Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0011849 (diabetes)
277,896 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The isolated perfused working rat heart was used to study experimental diabetes-induced alterations in the effect of isoproterenol on adenosine 3',5'-cyclic monophosphate (cAMP) content, inotropy, and phosphorylase activity. Experimental diabetes was induced by intravenous injection of either alloxan (40 mg/kg) or streptozotocin (50 mg/kg). There were no changes in either basal cAMP levels or in isoproterenol-induced cAMP levels in hearts from diabetic rats at either 3 days or 100-120 days after induction of diabetes. Maximum changes produced by isoproterenol in positive and negative dP/dt developments of diabetic rat hearts were also not different from control at either time point. However, phosphorylase was activated to a significantly greater extent by isoproterenol in hearts obtained from acute as well as chronic diabetic rats. Chronic diabetic rat hearts exhibited significantly higher total phosphorylase activity. Diabetic rat hearts had slightly but not significantly higher basal phosphorylase a activity. Furthermore, prostaglandin E1 activated phosphorylase in diabetic rat hearts but not in control rat hearts. Acute metabolic derangements and alterations in Ca2+ homeostasis caused by diabetes could be the underlying causes for this phosphorylase response. Thyroid hormone levels were depressed in diabetic rats. However, hypothyroidism is probably not responsible for the alterations in phosphorylase activity.
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PMID:Effect of experimental diabetes on rat cardiac cAMP, phosphorylase, and inotropy. 630 13

Isolated perfused hearts from control Bio-Breeding/Worcester (BB/W) rats and spontaneously diabetic BB/W rats were studied to determine whether metabolic abnormalities that are expressed in alloxan-diabetic rats in the regulation of enzymes involved in glycogen metabolism could be observed in this non-chemically induced insulin-deficient rat. Perfusion of hearts from control rats with 10(-8) M insulin for 10 min resulted in activation of glycogen synthase (30% synthase I without insulin to 44% synthase I with insulin). Perfusion of hearts from BB/W diabetic rats demonstrated a lack of acute synthase activation with insulin and a 45% decrease in synthase phosphatase activity. Perfusion of hearts from BB/W diabetic rats with 0.28 microM epinephrine for 1 min resulted in a greater activation of phosphorylase (44% phosphorylase a) than that observed in BB/W control hearts (31% phosphorylase a) perfused under the same conditions. Epinephrine produced similar changes in cyclic AMP accumulation, protein kinase activation, and phosphorylase kinase activation in perfused hearts of BB/W control and diabetic rats. Further, phosphorylase phosphatase activities were not changed by epinephrine or insulin deficiency. These studies further document metabolic abnormalities in the BB/W diabetic rat that are attributable to insulin deficiency in a non-chemically induced model for insulin-dependent diabetes.
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PMID:Altered regulation of cardiac glycogen metabolism in spontaneously diabetic rats. 631 7

Glucose and gluconeogenic substrates promote the activation of hepatic glycogen synthase in vivo and in vitro; activation occurs as inactive glycogen synthase D is dephosphorylated to active glycogen synthase I by glycogen synthase phosphatase. Impairments of glycogen accumulation and glycogen synthase activation in diabetes have been attributed to decreased glycogen synthase phosphatase activity. To determine the role of glycogen synthase phosphatases associated with cytosol and smooth endoplasmic reticulum in the impairment of glycogen synthase activation, livers of normal and streptozotocin-diabetic fed rats were sampled by freeze-clamping before and after perfusion with a mixture of 25 mM glucose, 10 mM glutamine, 4 mM lactate, and 1 mM pyruvate. Perfusion induced activation of glycogen synthase in normal rats, but activation was reduced in the diabetic rats in proportion to the severity of insulin deficiency (r = 0.72, P less than 0.0001). There was also a close correlation between insulin levels and glycogen synthase phosphatase activities of both cytosol (r = 0.76, P less than 0.0001) and SER (r = 0.71, P less than 0.0001) fractions. In contrast, glycogen phosphorylase phosphatase activity and inactivation of glycogen phosphorylase during perfusion were normal in the diabetic livers. This is the first demonstration that glycogen synthase phosphatase activities in both soluble and SER fractions of liver cells are closely related to circulating insulin levels, and that the impairment of glycogen synthesis in diabetes may result from deficient glycogen synthase phosphatase activity in both cell compartments.
Diabetes 1983 Dec
PMID:Impaired glycogenic substrate activation of glycogen synthase is associated with depressed synthase phosphatase activity in diabetic rat liver. 631 99

