Therapeutic effects of dehydroepiandrosterone (DHEA) in diabetic mice

Dehydroepiandrosterone (DHEA), a major adrenal secretory steroid in humans, was therapeutic when fed in a concentration of 0.4% to C57BL/KsJ mice with either non-insulin-dependent or insulin-dependent diabetes. Genetically diabetic (db/db) mice of both sexes develop obesity and a glucose intolerance and hyperglycemia associated with insulin resistance by 2 mo of age, and exhibit beta-cell necrosis and islet atrophy by 4 mo. In contrast, DHEA feeding initiated between 1 and 4 mo of age, while only moderately effective in preventing obesity, did prevent the other pathogenic changes and effected a rapid remission of hyperglycemia, a preservation of beta-cell structure and function, and an increased insulin sensitivity as measured by glucose tolerance tests. DHEA feeding was also therapeutic to normal C57BL/KsJ male mice made diabetic by multiple low doses of streptozotocin (SZ). While DHEA treatments did not block either the direct cytotoxic action of SZ on beta-cells or the development of insulitis, the steroid significantly moderated the severity of the ensuing diabetes (reduced hyperglycemia and water consumption, and increased plasma insulin and numbers of residual, granulated beta-cells.     

Quantitative analysis of pancreatic proinsulin mRNA in genetically diabetic (db/db) mice

C57BL/KsJ db/db mice develop hyperphagic obesity and nonketotic diabetes similar to non-insulin-dependent diabetes mellitus in humans. Initially the mice demonstrate an abundant beta-cell mass and hyperinsulinemia, which is followed by apparent beta-cell loss. As an index of insulin synthesis, this study assesses pancreatic proinsulin mRNA, measured by dot hybridization to cloned cDNA, during the development of diabetes in the mice. Changes in proinsulin mRNA from 5 to 13 wk of age are compared with serum insulin, pancreatic insulin content, and blood glucose. In control (+/db) mice, total proinsulin mRNA and pancreatic insulin content increased with age. Both changes were proportional to an increase in body weight. Obesity, hyperglycemia, and hyperinsulinemia were evident in diabetic (db/db) mice at 5 wk of age. Although pancreatic insulin content was comparable to that in the +/db controls at 5 wk, a fourfold relative elevation of proinsulin mRNA was observed. Despite an increase in body weight, proinsulin mRNA concentration and total proinsulin mRNA fell to levels similar to those of the control mice at 10 and 13 wk, associated with a loss of hyperinsulinemia, a mild decrease in pancreatic insulin content, and a marked increased in fasting blood glucose. A separate group of db/db mice was pair fed with the +/db controls from 4 to 13 wk. These diet-restricted diabetic mice were heavier than control mice and gained weight with age, but they weighed less than the unrestricted mice at all ages. Compared with the unrestricted db/db mice, a more modest fasting hyperglycemia was apparent, and a persistent hyperinsulinemia was observed.(ABSTRACT TRUNCATED AT 250 WORDS)     

NOR/Lt mice: MHC-matched diabetes-resistant control strain for NOD mice.

NOR/Lt is an insulitis-resistant and diabetes-free strain produced from an isolated genetic contamination within an NOD/Lt pedigree line. The albino coat-color phenotype, strain-specific endogenous retroviral profile, and skin graft tests indicated an NOD/Lt x C57BL/KsJ outcross-backcross segregant as the source of the contaminating genome. Analysis of 53 polymorphic DNA, biochemical, and immunologic markers distinguishing NOD/Lt from C57BL/KsJ revealed that 4 chromosomes (chromosomes 2, 4, 11, and 12) in NOR/Lt contained C57BL/KsJ-derived genes. The remaining markers on 14 chromosomes, including the diabetogenic H-2g7 complex on chromosome 17, were of NOD origin. Although completely resistant to cyclophosphamide-induced diabetes, NOR/Lt mice exhibited the same peripheral T-lymphocyte accumulation characteristic of NOD/Lt. Similarly, NOR/Lt peritoneal macrophages exhibited depressed interleukin-1 secretion characteristic of NOD/Lt. In addition to their diabetes resistance, NOR/Lt mice were distinguished from NOD/Lt by exhibiting more robust suppressor T-lymphocyte function. Outcross of NOR/Lt with NOD/Lt to generate heterozygosity at those chromosomal segments, defined by C57BL/KsJ markers in NOR/Lt parentals, did not produce insulitis or diabetes in F1 females. However, these F1 females were sensitive to cyclophosphamide-induced diabetes. In summary, the NOR/Lt strain is an MHC-matched diabetes-resistant control strain for NOD/Lt. Moreover, NOR/Lt will help identify the location and function of a non-MHC gene or genes capable of conferring resistance against insulitis and diabetes.     

