A model for diabetic nephropathy: advantages of the inducible cAMP early repressor transgenic mouse over the streptozotocin-induced diabetic mouse

We have previously found progressive diabetic nephropathy in inducible cAMP early repressor (ICER Igamma) transgenic (Tg) mice. The ICER Igamma Tg mouse is an interesting model of sustained hyperglycemia due to its low production of insulin and insulin-producing beta cells. Here in a longitudinal study we further analyzed diabetic nephropathy and structural and functional alterations in other organs, comparing our model with streptozotocin (STZ)-diabetic model mice. The high-dose STZ-diabetic model showed marked variation in blood glucose levels and severe toxicity of STZ in the liver and kidney. The low-dose STZ-diabetic model showed less toxicity, but the survival rate was very low. STZ-diabetic mice had much more variation of glomerular hypertrophy and sclerosis. Furthermore, non-specific toxicity of STZ or insulin injections to maintain optimal blood glucose levels might have another effect upon the diabetic renal changes. In contrast, ICER Igamma Tg mice exhibited a stable and progressive phenotype of diabetic kidney disease solely due to chronic hyperglycemia without other modulating factors. Thus, ICER Igamma Tg mouse has advantages for examining diabetic renal disease, and offers unique and very different perspectives compared to STZ model.     

Transgenic Mice Over-expressing Dicarbonyl/L-xylulose Reductase Gene Crossed with KK-A(y) Diabetic Model Mice: An Animal Model for the Metabolism of Renal Carbonyl Compounds.

Carbonyl compounds in the blood stream tend to accumulate in the kidney of diabetic or end stage renal failure subjects. Previously we isolated cDNA encoding dicarbonyl/L-xylulose reductase (DCXR) from a mouse kidney cDNA library. In the present study, transgenic (Tg) mice were generated to study the functional role of DCXR in the kidney. With a six-fold increase in the DCXR protein expression levels in the kidney, the homozygous Tg mice did not show any notable histological abnormalities. While the elevated DCXR expression was observed throughout the body, its renal distribution was similar to that of the endogenous DCXR protein, namely, the major expression site was the collecting tubules, along with moderate expression in other tubules and Bowman's capsule, but it was absent from the interstitial area and glomeruli. The Tg mice were crossed with KK-A(y) diabetic model mice to examine the role of DCXR in the progression of diabetic nephropathy. The resulting progeny, Tg/A(y), showed lighter body weight, lower levels of blood glucose, water uptake and creatinine clearance compared to their +/A(y) littermates. Although remarkable pathological differences were not observed at the microscopic level and in the renal accumulation of carboxymethyl lysine, the data imply that DCXR might function in the metabolism of glucose or carbonyl compounds, and play a protective role in a kidney which is under hyperglycemic pressure. The DCXR Tg mice and the Tg x KK-A(y) hybrid mice, therefore, serve as specific models for carbonyl metabolism in the kidney with diabetic background.     

Altered expression of neuronal nitric oxide synthase in the duodenum longitudinal muscle-myenteric plexus of obesity induced diabetes mouse: implications on enteric neurodegeneration

Type 2 diabetes caused by obesity shows autonomic neuropathy. Molecular mechanism involved in enteric neurodegeneration is not clear. Neuronal nitric oxide synthase (nNOS) is one of the important agents involved in gastrointestinal function. Therefore, expression of nNOS in the duodenum LM-MP of type 2 diabetes model mouse was studied. Real time RT-PCR analysis showed reduction in nNOS expression in male diabetic LM-MP compared to male control. In contrast, female diabetic LM-MP had high level of nNOS mRNA compared to female control. Western blot determination of LM-MP showed reduction in nNOS protein in male diabetic LM-MP and high level of nNOS in female diabetic LM-MP compared to their respective controls. Expression of nNOS observed by Western blot was further confirmed by nNOS immunostaining of the mouse duodenum. TUNEL staining of mouse duodenum showed apoptosis in male diabetic enteric neurons. These studies suggest that nNOS expression in LM-MP varies with gender during early stage of type 2 diabetes. In addition, reduced expression of nNOS is likely to contribute to apoptosis seen in the enteric neurons of male type 2 diabetic mice.     

