Rottlerin activates AMPK possibly through LKB1 in vascular cells and tissues.

AMP-activated protein kinase (AMPK) is a cellular energy sensor involved in multiple cell signaling pathways that has become an attractive therapeutic target for vascular diseases. It is not clear whether rottlerin, an inhibitor of protein kinase Cdelta, activates AMPK in vascular cells and tissues. In the present study, we have examined the effect of rottlerin on AMPK in vascular smooth muscle cells (VSMCs) and isolated rabbit aorta. Rottlerin reduced cellular ATP and activated AMPK in VSMCs and rabbit aorta; however, inhibition of PKCdelta by three different methods did not activate AMPK. Both VSMCs and rabbit aorta expressed the upstream AMPK kinase LKB1 protein, and rottlerin-induced AMPK activation was decreased in VSMCs by overexpression of dominant-negative LKB1, suggesting that LKB1 is involved in the upstream regulation of AMPK stimulated by rottlerin. These data suggest for the first time that LKB1 mediates rottlerin-induced activation of AMPK in vascular cells and tissues.

Effects of olmesartan, an angiotensin II receptor blocker, on peripheral insulin sensitivity in Japanese subjects with type 2 diabetes and hypertension.

OBJECTIVE: Several studies have assessed the efficacy of angiotensin receptor blockers (ARBs) on peripheral insulin sensitivity using the euglycemic hyperinsulinemic clamp technique in hypertensive subjects. However, these subjects were mostly non-diabetic, and some studies showed that ARB treatment did not improve insulin sensitivity. Thus, it is still uncertain whether ARBs could improve insulin sensitivity in subjects with hypertension and diabetes. Therefore, we evaluated the effect of olmesartan on peripheral insulin sensitivity in subjects with type 2 diabetes and hypertension using M/I value during the euglycemic-hyperinsulinemic clamp technique. METHODS: We enrolled 10 Japanese subjects with type 2 diabetes and hypertension who had never taken antihypertensive agents. Their blood pressure, fasting plasma glucose level, HbA1c and glucose utilization rate during euglycemic-hyperinsulinemic clamp (M/I value) were examined before and after 6 months of treatment with 10-20 mg/day olmesartan (mean: 13.0 mg/day). RESULTS: Blood pressure decreased significantly from 156/88 mmHg before starting olmesartan to 135/76 mmHg after 6 months of olmesartan treatment. The mean M/I value increased significantly from 6.33 ± 3.19 (mg/kg/min/mU/L) × 100 to 8.11 ± 4.20 (mg/kg/min/mU/L) × 100. Peripheral insulin sensitivity improved in eight out of ten subjects. Fasting glucose levels and HbA1c levels also decreased significantly. CONCLUSION: These results indicate that olmesartan improves glucose metabolism by improving the peripheral insulin sensitivity in subjects with type 2 diabetes.

What is artificial endocrine pancreas? Mechanism and history.

The artificial endocrine pancreas is a feedback control instrument that regulates insulin delivery on a minute-by-minute basis according to measured blood glucose levels. Only one type of bedside-type artificial endocrine pancreas is now available in Japan: STG-22 (Nikkiso Co. Ltd., Japan). In the insulin infusion algorithm, insulin is infused on the basis of its proportional and derivative actions, to blood glucose concentrations with a constant time delay. The bedside-type artificial endocrine pancreas has been proven to be useful not only as a therapeutic tool for diabetes mellitus, but also as an elegant research tool for investigating the pathophysiology of the disease, by using the euglycemic hyperinsulinemic glucose clamp technique. The wearable type of closed-loop system has been developed recently. The breakthrough is the establishment of a needle-type glucose sensor. The development of closed-loop glycemic control systems that enable long-term physiological regulation has focused on implantable devices. Much effort has been expended to realize these devices.

Development of a highly responsive needle-type glucose sensor using polyimide for a wearable artificial endocrine pancreas.

To produce a long-life, stable, miniature glucose sensor for a wearable artificial endocrine pancreas (WAEP), we developed a novel microneedle-type glucose sensor using polyimide, designated the PI sensor (outer diameter, 0.3 mm; length, 16 mm), and investigated its characteristics in vitro and in vivo. In the in vitro study, we tested the sensor in 0.9% NaCl solution with varying glucose concentrations and observed an excellent linear relationship between the sensor output and glucose concentration (range: 0-500 mg/100 ml). In in vivo experiments, the PI sensor was inserted into the abdominal subcutaneous tissue of beagle dogs (n = 5), and interstitial fluid glucose concentrations were monitored after sensor calibration. Simultaneously, blood glucose concentrations were also monitored continuously with another PI sensor placed intravenously. The correlation and time delay between subcutaneous tissue glucose (Y) and blood glucose concentrations (X: 30-350 mg/100 ml) were Y = 1.03X + 7.98 (r = 0.969) and 6.6 +/- 1.2 min, respectively. We applied the new WAEP system/PI sensor and an intravenous insulin infusion algorithm developed previously for glycemic control in diabetic dogs. The use of the WAEP system resulted in excellent glycemic control after an oral glucose challenge of 1.5 g/kg (post-challenge blood glucose levels: 176 +/- 18 mg/100 ml at 65 min and 93 +/- 23 mg/100 ml at 240 min), without any hypoglycemia. Thus, we confirmed that our new PI sensor has excellent sensor characteristics in vitro and in vivo. The new WAEP using this sensor is potentially suitable for clinical application.