Estrone treatment dissociates primary versus secondary consequences of "diabetes" (db) gene expression in mice

Feeding 0.001% estrone in a diet to C57BL/KsJ mice homozygous for the recessive obesity gene "diabetes" (db) permitted dissociation of the primary consequences of obesity gene expression from the secondary consequences of diabetes effected through interaction between the db gene and other diabetogenic genes in the inbred background. Estrone-treated db/db mice were similar to untreated mutants in exhibiting hyperphagia and marked obesity. However, estrone-treated mutants did not develop the hyperinsulinemia, hyperglycemia, and islet atrophy characteristic of untreated db/db mice. Thus, expression of the primary defect could be studied in the absence of the myriad secondary sequelae elicited by chronic hyperinsulinemia and hyperglycemia. Reduced numbers of hepatocyte plasma membrane insulin receptors (50% of normal) persisted in the estrone-treated mice in the absence of hyperinsulinemia, indicating that this deficiency was a consequence of the primary genetic defect and not merely a downregulation phenomenon secondary to hyperinsulinemia. Comparison of insulin secretion from comparably sized +/+ islets versus islets from estrone-treated db/db mice showed no intrinsic defects in beta-cell sensitivity to glucose. In conclusion, db-induced obesity can be dissociated from hyperinsulinemia, hyperglycemia, beta-cell dysfunction, and hyperphagia but is associated with a generalized membrane defect reflected in part by the persistent deficiency of plasma membrane insulin receptors.     

Effect of genetic background on the therapeutic effects of dehydroepiandrosterone (DHEA) in diabetes-obesity mutants and in aged normal mice

Dehydroepiandrosterone (DHEA) was fed at 0.1-0.4% in the diet to genetically diabetic (db/db) or obese (ob/ob) C57BL/KsJ (BL/Ks) or C57BL/6J (BL/6) mice. Treatment of BL/Ks-db/db or ob/ob mice with 0.4% DHEA prevented hyperglycemia, islet atrophy, and severe diabetes associated with this inbred background, but did not affect weight gain and food consumption. Homozygous obese (ob) or diabetes (db) mice on the BL/6 background were more sensitive to DHEA, and the mild, transient hyperglycemia associated with ob or db gene expression on the BL/6 inbred background could be prevented by 0.1% DHEA. Both body weight and food consumption were decreased in BL/6 mutants maintained on 0.1% DHEA whereas this effect was not seen in BL/Ks mutants fed up to 0.4% DHEA. Early therapy with 0.4% DHEA, initiated at 2 wk of age, prevented the development of most diabetes symptoms and decreased the rate of weight gain in pups of all genotypes. In addition to therapeutic effects on both obese mutants, DHEA effected significant changes in an aging study using normal BL/6 female mice. Four weeks of DHEA treatment initiated at 2 yr of age improved glucose tolerance and at the same time reduced plasma insulin to a "younger" level. This suggests that DHEA may act in insulin-resistant mutant mice and in aging normal mice to increase the sensitivity to insulin.     

Genetic control of organ-reactive autoantibody production in mice by obesity (ob) diabetes (db) genes