The offspring of the female diabetic "nonobese diabetic" (NOD) mouse are large for gestational age and have elevated pancreatic insulin content: a new animal model of human diabetic pregnancy

Pregnancy in diabetic mothers is associated with intrauterine death, perinatal mortality, and birth weight greater than that of infants born of normal mothers. The use of rodents made diabetic by alloxan or streptozotocin as an animal model for human diabetic pregnancy has been controversial because of the severity of the diabetes as well as the direct effect of diabetogenic drugs on the developing organism. Among our female NOD (nonobese diabetic) mice, insulin-dependent diabetes occurs spontaneously in 9% by 12 weeks and in 80% by 29 weeks of age. Offspring born within 21 days of conception to mildly hyperglycemic NOD pregnant mice between 26 and 52 weeks of age, and prior to the onset of maternal ketonuria are macrosomic with an average of 31% increase in body weight and 44% increase in kidney weight, in comparison to controls. Besides organomegaly, the macrosomic offspring have significantly higher pancreatic insulin content which was elevated 80% when compared with that of controls, and litter sizes are significantly 50% smaller. These results suggest that the mildly hyperglycemic pregnant NOD mouse represents a promising model for the study of pregnancy complicated by diabetes.     

Diabetes induces changes of catecholamines in primary mesangial cells

Diabetes mellitus is a frequent cause of kidney function damage with diabetic nephropathy being predominantly related to glomerular dysfunction. Diabetes is capable of interfering with distinct hormonal systems, as well as catecholamine metabolism. Since mesangial cells, the major constituent of renal glomerulus, constitute a potential site for catecholamine production, the present study was carried out to investigate alterations in catecholamine metabolism in cultured mesangial cells from the nonobese diabetic mouse, a well-established model for type I diabetes. We evaluated mesangial cells from normoglycemic and hyperglycemic nonobese diabetic mice, as well as cells from normoglycemic Swiss mice as control. Mesangial cells from normoglycemic mice presented similar profiles concerning all determinations. However, cells isolated from hyperglycemic animals presented increased dopamine and norepinephrine production/secretion. Among the studied mechanisms, we observed an upregulation of tyrosine hydroxylase expression accompanied by increased tetrahydrobiopterin consumption, the tyrosine hydroxylase enzymatic cofactor. However, this increase in synthetic pathways was followed by decreased monoamine oxidase activity, which corresponds to the major metabolic pathway of catecholamines in mesangial cells. In addition, whole kidney homogenates from diabetic animals also presented increased dopamine and norepinephrine levels when compared to normoglycemic animals. Thus, our results suggest that diabetes alters catecholamine production by interfering with both synthesizing and degrading enzymes, suggesting a possible role of catecholamine in the pathogenesis of acute and chronic renal complications of diabetes mellitus.     

Peripheral insulin insensitivity in the hyperglycemic athymic nude mouse: similarity to noninsulin-dependent diabetes mellitus

Previous studies in the homozygous athymic nude mouse (USC colony) have indicated a diabetic state characterized by spontaneous hyperglycemia, abnormal glucose tolerance, and normal or relatively decreased plasma insulin levels. Pancreatic islet cell population assessed by morphometric and immunohistochemical studies demonstrated normal insulin-secreting cells in the hyperglycemic nude mouse. To further elucidate the pathogenesis of the hyperglycemic state in the athymic nude mouse, we have studied the effects of insulin on the transport of glucose in skeletal muscle by measuring basal and insulin-stimulated uptake of a nonmetabolizable glucose analogue, 2-deoxy-D-glucose by using the perfused hindquarter preparation. Although basal 2-deoxy-D-glucose uptake by peripheral skeletal muscle was similar in the hyperglycemic and control mice, the insulin-stimulated uptake of 2-deoxy-D-glucose was significantly decreased in the athymic nude mouse at both 0.1 milliunits/ml and supraphysiologic concentrations of insulin (1 milliunit/ml) when compared with control mice (P less than 0.05 and P less than 0.001, respectively). This form of peripheral insulin insensitivity with normal pancreatic beta cell reserve, in addition to the lean body mass of the diabetic animal, mimics in part the peripheral insulin insensitivity seen in non-insulin-dependent diabetes mellitus.     

