An inhibitor of human liver glycogen phosphorylase a (HLGPa) has been identified and characterized in vitro and in vivo. This substance, [R-(R*,S*)]-5-chloro-N-[3-(dimethylamino)-2-hydroxy-3-oxo-1-(phenylmethyl)propyl]-1H-indole-2-carboxamide (CP-91149), inhibited HLGPa with an IC 50 of 0.13 M in the presence of 7.5 mM glucose. CP-91149 resembles caffeine, a known allosteric phosphorylase inhibitor, in that it is 5-to 10-fold less potent in the absence of glucose. Further analysis, however, suggests that CP-91149 and caffeine are kinetically distinct. Functionally, CP-91149 inhibited glucagon-stimulated glycogenolysis in isolated rat hepatocytes (P < 0.05 at 10-100 M) and in primary human hepatocytes (2.1 M IC 50 ). In vivo, oral administration of CP-91149 to diabetic ob͞ob mice at 25-50 mg͞kg resulted in rapid (3 h) glucose lowering by 100-120 mg͞dl (P < 0.001) without producing hypoglycemia. Further, CP-91149 treatment did not lower glucose levels in normoglycemic, nondiabetic mice. In ob͞ob mice pretreated with 14 C-glucose to label liver glycogen, CP-91149 administration reduced 14 C-glycogen breakdown, confirming that glucose lowering resulted from inhibition of glycogenolysis in vivo. These findings support the use of CP-91149 in investigating glycogenolytic versus gluconeogenic f lux in hepatic glucose production, and they demonstrate that glycogenolysis inhibitors may be useful in the treatment of type 2 diabetes.
We have previously shown that hemizygous transgenic mice expressing human islet amyloid polypeptide (hIAPP) in pancreatic beta-cells have no diabetic phenotype, whereas in the homozygous state, they developed severe, early-onset hyperglycemia associated with impaired insulin secretion and beta-cell death. We investigated the possibility that when the hemizygous mice are crossed onto an obese, insulin-resistant strain such as agouti viable yellow (A(vy)/a), they would exhibit a phenotype more akin to human type 2 diabetes. The hIAPP-expressing A(vy) males (TG-Y) displayed fasting hyperglycemia at 90 days of age and by 1 year progressed to severe hyperglycemia relative to their nontransgenic counterparts. Plasma insulin concentrations and pancreatic insulin content dropped 10- to 20-fold, suggesting severe impairment of beta-cell function. Histopathological findings revealed beta-cell degeneration and loss consistent with the drop in the plasma insulin concentration. In addition, large deposits of IAPP amyloid were present in TG-Y islets. We conclude that in transgenic mice expressing hIAPP, insulin resistance can induce overt, slow-onset diabetes associated with islet amyloid and decreased beta-cell mass.
To assess the importance of the route of glucose delivery in determining net hepatic glucose balance (NHGB) eight conscious overnight-fasted dogs were given glucose via the portal or a peripheral vein. NHGB was measured using the arteriovenous difference technique during a control and two 90-min glucose infusion periods. The sequence of infusions was randomized. Insulin and glucagon were held at constant basal levels using somatostatin and intraportal insulin and glucagon infusions during the control, portal, and peripheral glucose infusion periods (7±1, 7±1, 7±1 IU/ml; 100±3, 101±6, 101±3 pg/ml, respectively).In the three periods the hepatic blood flow, glucose infusion rate, arterial glucose level, hepatic glucose load, arterial-portal glucose difference and NHGB were 37±1, 34±1, 32±3 ml/kg per min; 0±0, 4.51±0.57, 4.23±0.34 mg/kg per min; 101±5, 200±15, 217±13 mg/dl; 28.5±3.5, 57.2±6.7, 54.0±6.4 mg/kg per min; +2±1, -22±3, +4±1 mg/dl; and 2.22±0.28, -1.41±031, and 0.08±0.23 mg/kg per min, respectively. Thus when glucose was delivered via a peripheral vein the liver did not take up glucose but when a similar glucose load was delivered intraportally the liver took up 32% (P < 0.01) of it. In conclusion portal glucose delivery provides a signal important for the normal hepatic-peripheral distribution of a glucose load.
The adult greyhound was found to be similar to adult man with respect to kinetic and histomorphometric indices of calcium metabolism. The relationship between trabecular bone tissue balance and the pattern of human PTH fragment 1-34 (hPTH 1-34) administration by daily injections or continuous sc infusions was investigated in this model and the results compared to those from a clinical trial of hPTH 1-34 in involutional osteoporosis (peptide administration by single daily injections). In the dogs, the daily injection regime elevated plasma levels of immunoreactive hPTH 1-34 for no more than 4 h/day. The greyhounds so treated showed significantly increased indices of bone formation (surface osteoid, plasma alkaline phosphatase activity, and skeletal accretion rate of calcium) and resorption (number of osteoclasts, resorption surfaces). Iliac trabecular bone volume increased significantly, as it did in the patients. The infusions did not significantly increase the trabecular bone volume or the 47Ca accretion rate, two parameters which increased in parallel in dogs and patients treated successfully by daily injections. The osteoclastic surfaces, however, were clearly increased by continuous infusions, while the increases in the osteoblastic surfaces were less statistically significant. Since hPTH 1-34 may inhibit osteogenesis in Friedenstein chambers, it is possible that the increased osteoblastic activity induced by the daily injection regime in trabecular bone is dependent on the noncontinuous nature of the PTH stimulus.
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