Inbred strains of mice exhibited genetic and sex-dependent differences in spontaneous production of organ-reactive autoantibodies detected by indirect immunofluorescence. Antitestis autoreactivity was found primarily in sera from C57BL/6J (B6) mice, whereas antigastric autoreactivity was common to both CBA/J and 129/J strains. Autoantibodies against islet cell cytoplasmic antigens (ICAs) were uniquely expressed by C57BL/KsJ (BKs) males. Introduction of the diabetes (db) mutation into these various inbred-strain backgrounds induced expression of ICA, with stronger induction observed in males. The stress imposed by the db or obesity (ob) mutation induced ICA in BKs mice at a higher frequency than in B6 mice; this differential sensitivity was somehow related to a gene linked to the H-2 complex because BKs.B6 H-2b congenic mice resembled B6 mice. The db3J mutation increased the expression of these autoantibodies in 129/J mice, which, like B6, were H-2b and therefore presumably possessed the same H-2-linked inducibility allele as BKs. Cytotoxic autoantibodies against islet cell surface antigens were only observed in C3HeB/FeJ db/db males, and their presence was correlated with beta-cell necrosis. It is concluded that db and/or ob genes appear to play an important role in the production of autoantibodies to islet cells, and sex-linked factor(s) may modify the phenotypic expression of the autoantibodies.     

Genetic control of diabetogenesis in NOD/Lt mice. Development and analysis of congenic stocks

Genetic outcross and backcross analysis of nonobese diabetic (NOD/Lt) mice with a related but diabetes-resistant strain, nonobese normal (NON/Lt), has demonstrated that susceptibility to insulin-dependent diabetes mellitus is controlled in a recessive fashion by multiple genetic loci, including one (Idd-1s) associated with H-2 on chromosome 17 and another (Idd-2s) associated with Thy-1b/Apoa-1b (formerly Alp-1) on chromosome 9. To analyze the separate pathogenic contributions of Idd-1s and Idd-2s, two distinct congenic stocks of NOD/Lt mice homozygous on chromosomes 17 and 9 for NON/Lt linkage markers for the respective resistance alleles (Idd-1r and Idd-2r) were developed. The recessive nature of Idd-1s was confirmed at the fifth backcross generation in that 83% of females and 29% of males homozygous for NOD H-2 haplotype developed diabetes, whereas no diabetes occurred in any of the mice homozygous or heterozygous for the NON haplotype. However, codominant and recessive MHC-associated susceptibility genes in this congenic stock were indicated by the finding that at least one copy of the NOD/Lt MHC was required for insulitis development. Virtually no insulitis was detected in the pancreases of mice homozygous for NON haplotype at 42 wk of age, whereas heavy generalized insulitis was present in 3 of 19 H-2 heterozygotes and in 7 of 7 diabetic and 3 of 5 nondiabetic mice homozygous for NOD haplotype. Further indication of the presence of MHC-associated codominant and recessive MHC-associated susceptibility genes was the observation that the NOD MHC haplotype correlated in a codominant fashion with a relative increase in the percentage of splenic T-lymphocytes bearing the Ly-2 surface marker. Severe insulitis and concomitant high diabetes incidences occurred in all genotypic classes of congenic mice carrying Thy-1/Apoa-1 linkage markers for either NOD or NON alleles at Idd-2. Molecular analysis indicated that the NON-derived Idd-2r resistance allele had been replaced by recombination with Idd-2s from NOD. Restriction-fragment-length polymorphism analysis of two polymorphic markers proximal to Thy-1, low-density lipoprotein receptor Ldlr and Ets-1, a protooncogene, confirmed a recombinant chromosome 9, because homozygosity for NOD genomic fragments was found centromeric to an NON congenic segment of at least 20 centiMorgans spanning the Thy-1 and Mod-1 loci.(ABSTRACT TRUNCATED AT 400 WORDS)     

Reduction of glycemic and lipid levels in db/db diabetic mice by psyllium plant fiber

The soluble plant fiber psyllium significantly reduced fasting glucose and total cholesterol levels in the C57BL/KsJ db/db diabetic mouse relative to placebo-fed mice. Insulin levels were significantly higher in psyllium-fed than placebo-fed animals, indicating this fiber may delay the progression of diabetes in the animal model. High-density lipoprotein cholesterol levels rose moderately in both psyllium- and placebo-fed animals during the study, whereas triglyceride levels remained unchanged in both groups. Psyllium's effect on glycemic, lipid, and hormone parameters was not explained by weight loss or reduced food intake; these were similar in psyllium- and placebo-fed animals during the study. Our results show that psyllium fiber can beneficially moderate glycemic and lipid parameters in the db/db diabetes model.     