Type I diabetic bone phenotype is location but not gender dependent

Bone is highly dynamic and responsive. Bone location, bone type and gender can influence bone responses (positive, negative or none) and magnitude. Type I diabetes induces bone loss and increased marrow adiposity in the tibia. We tested if this response exhibits gender and location dependency by examining femur, vertebrae and calvaria of male and female, control and diabetic BALB/c mice. Non-diabetic male mice exhibited larger body, muscle, and fat mass, and increased femur BMD compared to female mice, while vertebrae and calvarial bone parameters did not exhibit gender differences. Streptozotocin-induced diabetes caused a reduction in BMD at all sites examined irrespective of gender. Increased marrow adiposity was evident in diabetic femurs and calvaria (endochondrial and intramembranous formed bones, respectively), but not in vertebrae. Leptin-deficient mice also exhibit location dependent bone responses and we found that serum leptin levels were significantly lower in diabetic compared to control mice. However, in contrast to leptin-deficient mice, the vertebrae of T1-diabetic mice exhibit bone loss, not gain. Taken together, our findings indicate that TI-diabetic bone loss in mice is not gender, bone location or bone type dependent, while increased marrow adiposity is location dependent.     

Diabetes mellitus in mice induced by multiple subdiabetogenic doses of streptozotocin: age and sex dependence

In order to investigate whether age and sex have an influence on induction and development of diabetes, male and female C57Bl/KsJ mice of different ages were treated with subdiabetogenic injections of streptozotocin for five consecutive days. After a long period of observation all treated animals became diabetic. Male mice showed higher plasma glucose values than female animals suggesting a sex dependence. In the first phase of diabetes development the hyperglycemic response was dependent on the age of the mice. Animals treated during puberty, both male and female developed a more rapid onset of hyperglycemia and a more severe diabetes than the other age groups. The increased plasma glucose levels were accompanied in mice treated after and during puberty by an inflammatory lesion of the endocrine pancreas.     

Glucocorticoids in the nonobese diabetic (NOD) mouse: basal serum levels, effect of endocrine manipulation and immobilization stress.

The NOD mouse is a recognized model for studying immunologically mediated insulin-dependent diabetes mellitus (IDDM). In most colonies, the disease appears with a greater preponderance in females than in males and castration alters the expression of the disease. The prevalence of diabetes may also vary depending upon environmental factors such as stress. Therefore, we measured in the NOD mouse serum glucocorticoid concentrations in basal and stress conditions. We observed in NOD as well as in C57BL/6 mice, taken as controls, a circadian rhythm of corticosterone, with females having higher values than males. After a single restraint stress, female and male NOD mice exhibit a comparable response, whereas after repeated stress, males respond significantly less than females, suggesting an adaptation phenomenon. In contrast, there is no difference in the pattern of corticosterone response of C57BL/6 females and males to both types of stress, but females always respond better than males. Moreover, whatever the stress considered, NOD mice generally exhibit a higher corticosterone response than C57BL/6 mice. The sexual dimorphism in diabetes expression in NOD mice may be related to the levels of corticosterone, a hyperglycemic hormone, in both basal and stress conditions. However, the understanding of corticosteroid effects in this model of type I IDDM is rather complex given their well known anti-inflammatory and immunosuppressive effects in other models of autoimmune diseases.     

Suppressive effects of continuous low-dose-rate γ irradiation on diabetic nephropathy in type II diabetes mellitus model mice

It has been proposed that the development of diabetic nephropathy is caused in large part by oxidative stress. We previously showed that continuous exposure of mice to low-dose-rate γ radiation enhances antioxidant activity. Here, we studied the ameliorative effect of continuous whole-body irradiation with low-dose-rate γ rays on diabetic nephropathy. Ten-week-old female db/db mice, an experimental model for type II diabetes, were irradiated with low-dose-rate γ rays from 10?weeks of age throughout their lives. Nephropathy was studied by histological observation and biochemical analysis of serum and urine. Antioxidant activities in kidneys were determined biochemically. Continuous low-dose-rate γ radiation significantly increases life span in db/db mice. Three of 24 irradiated mice were free of glucosuria after 80?weeks of irradiation. Histological studies of kidney suggest that low-dose irradiation increases the number of normal capillaries in glomeruli. Antioxidant activities of superoxide dismutase, catalase and glutathione are significantly increased in kidneys of irradiated db/db mice. Continuous low-dose-rate γ irradiation ameliorates diabetic nephropathy and increases life span in db/db mice through the activation of renal antioxidants. These findings have noteworthy implications for radiation risk estimation of non-cancer diseases as well as for the clinical application of low-dose-rate γ radiation for diabetes treatment.     

