 4, it was seen mostly in somatostatin and some beta cells. At day 7, an increasing number of interleukin-1β cells were observed within the islets and co-localized to several somatostatin cells, beta cells and macrophages. The mean number of intra-islet interleukin-1β cells reached a peak at day 11 and was significantly higher than at day 7 (p = 0.05) and at day 14 (onset of diabetes; p = 0.03). At day 11, interleukin-1β immunolabelling was also present in selective macrophages which co-expressed inducible nitric oxide synthase. At onset of diabetes, some macrophages, residual beta cells and somatostatin cells showed immunolabelling for the cytokine. Exposure of NOD mice to oral nicotinamide was associated with a considerably reduced expression of interleukin-1β cells within the islet at day 11 (p = 0.002). We conclude that cylophosphamide treatment enhances the expression of interleukin-1β in selective macrophages, somatostatin and beta cells during the course of the disease. Its expression reaches a maximum immediately prior to onset of diabetes. Interleukin-1β present in intra-islet macrophages, somatostatin and beta cells may influence its expression by autocrine and paracrine means. Interleukin-1β expression within islet macrophages may also up-regulate inducible nitric oxide synthase within the same macrophage or adjacent macrophage populations. These intra-islet molecular events may corroborate with other local cytotoxic processes leading to beta cell destruction. Oral nicotinamide may attenuate intra-islet expression of interleukin-1β and thus inducible nitric oxide synthase during prevention of Type 1 diabetes in this animal model. The expression of interleukin-1β in specific islet endocrine cell-types shown in this study requires furtherbreak investigation.

A combined casein-free-nicotinamide diet prevents diabetes in the NOD mouse with minimum insulitis

We have previously shown that diabetes in the NOD mouse can be prevented if mice are placed from weaning on an infant formula diet in which the protein source is replaced with casein hydrolysate (Pregestimil) or soy protein (Prosobee), or if 1% nicotinamide is given in the drinking water. Nicotinamide somewhat suppresses insulitis but the hydrolysed casein formula does not. In this study, Prosobee was given concurrently with oral nicotinamide from weaning and their effects on the development of insulitis and diabetes measured. These effects were also assessed in mice given Prosobee alone from conception (day -20) or from weaning. Unlike the earlier experiments, a marked suppression of insulitis was observed when the diets and nicotinamide were given concurrently (mean insulitis scores +95% confidence intervals (back transformed): day 40 = 0.4% [0.03, 1.17] vs. 12.5% [2.52, 28.40] and at day 90 = 8.8% [3.65, 15.68] vs. 48.1% [33.89, 62.49], P = 0.0001). A similar suppression was observed on day 90 with Pregestimil combined with nicotinamide 7.3% [3.88, 11.70] vs. 43.8% [32.59, 55.35] (P = 0.0001). Qualitatively, introduction of Prosobee from conception appeared to elicit a greater degree of suppression of insulitis than when introduced from day 21. Insulitis lesions were examined immunohistochemically for CD4, CD8 and MAC-1 cells. The proportion of these cells was not different for any regime despite the great differences in total number of inflammatory cells in and around the islets of mice fed the combined diet. All the three dietary treatments (Prosobee from day -20, Prosobee from day 21, Prosobee+nicotinamide from day 21) resulted in substantial protection from diabetes in mice followed until 250 days. We conclude that the complete prevention of diabetes in the NOD mouse fed a casein-free diet together with nicotinamide is accompanied by marked inhibition of insulitis, which is not seen when either dietary agent is introduced alone. The somewhat greater suppression of insulitis in mice given the soy diet from conception compared to those fed from day 21 may indicate that even maternal diet during gestation may influence diabetes outcome in the offspring.