T-lymphopenia and T-cell imbalance in diabetic db/db mice

The diabetic db/db mice of the C57 BL/KsJ strain display anti-islet immunity, thymic dysfunction, and lymphopenia. In the present work, lymphocytes, T-cells, and T-cell subsets were enumerated in thymus and spleen from diabetic db/db mice and their db/ + heterozygote littermates from the 10th day to the 10th month of life. A significant lymphopenia was detected in thymus and spleen from the second month on, involving specifically the T-cell compartment, as assessed by use of a monoclonal anti-Thy1 antibody in indirect fluorescence. The study of T-cell subsets by monoclonal anti-Lyt1 and anti-Lyt2 antibodies revealed a significant increase in Lyt1+ cells and a decrease in Lyt2+ cells, with a corresponding increase of the Lyt1+/Lyt2+ ratio. These anomalies appeared early in life, and were apparently linked neither with the degree of hyperglycemia nor with weight loss or infection. The T-cell depletion in thymus was more pronounced in young male (less than 3 mo) than in young female db/db mice. These alterations may correspond to an increase in the helper/suppressor-cytotoxic ratio and could be linked with the thymic anomalies present in these mice, contributing to the development of anti-islet autoimmunity.     

PPARalpha agonist fenofibrate improves diabetic nephropathy in db/db mice

Peroxisome proliferator-activated receptor alpha (PPARalpha) is a member of the ligand-activated nuclear receptor superfamily, and plays an important role in lipid metabolism and glucose homeostasis. The purpose of this study is to determine whether the activation of PPARalpha by fenofbrate would improve diabetes and its renal complications in type II diabetes mellitus. Male C57 BLKS db/db mice and db/m controls at 8 weeks of age were divided to receive either a regular diet chow (db/db, n=8; db/m, n=6) or a diet containing fenofibrate (db/db, n=8; db/m, n=7). Mice were followed for 8 weeks. Fenofibrate treatment dramatically reduced fasting blood glucose (P<0.001) and HbA1c levels (P<0.001), and was associated with decreased food intake (P<0.01) and slightly reduced body weight. Fenofibrate also ameliorated insulin resistance (P<0.001) and reduced plasma insulin levels (P<0.05) in db/db mice. Hypertrophy of pancreatic islets was decreased and insulin content markedly increased (P<0.05) in fenofibrate-treated diabetic animals. In addition, fenofibrate treatment significantly reduced urinary albumin excretion (P<0.001). This was accompanied by dramatically reduced glomerular hypertrophy and mesangial matrix expansion. Furthermore, the addition of fenofibrate to cultured mesangial cells, which possess functional active PPARalpha, decreased type I collagen production. Taken together, the PPARalpha agonist fenofibrate dramatically improves hyperglycemia, insulin resistance, albuminuria, and glomerular lesions in db/db mice. The activation of PPARalpha by fenofibrate in mesangial cells may partially contribute to its renal protection. Thus, fenofibrate may serve as a therapeutic agent for type II diabetes and diabetic nephropathy.     

Peptide and major histocompatibility complex-specific breaking of humoral tolerance to native insulin with the B9-23 peptide in diabetes-prone and normal mice

NOD mice spontaneously develop anti-insulin autoantibodies and diabetes. A dominant peptide recognized by T-cell clones from NOD mice is insulin B-chain peptide B9-23. When administered subcutaneously to NOD mice, this peptide decreases the development of diabetes. In this study, we evaluated the autoantibody response to native insulin after administration of the B9-23 peptide. In NOD mice, administration of the B9-23 peptide in incomplete Freund's adjuvant enhanced their insulin autoantibody response with a higher level and longer persistence. Induction of insulin autoantibodies with the B9-23 peptide was observed in non-diabetes-prone BALB/c mice and NOR mice within 2 weeks of administration, but this was not observed in C57BL/6 mice. A series of A-chain, other B-chain, and proinsulin peptides did not induce insulin autoantibodies. Induced anti-insulin autoantibodies could not be absorbed with the peptide alone but could be absorbed with native insulin. The B13-23 peptide (one of two identified epitopes within B9-23) when administered to BALB/c mice, induced autoantibodies, whereas peptide B9-16 did not. Induction of autoantibodies mapped to the major histocompatibility complex (MHC) rather than to the background genes. Both splenocytes with I-A(d)/I-E(d) or I-A(g7)/I-E(null) presented the B9-23 peptide to NOD islet-derived T-cell clones. Finally, administration of the B9-23 peptide to BALB/c mice, even without adjuvant, could induce insulin autoantibodies. Our results indicate that B-cell tolerance to intact insulin is readily broken with the presentation of the B9-23 insulin peptide, depending on the host's specific MHC.     