Developing a new model for non-insulin dependent diabetes mellitus (NIDDM) by using the Philippine wild mouse, Mus musculus castaneus.

The Philippine wild-caught castaneus mouse (Mus musculus castaneus) and laboratory mouse (C57BL/6J: B6) were used to develop a new non-insulin dependent diabetes mellitus (NIDDM) model. Offspring from the cross between a wild male and B6 female were backcrossed to the sire. One male which exhibited highest fasting hyperglycemia (190 mg/dl) among eighty-seven backcross offspring was selected at 10 weeks of age, and crossed with a B6 female to comprise the fundamental stock (F0). Thereafter, full-sib mating was performed to develop a new inbred strain named CBD (Castaneus-B6 diabetic) mouse. Mice with relatively higher fasting hyperglycemia among F0 and F1 generations were selected for breeding. From the F2 generation, mice were defined as diabetic when blood glucose levels exceeded 200 mg/dl at 120 min in intraperitoneal glucose tolerance test (IPGTT) at 10 weeks of age, and have been selectively bred. The incidence of diabetic males from the F3-F6 generation fluctuated 45-75% at 10 weeks of age and 59-72% at 20 weeks of age. Diabetic males had about two-fold higher fasting glucose and insulin levels than B6 males. Glucose-stimulated insulin secretion was impaired in diabetic CBD mice compared to B6 males at 20 weeks. Moreover, diabetic mice had slight obesity compared to B6 mice. These facts indicated that diabetic features of CBD mice resemble NIDDM in humans. The CBD strain, characterized by high incidence and early onset of diabetes with mild obesity would be of value as a new NIDDM model. The method, utilizing wild castaneus mouse of different origin from laboratory mice, maybe useful in the development of other animal models.     

Renal function and glucose transport in male and female mice with diet-induced type II diabetes mellitus

The aim of this study was to measure cardiovascular and renal function, including the renal transport capacity for glucose, in male and female C57BL/6J mice with diet-induced Type II diabetes mellitus. Typical of Type II diabetes, mice fed a high-fat, high-simple carbohydrate diet for 3 months were obese (45-65 g), hyperglycemic (138-259 mg%), and hyperinsulinemic (1.8-15.06 ng/ml); significant gender differences were observed in all cases. Based on systolic pressure measurements in conscious mice and arterial blood pressure measurements in anesthetized mice, no diet-induced hypertension was observed in either male or female mice. Urine flow rate, sodium, potassium, osmolar, and protein excretion rates were significantly increased (P < 0.05) in male mice fed the high-fat, high-simple carbohydrate diet compared with female mice fed the same diet. However, no differences in the excretion variables existed between male and female mice fed the control diet. The glomerular filtration rate (ml min-1 g kw-1), determined by FITC-inulin, in male and female mice fed the control diet (0.87 +/- 0.01 and 0.90 +/- 0.1, respectively) and high-fat, high-simple carbohydrate diet (0.96 +/- 0.1 and 0.93 +/- 0.2, respectively) was not different between the groups. These hyperglycemic mice were also not glucosuric. Infusions of progressive amounts of glucose in male mice fed either diet for 3 or 6 months demonstrated that the renal threshold for glucose was 400 mg% for all these mice, well above the fasting plasma glucose concentrations observed in this study. Thus, C57BL/6J mice were valuable tools for studying diet-induced obesity, hyperglycemia, and hyperinsulinemia; however, no hypertension or kidney dysfunction was apparent within the time frame of the current study.     