Isolated perfused hearts from normal and alloxan-diabetic rats were studied to determine the effects of prostaglandin E1 (PGE1) on phosphorylase activation in the insulin-deficient state. Perfusion of hearts from normal and diabetic rats with 3 X 10(-5) M PGE1 for the final 2 min resulted in activation to the same extent of adenosine 3',5'-cyclic monophosphate (cAMP) accumulation, cAMP-sensitive protein kinase, and phosphorylase kinase. Although phosphorylase activation was somewhat suppressed in both the normal and diabetic heart, PGE1 produced a 36% increase in phosphorylase a in normal hearts and a 44% increase in phosphorylase a in diabetic hearts. The decreased effectiveness of phosphorylase activation by PGE1 appears to be located beyond activation of phosphorylase kinase and perhaps involves an alteration in phosphorylase sensitivity to phosphorylase kinase. Further, the activation of phosphorylase by phosphorylase kinase is hypersensitive in hearts of diabetic rats, perhaps due to a diabetes-related alteration in calcium metabolism.
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PMID:Effects of prostaglandin E1 in diabetic heart. 631 70

A hypersensitivity of glycogen phosphorylase activation by epinephrine and glucagon has been demonstrated in isolated perfused working and non-working hearts from diabetic rats. Accumulation of tissue cAMP and activation of cAMP-dependent protein kinase in response to epinephrine and glucagon were no greater and usually less in hearts of diabetic than of normal rats. Insulin deficiency was not associated with greater changes in epinephrine-induced activation of glycogen phosphorylase kinase than that observed in normal hearts. Perfusion of hearts with subphysiological concentrations of calcium (0.83 mM) partially reversed the diabetes-related hypersensitivity of phosphorylase activation by epinephrine. The phosphorylase activation hypersensitivity to epinephrine was completely reversed by adrenalectomizing diabetic rats 5 days before heart perfusion, an effect potentially caused by steroid-induced changes in cardiac calcium metabolism. These data are consistent with the hypothesis that phosphorylase activation by phosphorylase kinase is allosterically increased in the diabetic due to a diabetes-related increase in free intracellular calcium concentrations.
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PMID:Phosphorylase activation hypersensitivity in hearts of diabetic rats. 632 Jun 71

Hepatocytes from normal fed rats and from chronically (90 h) alloxan-diabetic rats were compared. The rate and the extent of activation of glycogen synthase in response to 60 mM-glucose were greatly decreased in diabetes. During incubation of gel-filtered extracts from broken hepatocytes, diabetes only decreased the rate of the activation, which became ultimately complete in either preparation. Synthase phosphatase activity, as measured by the activation of purified hepatic synthase b, was decreased in chronic diabetes. The decrease was proportional to the severity of the diabetes, and reached 90% when the plasma glucose concentration was greater than or equal to 55 mM. In contrast, phosphorylase phosphatase activity was not decreased. Synthase phosphatase activity was progressively restored by treatment with insulin for 20-68 h. During the induction of diabetes and during insulin treatment there was a good correlation between the activity of synthase phosphatase and the maximal activation of synthase in glucose-stimulated hepatocytes from the same livers. The decreased activity of synthase phosphatase in diabetes cannot be explained by an inhibitor. The decrease was much less marked when synthase phosphatase was assayed by the dephosphorylation of 32P-labelled synthase from muscle. This observation suggested a loss of only one component of synthase phosphatase. Cross-combination of subcellular fractions from control rats and from diabetic rats showed a preferential loss of G-component, with little or no loss of S-component. No G-component could be detected in severe diabetes. The concentration of G-component is therefore of critical importance in the glucose-induced activation of glycogen synthase in the liver.
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PMID:The hepatic defect in glycogen synthesis in chronic diabetes involves the G-component of synthase phosphatase. 632 Aug 6

It was shown previously in experiments on white rats with alloxan diabetes that trihydroxyoctadecadiene acids from Bryonia alba L. have a hypoglycemic action. The present paper is concerned with the effects of the above-indicated compounds on the activity of glycogen phosphorylase (a- and b-forms), phosphoprotein phosphatase and hexokinase in liver and muscle tissues of white rats with alloxan diabetes. One of the possible mechanisms of the hypoglycemic action of trihydroxyoctadecadiene acids is discussed.
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PMID:[Effect of trihydroxyoctadecadiene acids from Bryonia alba L. on the activity of glycogen metabolism enzymes in alloxan diabetes]. 632 80

