Diabetes Induced Changes in Podocyte Morphology and Gene Expression Evaluated Using GFP Transgenic Podocytes.

The effect of diabetes in vivo has not been examined on isolated podocytes. To achieve this, GFP was expressed constitutively in podocytes of PGFP transgenic mice which were bred to OVE mice to produce diabetic OVE-GFP mice. Viewing GFP fluorescence, foot processes of OVE-GFP podocytes were visually and measurably effaced, which did not occur with less severe STZ diabetes. Over 300,000 podocytes were purified from each PGFP mouse but only 49,000 podocytes per diabetic OVE-GFP mouse. The low yield from OVE-GFP mice appeared to be due to more fragile state of most OVE-GFP diabetic podocytes which did not survive the isolation process. Diabetic podocytes that were isolated had high levels of the lipid peroxidation product 4-HNE and they were more sensitive to death due to oxidative stress. Gene array analysis of OVE-GFP podocytes showed strong diabetes induction of genes involved in inflammation. Four CXC chemokines were induced at least 3-fold and the chemokine CXCL1 was shown for the first time to be specifically induced in podocytes by OVE, dbdb and STZ diabetes.

Inflammatory gene expression in OVE26 diabetic kidney during the development of nephropathy.

AIM: To define renal gene expression during the development of severe albuminuria in OVE26 diabetic mice. METHODS: Kidney microarray analysis was performed at 2, 4 and 8 months. Data were validated by RT-PCR, in situ hybridization and immunohistochemistry. RESULTS: Gene expression differences between control and diabetic mice increased 10-fold from 2 to 8 months. This change was most obvious for inflammatory genes. Three inflammatory genes, complement C3, VCAM1 and CD44 were upregulated more than 4-fold. Inflammatory gene expression correlated with albuminuria and C3 and CD44 increased in tubules that accumulated albumin. VCAM1 was induced in different tubules that were neither dilated nor accumulated albumin. Six of 8 genes previously reported to be markers of human advanced diabetic nephropathy and the NF-κB_IFN_x promoter module were elevated in the oldest diabetic mice. Vitamin D inhibits diabetic renal inflammation. Vitamin D and mRNA for vitamin D synthetic enzyme CYP2B1 were elevated in kidneys of young OVE26 mice. CONCLUSIONS: OVE26 mice induce inflammatory genes consistent with advanced renal disease, associated with severe albuminuria and to a greater extent than reported in other diabetic models. They provide an excellent model of diabetic nephropathy to assess the effect of induction of inflammatory proteins.

Diabetic albuminuria is due to a small fraction of nephrons distinguished by albumin-stained tubules and glomerular adhesions.

OVE26 diabetic mice develop severe albuminuria. Immunohistochemical analysis revealed a pattern of intense albumin staining in a small subset of OVE26 tubules. Immunostaining was strikingly heterogeneous; some tubules stained intensely for albumin, but most tubules had weak or no staining. Serial sectioning showed that staining patterns were distinctive for each nephron. Electron microscopy revealed that albumin accumulated in villi and at the base of the brush border. Tubule cell injury, as shown by loss of villi, tubule dilation, and cellular protrusions into the tubule lumen, was unambiguously associated with albumin staining. Examination of albumin staining of proteinuric human kidneys also showed a heterogeneous pattern of staining. Analysis of OVE26 serial sections indicated that all glomeruli connected to albumin-positive tubules were identified by albumin-stained lesions in the tuft that adhered to Bowman's capsule, implicating this as a critical feature of heavy albumin leakage. These results indicate that albumin accumulation provides a marker of damaged nephrons, and confirm that albumin leakage produces significant tubular damage. This study shows that that formation of sclerotic glomerular adhesions is a critical step leading to severe albuminuria.

Podocyte-specific overexpression of the antioxidant metallothionein reduces diabetic nephropathy.

Podocytes are critical components of the selective filtration barrier of the glomerulus and are susceptible to oxidative damage. For investigation of the role of oxidative stress and podocyte damage in diabetic nephropathy, transgenic mice that overexpress the antioxidant protein metallothionein (MT) specifically in podocytes (Nmt mice) were produced. MT expression was increased six- and 18-fold in glomeruli of two independent lines of Nmt mice, and podocyte-specific overexpression was confirmed. Glomerular morphology and urinary albumin excretion were normal in Nmt mice. OVE26 transgenic mice, a previously reported model of diabetic nephropathy, were crossed with Nmt mice to determine whether an antioxidant transgene targeted to podocytes could reduce diabetic nephropathy. Double-transgenic OVE26Nmt mice developed diabetes similar to OVE26 mice, but MT overexpression reduced podocyte damage, indicated by more podocytes, less glomerular cell death, and higher density of podocyte foot processes. In addition, expansion of glomerular and mesangial volume were significantly less in OVE26Nmt mice compared with OVE26 mice. Four-month-old OVE26Nmt mice had a 70 to 90% reduction in 24-h albumin excretion, but this protection does not seem to be permanent. These results provide evidence for the role of oxidative damage to the podocyte in diabetic mice and show that protection of the podocyte can reduce or delay primary features of diabetic nephropathy.

Causes and characteristics of diabetic cardiomyopathy.