Effects of hyperglycemia and aging on nuclear sirtuins and DNA damage of mouse hepatocytes

Hyperglycemia, like aging, induces chromatin remodeling in mouse hepatocytes in comparison to normoglycemia and younger age, respectively. Changes in glucose metabolism also affect the action and expression of sirtuins, promoting changes in chromatin conformation and dynamics. Here we investigate the abundance and activity of the nuclear sirtuins Sirt1, Sirt6, and Sirt7 in mouse hepatocytes in association with specific histone acetylation, DNA damage, and the activation of nucleolar organizing regions (NORs) in hyperglycemic nonobese diabetic (NOD) and old normoglycemic BALB/c mouse strains. Higher levels of Sirt1 and PGC-1α and increased expression of gluconeogenesis pathway genes are found in the hyperglycemic NOD mice. Increased Sirt6 abundance is found in the hyperglycemic NOD mice, which might increase DNA damage repair. With aging, lower Sirt1 abundance and activity, increased acetylated histone modifications and Sirt7 levels, and NOR methylation are found. Thus, whereas in normal aging cell metabolism is reduced, in the diabetic mice a compensatory mechanism may elevate Sirt1 and Sirt6 levels, increasing gluconeogenesis and DNA repair from the oxidative damage caused by hyperglycemia. Therefore understanding the regulation of epigenetic factors in diabetes and aging is crucial for the development of new therapeutic approaches that could prevent diseases and improve quality of life.     

Diabetic peculiarity of the ALS-Ay and ALR-Ay strains

ALS and ALR mice were developed as mouse models of alloxan-induced diabetes. These strains do not show spontaneous onset of diabetes. When an obesity gene (Ay) was introduced to these two strains, severe diabetic conditions occurred spontaneously in the produced ALS-Ay and ALR-Ay strains. These strains were examined body weight gain, food consumption, water consumption, urinary sugar content, ketone body level and blood sugar level, and subjected to glucose tolerance test. As a result, in comparison with ALS mice, male ALS-Ay mice showed no obesity and very low tolerance to the glucose tolerance test performed 24 weeks after birth. The level of insulin secretion was 5.0 microU/ml or less, showing hardly any secretory reaction. On the other hand, female ALS-Ay mice were obese and showed no marked decrease in glucose tolerance. The level of insulin secretion was high, and the secretory reaction was strong. In ALR-Ay strain, both male and female mice were obese and showed diabetic conditions similar to those of ALS-Ay mice, though the severity tended to be lower. The characteristic features of diabetic conditions in these mice suggest that these strains, particularly ALS-Ay, may serve as useful new-type models of diabetes.     

Sex differences in progression of diabetic nephropathy in OVE26 type 1 diabetic mice

AimsOVE26 mice (FVB background), genetically overexpressing calmodulin in pancreatic beta cells, develop early onset type 1 diabetes, leading to progressive diabetic nephropathy (DN), with features of established human DN. The role of gender in characteristics of renal lesions has remained unexplored.MethodsMale and female OVE26 mice were compared to age and sex matched wild-type, nondiabetic FVB mice at ages of 4, 12, 24 and 36 weeks. Nephropathy was examined by measuring urine albumin-to-creatinine ratio, histopathology, expression of pathological markers and immunochemistry in the same cohort of mice.ResultsProgression of diabetic kidney disease was evident first in the OVE26 glomerulus, initially as mesangial matrix expansion at 4 weeks followed by loss of podocytes, glomerular volume expansion and severe albuminuria at 12 weeks. Tubule dilation and initiation of interstitial fibrosis did not become significant until 24 weeks. T-lymphocyte infiltration into the renal parenchyma appeared at 36 weeks. OVE26 female mice developed more advanced DN than male OVE26 mice, such as more severe albuminuria, greater podocyte loss, additional fibrosis and significantly more inflammatory cell infiltration. The female OVE26 mice had lowest level of plasma estradiol in all 36 weeks old mice, as well as renal estrogen receptors.ConclusionsThis demonstration of the role of gender, combined with the detailed characterization of DN progression illustrates the value of OVE26 mice for understanding gender effects on DN and provides the basis for researchers to better select the age and sex of OVE26 mice in future studies of type 1 DN.Research in contextWhat is already known about this subject?

• •OVE26 mice, genetically overexpressing calmodulin in pancreatic beta cells, develop early onset type 1 diabetes.
• •OVE26 mice are a widely used and valuable rodent model which develop severe, progressive diabetic nephropathy, with features of established human diabetic nephropathy.

What is the key question?