Cells are endowed with specific cognitive molecules that function as receptors for hormones, neurotransmitters, and other intercellular messengers. The receptor molecules may be present in the plasma membrane, cytoplasm, or nucleus. When occupied by the messenger, the receptor is coupled to the cellular machinery that responds to the message-bearing molecules. For some hormones the events following attachment of the messenger to the receptor are well known. An example is the generation of cAMP after combination of glucagon with its receptor and the series of steps culminating in activation of phosphorylase. In the case of many other messengers, including insulin, the nature of these coupling steps is not known. Receptors are subject to the regulatory processes of synthesis, degradation, and conformational change; alterations in receptor properties may have significant effects on the qualitative and quantitative responses of the cell to the extracellular messenger. The insulin receptor is located in the plasma membrane, is composed of two pairs of subunits, and has a molecular weight of about 350,000. It is located in cells such as adipocytes, hepatocytes, and skeletal muscle cells as well as in cells not considered to be typical target organ cells. Insulin receptors in nonfetal cells are downregulated by exposure of the cells to high concentrations of insulin. Other factors that regulate insulin binding include muscular exercise, diet, thyroid hormones, glucocorticoids, androgens, estrogens, and cyclic nucleotides. The fetus has high concentrations of insulin receptors in several tissues. These begin to appear early in fetal life and may outnumber those found in adult tissues. Fetal insulin receptors are unusual in that they may not undergo downregulation but may experience the opposite when exposed to insulin in high concentrations. Thus the offspring of a mother with poorly controlled diabetes may be placed in double jeopardy by fetal hyperinsulinemia and augmented insulin binding by the receptors. Many disorders in children and adults are associated with changes in the properties of the insulin receptor. In general, the alterations have been measured in receptor-bearing cells that are readily accessible, such as circulating monocytes and erythrocytes. The receptors on these cells generally reflect the status of receptors on the major target organs of insulin, although exceptions are known, and conclusions drawn from studies of receptors on circulating cells must be made with caution.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:The insulin receptor. 636 73

The metabolic basis for glycogen accumulation in the placenta of rats with diabetes induced by streptozotocin on day 12 of pregnancy was studied on days 15 and 20. On day 15 glycogen content of the placenta was 1.5-fold higher in the diabetic than in the control rats and this difference increased to greater than fivefold on day 20 of gestation whether calculated per g tissue or per total placenta. Accumulation of glycogen was associated with increased specific activities of both glycogen synthase and phosphorylase. The activities of these enzymes regulating synthase and phosphorylase activities and the activity of acid alpha-glucosidase were not significantly affected by diabetes. Glucose-6-phosphate concentration of the placenta was 67 and 23 nmol/g in diabetic and control rats, respectively. Incubation of placental homogenates with glucose increased the rate of inactivation of phosphorylase and activation of glycogen synthase. These results indicate that the enhanced glucogenesis in diabetes is not due to changes in the activities of these enzymes, as measured in vitro under standard conditions. The factors promoting glycogen accumulation in vivo are related to the abundance of glucose and glucose-6-phosphate as substrates for glycogen synthesis, which may also cause an increase in the activity ratio glycogen synthase a/phosphorylase a. In addition, the high intracellular glucose-6-phosphate concentration is likely to enable glycogen synthase b to contribute to glycogen synthesis.
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PMID:Mechanism of placental glycogen deposition in diabetes in the rat. 640 9

The effects of glucose on phosphorylase and glycogen synthase were investigated in hepatocytes isolated from acutely (40 h) and chronically (90 h) alloxan-diabetic rats. The glucose-induced inactivation of phosphorylase proceeded normally in all conditions. The ensuing activation of glycogen synthase was slightly blunted in acute diabetes, but became virtually absent in 72 h diabetes of similar severity. In hepatocytes from rats with various degrees of chronic diabetes, the maximal activation of glycogen synthase (at 60 mM-glucose) was inversely correlated with the plasma glucose concentration.
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PMID:Effects of glucose on phosphorylase and glycogen synthase in hepatocytes from diabetic rats. 640 78


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