Temporal relationship of tissue somatostatin-like immunoreactivity to metabolic changes in genetically obese and diabetic mice

Somatostatin-like immunoreactivity (SRIF-LI) content in 2 N acetic acid extracts of hypothalamus, gastric antrum, and pancreas was measured in genetically obese (C57BL/6J ob/ob and db/db) and diabetic (C57BL/KsJ db/db and ob/ob) mice and normal littermate controls from 5 to 24 wk to determine the relationship of previously reported changes to the development of metabolic abnormalities. Hypothalamic SRIF-L concentration was similar in control, diabetic, and obese mice at all ages and increased progressively with age in all groups. Gastric antrum SRIF-LI was similar in all groups of mice at all ages. Obese mice gained weight progressively and showed moderate hyperglycemia and marked hyperinsulinemia from 5 wk of age. Pancreatic SRIF-LI content in obese (C57BL/6J) animals was similar to that in lean littermate controls, but pancreatic SRIF-LI concentration (expressed by weight or protein content) was decreased until 8 (6J ob/ob) and 10 (6J db/db) wk. Diabetic (C57BL/KsJ) mice showed a similar metabolic pattern until 10 wk with no change in pancreatic SRIF-LI content or concentration. Thereafter a progressive fall in serum insulin and a marked rise in serum glucose was associated with increasing pancreatic SRIF-LI content and concentration. These studies suggest that the genetically hyperphagic syndromes are unassociated with any change in hypothalamic or gastric SRIF-LI; that pancreatic SRIF-LI increases occur in response to, rather than as the cause of, relative hypoinsulinemia; and that the genetic background of the mice (KsJ or 6J) rather than the mutant gene (db or ob) determines the defect in carbohydrate metabolism and the pancreatic SRIF-LI response.     

Insulin autoantibodies are associated with islet inflammation but not always related to diabetes progression in NOD congenic mice

Susceptibility to diabetes in humans and nonobese diabetic (NOD) mice is believed to arise from the combined effect of multiple genetic loci, resulting in immune-mediated destruction of the insulin-secreting beta-cells. Insulin autoantibodies (IAAs) are often present in humans for years, and in NOD mice for weeks, before the onset of diabetes. We have evaluated the expression of IAAs in NOD mice and in diabetes-resistant NOD congenic strains to characterize the association of autoantibody expression with insulitis and diabetes. In NOD congenic strains with genes that contribute to protection from insulitis and diabetes (Idd3, Idd5, Idd10, and Idd18), the prevalence of IAAs is reduced relative to NOD mice. In contrast, NOD.B10 Idd9 mice have a high prevalence of IAAs and a high degree of insulitis, despite a nearly complete resistance to diabetes. These data indicate that IAA expression is a phenotype that is associated with insulitis and correlates with overall disease progression in some strains of congenic mice but not in others. It is likely that patients with type 1 diabetes will also show non-major histocompatibility complex genetically determined variation in expression of autoantibodies and progression to diabetes.     

Islet allograft survival induced by costimulation blockade in NOD mice is controlled by allelic variants of Idd3

NOD mice develop type 1 autoimmune diabetes and exhibit genetically dominant resistance to transplantation tolerance induction. These two phenotypes are genetically separable. Costimulation blockade fails to prolong skin allograft survival in (NOD x C57BL/6)F1 mice and in NOD-related strains made diabetes-resistant by congenic introduction of protective major histocompatibility complex (MHC) or non-MHC Idd region genes. Here, we tested the hypothesis that the genetic basis for the resistance of NOD mice to skin allograft tolerance also applies to islet allografts. Surprisingly, costimulation blockade induced permanent islet allograft survival in (NOD x C57BL/6)F1 mice but not in NOD mice. After costimulation blockade, islet allograft survival was prolonged in diabetes-resistant NOD.B6 Idd3 mice and shortened in diabetes-free C57BL/6 mice congenic for the NOD Idd3 variant. Islet allograft tolerance could not be induced in diabetes-resistant NOD.B10 Idd5 and NOD.B10 Idd9 mice. The data demonstrate that 1) NOD mice resist islet allograft tolerance induction; 2) unlike skin allografts, resistance to islet allograft tolerance is a genetically recessive trait; 3) an Idd3 region gene(s) is an important determinant of islet allograft tolerance induction; and 4) there may be overlap in the mechanism by which the Idd3 resistance locus improves self-tolerance and the induction of allotolerance.     