• •Does gender play a role in determining characteristics of renal lesions and severity of nephropathy?

What are the new findings?

• •Female OVE26 mice had more severe albuminuria, greater podocyte loss.
• •Female OVE26 mice had additional fibrosis and significantly more inflammatory cell infiltration.
• •Diabetes induced reductions in estradiol levels and renal estrogen receptors may be responsible for the female sensitization to DN in OVE26 mice.

How might this impact on clinical practice in the foreseeable future?

• •Our findings provide the basis for researchers to better select the age and sex of OVE26 mice in future studies of type 1 DN.

     

Molecular mechanisms for gender differences in susceptibility to T cell-mediated autoimmune diabetes in nonobese diabetic mice

Nonobese diabetic (NOD) mice spontaneously develop diabetes with a strong female prevalence; however, the mechanisms for this gender difference in susceptibility to T cell-mediated autoimmune diabetes are poorly understood. This investigation was initiated to find mechanisms by which sex hormones might affect the development of autoimmune diabetes in NOD mice. We examined the expression of IFN-gamma, a characteristic Th1 cytokine, and IL-4, a characteristic Th2 cytokine, in islet infiltrates of female and male NOD mice at various ages. We found that the most significant difference in cytokine production between sexes was during the early stages of insulitis at 4 wk of age. IFN-gamma was significantly higher in young females, whereas IL-4 was higher in young males. CD4(+) T cells isolated from lymph nodes of female mice and activated with anti-CD3 and anti-CD28 Abs produced more IFN-gamma, but less IL-4, as compared with males. Treatment of CD4(+) T cells with estrogen significantly increased, whereas testosterone treatment decreased the IL-12-induced production of IFN-gamma. We then examined whether the change in IL-12-induced IFN-gamma production by treatment with sex hormones was due to the regulation of STAT4 activation. We found that estrogen treatment increased the phosphorylation of STAT4 in IL-12-stimulated T cells. We conclude that the increased susceptibility of female NOD mice to the development of autoimmune diabetes could be due to the enhancement of the Th1 immune response through the increase of IL-12-induced STAT4 activation by estrogen.     

Bioluminescence Imaging Reveals Dynamics of Beta Cell Loss in the Non-Obese Diabetic (NOD) Mouse Model

We generated a mouse model (MIP-Luc-VU-NOD) that enables non-invasive bioluminescence imaging (BLI) of beta cell loss during the progression of autoimmune diabetes and determined the relationship between BLI and disease progression. MIP-Luc-VU-NOD mice displayed insulitis and a decline in bioluminescence with age which correlated with beta cell mass, plasma insulin, and pancreatic insulin content. Bioluminescence declined gradually in female MIP-Luc-VU-NOD mice, reaching less than 50% of the initial BLI at 10 weeks of age, whereas hyperglycemia did not ensue until mice were at least 16 weeks old. Mice that did not become diabetic maintained insulin secretion and had less of a decline in bioluminescence than mice that became diabetic. Bioluminescence measurements predicted a decline in beta cell mass prior to the onset of hyperglycemia and tracked beta cell loss. This model should be useful for investigating the fundamental processes underlying autoimmune diabetes and developing new therapies targeting beta cell protection and regeneration.     

Spirulina maxima prevents fatty liver formation in CD-1 male and female mice with experimental diabetes

The dietary administration of 5% Spirulina maxima (SM) during four weeks to diabetic mice, starting one week after a single dose of alloxan, 250 mg/Kg body weight, prevented fatty liver production in male and female animals. The main action of SM was on triacylglycerol levels in serum and liver. There was also a moderate hypoglycemia in male mice. The thiobarbituric acid reactive substances also decreased in serum and liver after SM administration. There was also a decrease in the percentage of HDL in diabetic mice that was reverted by the SM administration. The sum of LDL + VLDL percentages was also partially normalized in diabetic animals by the SM administration. An additional observation was the lower incidence of adherences between the liver and the intestine loops in the diabetic mice treated with SM compared with diabetic mice without SM. Male and female mice showed differences to diabetes susceptibility and response to SM, the female being more resistant to diabetes induction by alloxan and more responsive to the beneficial effects of SM. It is worth future work of SM on humans looking for better quality of life and longer survival of diabetic patients.