Low Dose Streptozotocin Causes Diabetes in Severe Combined Immunodeficient (Scid) Mice Without Immune Cell Infiltration of the Pancreatic Islets

Streptozotocin (stz) given in low doses (40 mg/kg body weight) on 5 consecutive days to susceptible strains of mice causes diabetes. Previous studies have shown that the induction of diabetes is associated with inflammatory infiltrates within the pancreatic islets. However, it is unclear whether stz causes limited beta cell destruction followed by insulitis or whether the diabetogen promotes immune cell influx into the pancreatic islets, followed by immune-mediated beta-cell destruction. It is also unclear whether stz given in sub-diabetogenic doses is capable of causing diabetes independent of cell-mediated processes. Here we have examined these possibilities in CB.17 Scid mice which lack functional T and B cells but have immunocompetent macrophages and NK cells. Low dose stz given to Scid mice caused diabetes in approximately 50% of mice of both sexes by 21 days (14/24 males; 10/18 females). Sections of pancreas were examined immunohistochemically for the presence of MAC-1 positive cells (macrophages and natural killer cells) in the exocrine, peri- and intra-islet regions at different time points following the administration of stz. There were no statistically significant differences in the number of immunoreactive cells in the three locations between tissues obtained from stz-injected mice (3, 7, 14 and 21 days after stz injection and at onset of diabetes) and buffer-injected Scid mice. Although diabetic Scid mice showed a reduced number of insulin immunoreactive cells and peri- and intra-islet distributed glucagon cells, no insulitis was seen histochemically. In parallel studies, normal Swiss male mice given stz at a similar dose developed diabetes (10/10) associated with insulitis which consisted predominantly of CD4, CD8 and MAC-1 cells. Balb/c mice given stz similarly, also developed diabetes (5/8) without showing insulitis, although a moderate increase in the number of macrophages were observed within several islets. These studies demonstrate that stz administered in multiple low doses to Scid mice can cause beta cell destruction and diabetes in the absence of immune cell infiltrate within the pancreatic islets.

Inducible nitric oxide synthase in pancreatic islets of the non-obese diabetic mouse: a light and confocal microscopical study of its ontogeny, co-localization and up-regulation following cytokine administration

Nitric oxide has been shown to mediate beta-cell destruction in rodent islets exposed to interleukin 1β in culture. The inhibitory effect is potentiated by tumour necrosis factor-α and interferon- γ. Cytokine stimulation leads to gene transcription and translation of inducible nitric oxide synthase, the biosynthetic enzyme of nitric oxide. In the non-obese diabetic mouse, progressive invasion of pancreatic islets by immune cells may lead to local production of inflammatory cytokines, resulting in inducible nitric oxide synthase expression within the islets. In this study, the ontogeny of this enzyme and its cellular expression were examined in pancreatic sections of female non- obese diabetic mice by double-label immunofluorescence. Light and confocal microscopy were employed to study the up-regulation, co- localization and immunocytoplasmic distribution of the enzyme in female non-obese diabetic and Swiss mice following cytokine treatment. From day 40 to day 220 a small number of beta-cells and a proportion of macrophages, usually in peri-islet and exocrine areas, expressed the enzyme. At onset of diabetes, an increasing number of macrophages within and surrounding the islets were positive for the enzyme. Treatment of day 60 female non-obese diabetic mice with interleukin 1β alone and in combination with tumour necrosis factor-α and/or interferon- γ resulted in a significant influx of macrophages into the pancreas, while this was lower in female Swiss mice treated similarly. Cytokine administration led to intense but sometimes eccentric immunocytoplasmic labelling for the enzyme in a considerable proportion of macrophages and beta-cells. Macrophages positive for inducible nitric oxide synthase were located in peri- and intra-islet areas, being distal and adjacent to enzyme-positive and negative beta-cells. Treatment with tumour necrosis factor-α and/or interferon-γ did not lead to enzyme up-regulation. These results show that in the non-obese diabetic mouse there is low and sustained expression of islet inducible nitric oxide synthase in the prediabetic period, which is followed by an increase around onset. However, treatment of female non-obese diabetic and Swiss mice with interleukin- 1β, alone or together with tumour necrosis factor-α and/or interferon-γ leads to a marked expression of this enzyme within macrophages and beta-cells

Longitudinal study of islet cell antibodies and insulin autoantibodies and development of diabetes in non-obese diabetic (NOD) mice