An ascochlorin derivative, AS-6, reduces insulin resistance in the genetically obese diabetic mouse, db/db

An ascochlorin derivative, AS-6, is a new hypoglycemic agent orally active in both obese hyperinsulinemic and insulin-deficient diabetic animal models. AS-6, when given as a 0.025-0.2% admixture in the diet, dose-dependently ameliorated polydipsia, polyuria, and glycosuria in the genetically obese diabetic mouse, C57BL/KsJ db/db, while neither insulin nor tolbutamide showed any beneficial effects. The amelioration by AS-6 was associated with a marked decrease in serum glucose and triglyceride. The effects persisted at least 10 wk, accompanied by a steady decrease in drinking water consumption. The chronic treatment prevented pancreatic islet degeneration, e.g., degranulation of the beta-cells, basophilic appearance of the exocrine border around the islets, and small round cell infiltration. The isolated islets from AS-6-treated mice released much more insulin in response to glucose than those from untreated controls. A significant correlation between serum immunoreactive insulin and glucose/triglyceride from both treated and untreated mice suggests that AS-6 restores sensitivity and responsiveness to insulin to the mice. In fact, the combined treatment with insulin synergistically decreased serum glucose by 50% below AS-6 treatment alone. Furthermore, the epididymal fat pad slices from AS-6-treated db/db mice increased CO2 generation and lipogenesis over the untreated controls, and the glucose metabolic rate (CO2 generation plus lipogenesis from U-[14C]-glucose) in the slices and the serum glucose level inversely correlated at r = 0.8799.(ABSTRACT TRUNCATED AT 250 WORDS)     

The influence of the major histocompatibility complex on development of autoimmune diabetes in RIP-B7.1 mice

The most important genetic susceptibility factor for type 1 diabetes is encoded in the major histocompatibility complex (MHC). The nonobese diabetic (NOD) mouse, which develops spontaneous diabetes, expresses H-2g7 comprising the MHC class I molecules Kd and Db and the MHC class II molecule I-Ag7. However, neither B6.H-2g7 mice, in which H-2g7 is expressed on the C57BL/6 genetic background, nor the nonobese resistant (NOR) mouse, in which H-2g7 is expressed on a genetic background that is 88% similar to NOD mice, develop diabetes. Immune tolerance can be broken in these diabetes-resistant mice expressing H-2g7 if the costimulatory molecule B7.1 is present on the islet beta cells. This does not occur if only single MHC class I components of the H-2g7 haplotype are present, such as Kd in BALB/c mice or Db in C57BL/6 mice, both of which develop only a low level of diabetes when B7.1 is expressed. The presence of I-Ag7 leads to the development of an autoimmune T-cell repertoire, and local costimulation of CD8 T-cells precipitates aggressive diabetes. This implies that a major role of the MHC class II molecules in diabetes is the development of an autoreactive T-cell repertoire.     

Age-related changes in hepatic glycogen metabolism in the genetically diabetic (db/db) mouse