Type 1 and type 2 diabetic patients are at increased risk of cardiomyopathy and heart failure is a major cause of death for these patients. Cardiomyopathy in diabetes is associated with a cluster of features including decreased diastolic compliance, interstitial fibrosis and myocyte hypertrophy. The mechanisms leading to diabetic cardiomyopathy remain uncertain. Diabetes is associated with most known risk factors for cardiac failure seen in the overall population, including obesity, dyslipidemia, thrombosis, infarction, hypertension, activation of multiple hormone and cytokine systems, autonomic neuropathy, endothelial dysfunction and coronary artery disease. In light of these common contributing pathologies it remains uncertain whether diabetic cardiomyopathy is a distinct disease. It is also uncertain which factors are most important to the overall incidence of heart failure in diabetic patients. This review focuses on factors that can have direct effects on diabetic cardiomyocytes: hyperglycemia, altered fuel use, and changes in the activity of insulin and angiotensin. Particular attention is given to the changes these factors can have on cardiac mitochondria and the role of reactive oxygen species in mediating injury to cardiomyocytes.

Cardiomyocyte dysfunction in models of type 1 and type 2 diabetes.

Cardiomyopathy is a major cause of mortality for both type 1 and 2 diabetic patients. However, experimental analysis of diabetic cardiomyopathy has focused on type 1 diabetes and there are few reports on cardiomyocyte dysfunction in the widely used type 2 diabetic model, db/db. In the current study, we assessed function in isolated ventricular myocytes from type 1 diabetic OVE26 mice and from type 2 diabetic db/db mice. When compared with their respective control strains, both diabetic models showed significant impairment in contractility, as assessed by percent peak shortening, maximal rate of contraction, and maximal rate of relaxation. The calcium decay rate was also significantly reduced in both types of diabetes, but the decrement was much greater in OVE26 myocytes, approx 50% vs only 20% in db/db myocytes. To understand the basis for slow calcium decay in diabetic myocytes and to understand the molecular basis for the quantitative difference between calcium decay in OVE26 and db/db myocytes, we measured cardiac content of the SERCA2a calcium pump. SERCA2a was significantly decreased in OVE26 diabetic myocytes but not reduced at all in db/db myocytes. The reduction of SERCA2a in OVE26 myocytes was completely prevented by overexpression of the antioxidant protein metallothionein, confirming that oxidative stress is an important component of diabetic cardiomyopathy. The current results demonstrate that though contractility is impaired in individual myocytes of db/db hearts and deficits are similar to what is seen in a severe model of type 1 diabetes, impairment in calcium reuptake is less severe, probably as a result of maintenance of normal levels of SERCA2a.

Development of late-stage diabetic nephropathy in OVE26 diabetic mice.

OVE26 mice are a transgenic model of severe early-onset type 1 diabetes. These mice develop diabetes within the first weeks of life and can survive well over a year with no insulin treatment, and they maintain near normal body weight. To determine whether OVE26 mice provide a valuable model of chronic diabetic nephropathy (DN), OVE26 diabetic mice were compared with their nondiabetic littermates for functional and structural characteristics of DN. OVE26 mice exhibited pronounced polyuria and significant albuminuria by 2 months of age (305 microg/24 h in OVE26 vs. 20 microg/24 h in controls). Albumin excretion rate increased progressively with age and exceeded 15,000 microg/24 h at 9 months of age. The profound loss of albumin led to hypoalbuminemia in some diabetic animals. Albuminuria coincided with an elevation in blood pressure as measured by tail cuff. The glomerular filtration rate (GFR) in OVE26 mice measured using fluorescein isothiocynate inulin clearance demonstrated that GFR increased significantly from 2 to 3 months of age and then decreased significantly from 5 to 9 months. GFR in 9-month-old diabetic mice was significantly lower than that of 9-month-old control mice. The decline in GFR coincided with a significant increase in renal vascular resistance. Structural studies showed an almost twofold increase in kidney weight between 2 and 5 months. Diabetic mice also showed progressively enlarged glomeruli and expanded mesangium with diffuse and nodular expansion of mesangial matrix. Tubulointerstitial fibrosis was also observed in these mice. Glomerular basement membrane was thickened in OVE26 mice. In summary, OVE26 mice demonstrate that most of the characteristics of human DN can be produced by chronic hyperglycemia in a murine model. This model will be useful for improved understanding and treatment of DN.

Elevated hexokinase increases cardiac glycolysis in transgenic mice.

OBJECTIVE: Cardiac glucose metabolism is critical to normal and pathological function. The significance of the first committed metabolic step, glucose phosphorylation, has not been established. In this study a new transgenic model was developed in order to investigate the importance of this enzymatic step in cardiac glycolysis. METHODS: Transgenic mice were produced that overexpress yeast hexokinase B under the control of a cardiac specific promoter. Yeast hexokinase B is a high affinity enzyme that is not inhibited by glucose-6-phosphate. Hexokinase enzyme activity was measured by a modified radiometric procedure. Cardiac glucose metabolism and contractility were measured in the Langendorff mode. Cardiac glycogen content and glucose-6-phosphate independent glycogen synthase activity were also determined. RESULTS: In transgenic hearts hexokinase activity was significantly elevated and increased glucose metabolism, particularly in the presence of insulin and during cardiac reperfusion. However during ischemic perfusion the effect of the transgene on glycolysis was minimal. Under all conditions tested there was no effect of hexokinase on contractility. Glycogen content of transgenic hearts was elevated 2-fold and glucose-6-phosphate independent glycogen synthase was also increased. CONCLUSION: These results demonstrate that glucose phosphorylation is a key step in determining cardiac glucose metabolism under oxidative conditions.