1a_Caveolin-1 (CAV-1) is the main structural component of caveolae, acting as a modulator of signal transduction. CAV-1 might be involved in the pathophysiology of microvascular complications in Type 1 diabetes (DM). We sought to determine whether fractionation on sucrose gradient (SF), a method routinely utilized for isolation of caveolar fractions in homogenous cell lines, is applicable for CAV-1-related studies in tissues with multiple cell types, such as the normal rat kidney cortex (C). Using this method, we also determined whether streptozotocin- induced DM in rats (4-week duration) leads to changes in renal subcellular targeting of CAV-1, and evaluated the effects of tight metabolic control (insulin, 12 IU /day) and angiotensin receptor blocker, losartan (4 weeks, 20 mg/kg/day). Immunoblotting of individual fractions obtained from C revealed CAV-1 expression in fractions 4-6 that corresponded to light scattering band that typically forms after separating cellular fractions on SF. These fractions were considered to be caveolar fractions. In C, CAV-1 was also detectable in fracti ons 8-10. These and all other fractions except caveolar fractions were considered to be non-caveolar fractions. A ratio of caveolar/non-caveolar expression of CAV-1 (CNCR) was computed for each renal cortex allowing comparisons of CAV-1 subcellular distribution in C and DM rats, and effects of treatments., 2a_Using this approach, DM was characterized by marked increases in CNCR as compared to C (5.54±1.56 vs. 2.65±1.33, p<0. 05) that were reduced by treatment with insulin (0.78±0. 24, p<0.01 vs. DM) or losartan (0.84±0.06, p<0.01 vs. DM). In summary, analysis of CAV-1 following the SF of renal cortex detected similar distribution of the protein as in homogenous cell lines, DM-induced changes in CAV-1 targeting, and the effects of pharmacological treatments. This suggests applicability of SF in studies focusing on CAV-1 targeting in organs with various cell lines in vivo., H. Demová, R. Komers., and Obsahuje seznam literatury
Akt kinase regulates numerous cell functions including glucose metabolism, cell growth, survival, protein synthesis, and control of local hemodynamics. mTOR is one of down-stream effectors of Akt involved in the initiation of protein translation. However, renal Akt signaling in Type 1 diabetes (DM) in vivo, in particular under the conditions reflecting differences in metabolic control, has received less attention. Renal cortical activity and expression of Akt and mTOR (kinase assay, western blotting) were determined in streptozotocin-diabetic rats (D) with different levels of glycemic control (blood glucose 22.0± 1.0, 13.4±1.5, 8.1±0.4 mmol/l, p<0.05 between the groups), achieved by varying insulin treatment (0,4 and 12 IU/day), and in control rats with (C4) or without (C) chronic insulin administration. Renal Akt activity was reduced in D rats without insulin treatment and severe hyperglycemia (D-0, -62 %, p<0.01 vs. C), partially restored in moderately hypergly cemic rats (D-4, -30 %, p<0.05 vs. C), and normalized in D rats with intensive insulin and tight metabolic control (D-12). Expression of active mTOR paralleled Akt activity in D-0 (-51 %, p<0.01 vs. C), but not in D-4 and D- 12 that demonstrated increases in active mTOR (+55 %, +80 % resp., p<0.05) as compared to C. Moreover, insulin activated renal Akt (+82 %, p<0.01), but not mTOR in C4. In conclusion, glycemic control and intensity of insulin treatment are important modulators of renal Akt and mTOR activity in diabetes. While Akt activity is reversible by tight metabolic control, combination of hyperglycemia and insulin treatment resulted in enhancement of mTOR activity. In addition to Akt, other signaling pathways likely contribute to regulation of renal mTOR activity in diabetes., J. Ždychová, J. Veselá, L. Kazdová, R. Komers., and Obsahuje bibliografii a bibliografické odkazy
The aim of this study was to determine the effects of insulin infusion on oxidative stress induced by acute changes in glycemia in non-stressed hereditary hypertriglyceridemic rats (hHTG) and Wistar (control) rats. Rats were treated with glucose and either insulin or normal saline infusion for 3 hours followed by 90 min of hyperglycemic (12 mmol/l) and 90 min of euglycemic (6 mmol/l) clamp. Levels of total glutathione (GSH), oxidized glutathione (GSSG) and total antioxidant capacity (AOC) were determined to assess oxidative stress. In steady states of each clamp, glucose infusion rate (GIR) was calculated for evaluation of insulin sensitivity. GIR (mg.kg-1.min-1) was significantly lower in hHTG in comparison with Wistar rats; 25.46 (23.41 - 28.45) vs. 36.30 (27.49 - 50.42) on glycemia 6 mmol/l and 57.18 (50.78 - 60.63) vs. 68.00 (63.61 - 85.92) on glycemia 12 mmol/l. GSH/GSSG ratios were significantly higher in hHTG rats at basal conditions. Further results showed that, unlike in Wistar rats, insulin infusion significantly increases GSH/GSSG ratios in hHTG rats: 10.02 (9.90 - 11.42) vs. 6.01 (5.83 - 6.43) on glycemia 6 mmol/l and 7.42 (7.15 - 7.89) vs. 6.16 (5.74 - 7.05) on glycemia 12 mmol/l. Insulin infusion thus positively influences GSH/GSSG ratio and that way reduces intracellular oxidative stress in insulin-resistant animals., M. Žourek, P. Kyselová, J. Mudra, M. Krčma, Z. Jankovec, S. Lacigová, J. Víšek, Z. Rušavý., and Obsahuje bibliografii a bibliografické odkazy
The hyperinsulinemic euglycemic clamp (HEC) combined with indirect calorimetry (IC) is used for estimation of insulin-stimulated substrate utilization. Calculations are based on urinary urea nitrogen excretion (UE), which is influenced by correct urine collection. The aims of our study were to improve the timing of urine collection during the clamp and to test the effect of insulin on UE in patients with type 1 diabetes (DM1; n=11) and healthy subjects (C; n=11). Urine samples were collected (a) over 24 h divided into 3-h periods and (b) before and during two-step clamp (1 and 10 mIU.kg-1.min-1; period 1 and period 2) combined with IC. The UE during the clamp was corrected for changes in urea pool size (UEc). There were no significant differences in 24-h UE between C and DM1 and no circadian variation in UE in either group. During the clamp, serum urea decreased significantly in both groups (p<0.01). Therefore, UEc was significantly lower as compared to UE not adjusted for changes in urea pool size both in C (p<0.001) and DM1 (p<0.001). While UE did not change during the clamp, UEc decreased significantly in both groups (p<0.01). UEc during the clamp was significantly higher in DM1 compared to C both in period 1 (p<0.05) and period 2 (p<0.01). The UE over 24 h and UEc during the clamp were statistically different in both C and DM1. We conclude that urine collection performed during the clamp with UE adjusted for changes in urea pool size is the most suitable technique for measuring substrate utilization during the clamp both in DM1 and C. Urine collections during the clamp cannot be replaced either by 24-h sampling (periods I-VII) or by a single 24-h urine collection. Attenuated insulin-induced decrease in UEc in DM1 implicates the impaired insulin effect on proteolysis. and Obsahuje bibliografii a bibliografické odkazy