Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0011860 (type 2 diabetes)
 57,723 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Signaling through the phosphatidylinositol 3'-kinase (PI3K) pathway is crucial for metabolic responses to insulin, and defects in PI3K signaling have been demonstrated in type 2 diabetes. PTEN (MMAC1) is a lipid/protein phosphatase that can negatively regulate the PI3K pathway by dephosphorylating phosphatidylinositol (3,4,5)-triphosphate, but it is unclear whether PTEN is physiologically relevant to insulin signaling in vivo. We employed an antisense oligonucleotide (ASO) strategy in an effort to specifically inhibit the expression of PTEN. Transfection of cells in culture with ASO targeting PTEN reduced PTEN mRNA and protein levels and increased insulin-stimulated Akt phosphorylation in alpha-mouse liver-12 (AML12) cells. Systemic administration of PTEN ASO once a week in mice suppressed PTEN mRNA and protein expression in liver and fat by up to 90 and 75%, respectively, and normalized blood glucose concentrations in db/db and ob/ob mice. Inhibition of PTEN expression also dramatically reduced insulin concentrations in ob/ob mice, improved the performance of db/db mice during insulin tolerance tests, and increased Akt phosphorylation in liver in response to insulin. These results suggest that PTEN plays a significant role in regulating glucose metabolism in vivo by negatively regulating insulin signaling.
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PMID:Specific inhibition of PTEN expression reverses hyperglycemia in diabetic mice. 1191 22

Impaired insulin action is a key feature of type 2 diabetes and is also found, to a more extreme degree, in familial syndromes of insulin resistance. Although inherited susceptibility to insulin resistance may involve the interplay of several genetic loci, no clear examples of interactions among genes have yet been reported. Here we describe a family in which five individuals with severe insulin resistance, but no unaffected family members, were doubly [corrected] heterozygous with respect to frameshift/premature stop mutations in two unlinked genes, PPARG and PPP1R3A these encode peroxisome proliferator activated receptor gamma, which is highly expressed in adipocytes, and protein phosphatase 1, regulatory subunit 3, the muscle-specific regulatory subunit of protein phosphatase 1, which are centrally involved in the regulation of carbohydrate and lipid metabolism, respectively. That mutant molecules primarily involved in either carbohydrate or lipid metabolism can combine to produce a phenotype of extreme insulin resistance provides a model of interactions among genes that may underlie common human metabolic disorders such as type 2 diabetes.
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PMID:Digenic inheritance of severe insulin resistance in a human pedigree. 1211 51

In human type 2 diabetes mellitus, loss of glucose-sensitive insulin secretion is an early pathogenetic event. Glucose is the cardinal physiological stimulator of insulin secretion from the pancreatic beta-cell, but the mechanisms involved in glucose sensing are not fully understood. Specific ser/thr protein phosphatase (PPase) inactivation by okadaic acid promotes Ca(2+) entry and insulin exocytosis in the beta-cell. We now show that glycolytic and Krebs cycle intermediates, whose concentrations increase upon glucose stimulation, not only dose dependently inhibit ser/thr PPase enzymatic activities, but also directly promote insulin exocytosis from permeabilized beta-cells. Thus, fructose-1,6-bisphosphate, phosphoenolpyruvate, 3-phosphoglycerate, citrate, and oxaloacetate inhibit PPases and significantly enhance insulin exocytosis, nonadditive to that of okadaic acid, at micromolar Ca2+ concentrations. In contrast, the effect of GTP is potentiated by okadaic acid, suggesting that the action of GTP does not require PPase inactivation. We conclude that specific glucose metabolites and GTP inhibit beta-cell PPase activities and directly stimulate Ca2+-independent insulin exocytosis. The glucose metabolites, but not GTP, seem to require PPase inactivation for their stimulatory effect on exocytosis. Thus, an increase in phosphorylation state, through inhibition of protein dephosphorylation by metabolic intermediates, may be a novel regulatory mechanism linking glucose sensing to insulin exocytosis in the beta-cell.
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PMID:Glucose metabolites inhibit protein phosphatases and directly promote insulin exocytosis in pancreatic beta-cells. 1244 86

Disruption of the PPP1R3A gene encoding the glycogen targeting subunit (G(M)/R(GL)) of protein phosphatase 1 (PP1) causes substantial lowering of the glycogen synthase activity and a 10-fold decrease in the glycogen levels in skeletal muscle. Homozygous G(M)(-/-) mice show increased weight gain after 3 months of age and become obese, weighing approximately 20% more than their wild-type (WT) littermates after 12 months of age. Glucose tolerance is impaired in 11-month-old G(M)(-/-) mice, and their skeletal muscle is insulin-resistant at > or =12 months of age. The massive abdominal and other fat depositions observed at this age are likely to be a consequence of impaired blood glucose utilization in skeletal muscle. PP1-G(M) activity, assayed after specific immunoadsorption, was absent from G(M)(-/-) mice and stimulated in the hind limb muscles of WT mice by intravenous infusion of insulin. PP1-R5/PTG, another glycogen targeted form of PP1, was not significantly stimulated by insulin in the skeletal muscle of WT mice but showed compensatory stimulation by insulin in G(M)(-/-) mice. Our results suggest that dysfunction of PP1-G(M) may contribute to the pathophysiology of human type 2 diabetes.
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PMID:Disruption of the striated muscle glycogen targeting subunit PPP1R3A of protein phosphatase 1 leads to increased weight gain, fat deposition, and development of insulin resistance. 1260 98