Hepatic glycogen metabolism was investigated in genetically diabetic C57BL/KsJ-db/db mice during their development. Initially, the development of obesity, hyperglycemia, hyperinsulinemia, and hyperglucagonemia in these mice was examined, which illustrated that the diabetes progressed normally. Little difference in hepatic glycogen concentrations was observed, averaging approximately 50 and 60 mg/g liver in diabetic (db/db) and control heterozygote (db/+) mice, respectively. Glycogen synthase activity (total and a-form) was significantly elevated by 5 wk in the diabetic mice relative to controls and reached maximum levels (two-fold higher than controls) around 8-9 wk. This activity then slowly declined during the rest of the 15-wk period examined. Both phosphorylase a and total phosphorylase activities were also elevated by 5 wk, reaching levels twofold higher than controls. These activities did not decline at the end of this 15-wk period, but instead continued to slowly increase. Glycogen synthase a activity showed a positive correlation (r = 0.54, N = 144) with circulating levels of insulin, and a similar correlation was seen for phosphorylase a activity and plasma glucagon levels (r = 0.64, N = 72). Protein kinase and phosphoprotein phosphatase activities were also measured, but no differences were detected between diabetic and control mice. This longitudinal study clarifies some of the changes in hepatic glycogen metabolism that occur during the progression of diabetes in the db/db mouse and indicates a role for circulating insulin and glucagon concentrations on the steady-state activities of glycogen synthase and phosphorylase, respectively.     

Alteration of islet cell populations in spontaneously diabetic mice.

Endocrine-cell populations in the islets of Langerhans of mutant mice with a severe hypoinsulinemic diabetes (ob/ob or db/db on the C57BL/KsJ background) or with a mild hyperinsulinemic diabetes (ob/ob or db/db on the C57BL/6J background) were studied quantitatively by immunofluorescence and morphometry. In severely diabetic mice, islets presented a reduced proportion of insulin containing cells but increased glucagon-, somatostatin-, and pancreatic polypeptide (PP)-containing cells, as compared with islets of control (+/+) mice. An inverse change was observed in islets of mildly diabetic mice: islets were hypertrophic and composed mostly of insulin-containing cells, with decreased proportions of glucagon-, somatostatin-, and PP-containing cells. In both types of diabetic syndromes, the changes in cell populations induced a qualitative alteration of cellular interrelationships in the affected islets.     

Localization of Idd11 is not associated with thymus and nkt cell abnormalities in NOD mice

Congenic mouse strains provide a unique resource for genetic dissection and biological characterization of chromosomal regions associated with diabetes progression in the nonobese diabetic (NOD) mouse. Idd11, a mouse diabetes susceptibility locus, was previously localized to a region on chromosome 4. Comparison of a panel of subcongenic NOD mouse strains with different intervals derived from the nondiabetic C57BL/6 (B6) strain now maps Idd11 to an approximately 8-Mb interval. B6-derived intervals protected congenic NOD mice from diabetes onset, even though lymphocytic infiltration of pancreatic islets was similar to that found in NOD mice. In addition, neither thymic structural irregularities nor NKT cell deficiencies were ameliorated in diabetes-resistant congenic NOD mice, indicating that Idd11 does not contribute to these abnormalities, which do not need to be corrected to prevent disease.     

Improved insulin sensitivity is associated with restricted intake of dietary glycoxidation products in the db/db mouse

Advanced glycation end products (AGEs), known promoters of diabetic complications, form abundantly in heated foods and are ingested in bioreactive forms. To test whether dietary AGEs play a role in the progression of insulin resistance, C57/BL/KsJ db/db mice were randomly placed for 20 weeks on a diet with either a low AGE content (LAD) or a 3.4-fold higher content of AGE (high AGE diet [HAD]), including (epsilon)N-carboxymethyllysine (CML) and methylglyoxal (MG). LAD-fed mice showed lower fasting plasma insulin levels throughout the study (P = 0.01). Body weight was reduced by approximately 13% compared with HAD-fed mice (P = 0.04) despite equal food intake. LAD-fed mice exhibited significantly improved responses to both glucose (at 40 min, P = 0.003) and insulin (at 60 min, P = 0.007) tolerance tests, which correlated with a twofold higher glucose uptake by adipose tissue (P = 0.02). Compared with the severe hypertrophy and morphological disorganization of islets from HAD-fed mice, LAD-fed mice presented a better-preserved structure of the islets. LAD-fed mice demonstrated significantly increased plasma HDL concentrations (P < 0.0001). Consistent with these observations, LAD-fed mice exhibited twofold lower serum CML and MG concentrations compared with HAD-fed mice (P = 0.02). These results demonstrate that reduced AGE intake leads to lower levels of circulating AGE and to improved insulin sensitivity in db/db mice.