Comparison between closed-loop portal and peripheral venous insulin delivery systems for an artificial endocrine pancreas.

To establish the ideal insulin delivery route for an artificial endocrine pancreas, we examined the effectiveness of closed-loop portal insulin delivery. We investigated the effects of the route of insulin delivery on net hepatic glucose balance (NHGB) in dogs under pancreatic clamp conditions with somatostatin plus basal glucagon and insulin infusions. A constant rate of suprabasal insulin was infused via the portal vein or a peripheral vein, and glucose was infused into the portal vein for 180 min. The mean net hepatic glucose uptake (NHGU) values in the portal insulin infusion group (PI group) were significantly greater than those in the peripheral venous insulin infusion group (VI group); the changes from the baseline values at 180 min were 3.54 +/- 0.66 and 2.45 +/- 0.82 mg kg(-1) min(-1) in the PI and VI groups, respectively, P < 0.05. Furthermore, dogs under pancreatic clamp conditions were controlled after a 2-g/kg oral glucose load by applying the closed-loop intraportal (PO) or intravenous (IV) insulin infusion algorithm. There were no significant differences in glycemic control and insulin requirements between these algorithms. However, the maximum peripheral venous and arterial plasma insulin concentrations with the PO algorithm were significantly lower than those with the IV algorithm [305.1 +/- 68.9 and 468.1 +/- 66.9 pmol/l (peripheral vein) and 305.3 +/- 62.9 and 469.6 +/- 85.1 pmol/l (artery) with the PO and IV algorithms, respectively, P < 0.05]. On the other hand, the maximum portal plasma insulin concentration with the PO algorithm was significantly higher than that with the IV algorithm (619.9 +/- 101.7 and 414.3 +/- 79.9 pmol/l with the PO and IV algorithms, respectively, P < 0.05). The mean NHGU values with the PO algorithm were significantly greater than those with the IV algorithm. Our results confirmed that closed-loop portal insulin delivery is feasible with regard to both insulin profiles and hepatic glucose handling in vivo, and indicated that the portal vein is the most suitable insulin delivery route for the artificial endocrine pancreas.

Strict glycemic control in diabetic dogs with closed-loop intraperitoneal insulin infusion algorithm designed for an artificial endocrine pancreas.

The ultimate goal of the development of an artificial endocrine pancreas is to achieve long-term strict glycemic regulation. To establish the physiological insulin delivery route of the artificial endocrine pancreas, intraperitoneal insulin infusion may be important. For this purpose, we tried to develop a closed-loop intraperitoneal insulin infusion algorithm by analyzing the pharmacokinetics of intraperitoneal regular insulin absorption using a mathematical model. The parameters for this algorithm were calculated to simulate the plasma insulin profile after intraperitoneal insulin injection as closely as possible. To evaluate the appropriateness of this algorithm, we tried glycemic control after an oral glucose load of 2 g/kg or a meal load of 80 kcal/kg in diabetic dogs by applying the algorithm. With the use of the subcutaneous insulin lispro infusion algorithm, which we have previously reported, alloxan-induced diabetic dogs exhibited postprandial hyperglycemia and delayed hyperinsulinemia, followed by hypoglycemia after an oral glucose load of 2 g/kg. However, by using the intraperitoneal insulin infusion algorithm, excellent glycemic control (postprandial blood glucose levels of 9.1 +/- 0.8 mmol/l at 70 min and 3.8 +/- 0.3 mmol/l at 240 min, respectively) could be achieved without any associated delayed hyperinsulinemia or hypoglycemia. Glycemic excursion after a meal load of 80 kcal/kg was also controlled from 3.9 to 10.1 mmol/l. Our results confirm that the intraperitoneal insulin infusion algorithm in vivo is feasible and that this algorithm can be superior to the subcutaneous insulin lispro infusion algorithm in the regulation of blood glucose.

Mitochondrial reactive oxygen species reduce insulin secretion by pancreatic beta-cells.

Pancreatic beta-cells exposed to hyperglycemia produce reactive oxygen species (ROS). Because beta-cells are sensitive to oxidative stress, excessive ROS may cause dysfunction of beta-cells. Here we demonstrate that mitochondrial ROS suppress glucose-induced insulin secretion (GIIS) from beta-cells. Intracellular ROS increased 15min after exposure to high glucose and this effect was blunted by inhibitors of the mitochondrial function. GIIS was also suppressed by H(2)O(2), a chemical substitute for ROS. Interestingly, the first-phase of GIIS could be suppressed by 50 microM H(2)O(2). H(2)O(2) or high glucose suppressed the activity of glyceraldehyde 3-phosphate dehydrogenase (GAPDH), a glycolytic enzyme, and inhibitors of the mitochondrial function abolished the latter effects. Our data suggested that high glucose induced mitochondrial ROS, which suppressed first-phase of GIIS, at least in part, through the suppression of GAPDH activity. We propose that mitochondrial overwork is a potential mechanism causing impaired first-phase of GIIS in the early stages of diabetes mellitus.