We have previously shown the presence of circulating islet cell cytoplasmic antibodies (ICA) and insulin autoantibodies (IAA) in the NOD mouse before onset of insulin‐dependent diabetes mellitus (IDDM). Here we have determined the levels of the two autoantibodies in 28 female NOD mice longitudinally from approximately day 40 to day 250, to examine their ontogeny, association and predictive value for diabetes. All animals (11 diabetic, 17 non‐diabetic) showed varying levels of ICA at some stage, while IAA activity was found in 21 out of 28 mice. Expression of both the markers was seen in more than half of the animals by day 60, with higher levels and rates occurring subsequently in both diabetic and non‐diabetic groups. The expression of ICA did not always correlate with that of IAA. There was no apparent difference in the ontogeny of ICA and IAA between the two groups. During the study period the number of animals with ICA was similar in the two groups, while the number of those with IAA was higher in the diabetic animals. In this group declining and rising levels of ICA were seen just before clinical diabetes with frequent peaks of IAA. In the same animals, eight out of 11 mice showed co‐expression of high levels of both markers either intermittently or persistently prior to onset, whereas only one non‐diabetic animal showed this. We conclude that the ontogeny and serum level of ICA or IAA alone could not be used to predict the clinical onset of diabetes in these animals. However, co‐expression of high levels of both markers prior to onset may suggest a strong predisposition to clinical diabetes. This may have relevance to attempts to predict the onset of IDDM in humans who have one or both of these immunological markers.

First phase insulin release in the non-obese diabetic mouse: correlation with insulitis, beta cell number and autoantibodies

The ontogenic variation of beta cell function and its relationship with the degree of islet damage and levels of autoantibodies have been studied in the non-obese diabetic (NOD) mouse model. We conducted in vivo first phase insulin release (FPIR) in response to intravenous glucose and studied its correlation with the degree of insulitis, islet cell antibody (ICA) and insulin autoantibody (IAA) levels in female NOD mice cross-sectionally at days 40 (n = 19), 90 (n = 21), 150-160 (n = 21) and day 250 (n = 20). The mean +/- SEM FPIR values showed an age-related decline from day 40 (46.2 +/- 5.3 microU/ml) to day 150-160 (17.8 +/- 2.5 microU/ml) and then doubled at day 250 (34.5 +/- 5 microU/ml), while the mean +/- SEM insulitis scores increased progressively until day 150-160 (61.7 +/- 6.1%) and then declined slightly at day 250 to 50.2 +/- 6.2%. In female NOD mice with spontaneous diabetes (n = 4) and streptozotocin-induced diabetic Swiss mice (n = 5) FPIR was either absent or greatly attenuated. A statistically significant inverse correlation between FPIR and insulitis was found among NOD mice at days 90 (P = 0.02; r = -0.52) and 150-160 (P = 0.03; r = -0.48). However, no statistically significant correlation was observed at days 40 and 250. Morphometric techniques applied to day 150-160 pancreatic sections showed a statistically significant negative correlation between insulitis and beta cell number per unit area of islet tissue (P = 0.0001; r = - 0.75). At this age some islet beta cells showed different intensities of staining by immunofluorescence.(ABSTRACT TRUNCATED AT 250 WORDS)

Longitudinal study of first phase insulin release in the BB rat

SummaryFirst phase insulin release was measured in response to intravenous glucose given weekly from approximately day 40 in 6 BB rats which subsequently developed diabetes and in age-matched non-diabetic (n =15) and normal Wistar rats (n = 8) until day 180. The mean sequential insulin responses in BB rats with and without diabetes were significantly lower (p = 0.008 and < 0.0001, respectively) than in normal rats from an early age. Five diabetic BB rats showed a progressive decline in first phase insulin release immediately prior to glycosuria, with the impaired phases ranging from 25–50 days. However, protracted periods of low first phase responses were also seen in several aglycosuric BB rats, which showed histological evidence of insulitis and B-cell loss. Our findings demonstrate that, although most BB rats with diabetes show a progressive impairment of B-cell function preceding the disease, this aberrant phase can also be present in BB rats which remain aglycosuric. Impaired first phase insulin release in response to serial intravenous glucose tolerance tests may not be a reliable predictor of Type 1 (insulin-dependent) diabetes in this animal model.