Both type 2 diabetes and hypertension are multifactorial diseases. Several lines of evidence suggested that common genetic factors contribute to both conditions. Genes responsible for obesity and insulin resistance are candidates for common genetic factors. Among candidate genes are genes encoding glycogen synthase, beta 3-adrenergic receptor, glycogen-associated regulatory subunit of protein phosphatase-1, peroxisome proliferator--activated receptor-gamma (PPAR gamma), leptin and adiponectin. In addition, recent genome scans mapped loci linked to type 2 diabetes, hypertension and/or metabolic syndrome. Identification of genes responsible for both type 2 diabetes and hypertension will increase our understanding of molecular mechanisms of these conditions and facilitate the development of effective methods for prevention and intervention of diabetes and hypertension as well as metabolic syndrome.
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PMID:[Genetic susceptibility to diabetes and hypertension]. 1287 70

G(M), the muscle-specific glycogen-targeting subunit of protein phosphatase 1 (PP1) targeted to the sarcoplasmic reticulum, was proposed to regulate recovery of glycogen in exercised muscle, whereas mutation truncation of its COOH-terminal domain is known to be associated with type 2 diabetes. Here, we demonstrate differential effects of G(M) overexpression in human muscle cells according to glycogen concentration. Adenovirus-mediated delivery of G(M) slightly activated glycogen synthase (GS) and inactivated glycogen phosphorylase (GP) in glycogen-replete cells, causing an overaccumulation of glycogen and impairment of glycogenolysis after glucose deprivation. Differently, in glycogen-depleted cells, G(M) strongly increased GS activation with no further enhancement of early glycogen resynthesis and without affecting GP. Effects of G(M) on GS and GP were abrogated by treatment with dibutyryl cyclic AMP. Expression of a COOH-terminal deleted-mutant (G(M) Delta C), lacking the membrane binding sequence to sarcoplasmic reticulum, failed to activate GS in glycogen-depleted cells, while behaving similar to native G(M) in glycogen-replete cells. This is explained by loss of stability of the G(M) Delta C protein following glycogen-depletion. In summary, G(M) promotes glycogen storage and inversely regulates GS and GP activities, while, specifically, synthase phosphatase activity of G(M)-PP1 is inhibited by glycogen. The conditional loss of function of the COOH-terminal deleted G(M) construct may help to explain the reported association of truncation mutation of G(M) with insulin resistance in human subjects.
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PMID:Regulation and function of the muscle glycogen-targeting subunit of protein phosphatase 1 (GM) in human muscle cells depends on the COOH-terminal region and glycogen content. 1294 60

The protein phosphatase calcineurin is a signaling intermediate that induces the transformation of fast-twitch skeletal muscle fibers to a slow-twitch phenotype. This reprogramming of the skeletal muscle gene expression profile may have therapeutic applications for metabolic disease. Insulin-stimulated glucose uptake in skeletal muscle is both impaired in individuals with type II diabetes mellitus and positively correlated with the percentage of slow- versus fast-twitch muscle fibers. Using transgenic mice expressing activated calcineurin in skeletal muscle, we report that skeletal muscle reprogramming by calcineurin activation leads to improved insulin-stimulated 2-deoxyglucose uptake in extensor digitorum longus (EDL) muscles compared with wild-type mice, concomitant with increased protein expression of the insulin receptor, Akt, glucose transporter 4, and peroxisome proliferator-activated receptor-gamma co-activator 1. Transgenic mice exhibited elevated glycogen deposition, enhanced amino acid uptake, and increased fatty acid oxidation in EDL muscle. When fed a high-fat diet, transgenic mice maintained superior rates of insulin-stimulated glucose uptake in EDL muscle and were protected against diet-induced glucose intolerance. These results validate calcineurin as a target for enhancing insulin action in skeletal muscle.
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PMID:Skeletal muscle reprogramming by activation of calcineurin improves insulin action on metabolic pathways. 1294 59

Several lines of evidence suggest that the aetio-pathogenesis of the common form of type 2 diabetes mellitus and its intrinsically related features of impaired insulin secretion and decreased insulin sensitivity (insulin resistance) includes a strong genetic component. At present, however, little is known about the nature of this genetic component although familial clustering of the disease has been described for decades. Major break-throughs in the genetic sciences of type 2 diabetes have been identifications of insulin receptor gene mutations in syndromes of severe insulin resistance and mutations in pancreatic beta-cell genes in the monogenic sub-group of type 2 diabetes: maturity-onset-diabetes-of-the-young, MODY. Pathophysiological models of insulin resistance in skeletal muscles and impaired glucose-induced insulin secretion in the beta-cells have formed a basis for selecting candidate genes with potential influence on the development of type 2 diabetes ("diabetogenes"). This process of selecting and analyzing genes for mutations that potentially associate with either type 2 diabetes mellitus, insulin resistance or impaired insulin secretion is often described as the "candidate gene approach". The studies reported in this thesis are excerpts from an extensive strategy of genetically dissecting (mutation analysis) in: 1) patients with the common form of late-onset type 2 diabetes mellitus the pathways that transduce the insulin signals from the plasma membrane to the activation of glycogen synthesis in skeletal muscle, and in 2) patients with either late-onset type diabetes or MODY the pathways involved in normal beta-cell development and beta-cell function (insulin secretion). Twelve of the genes that encode proteins in the insulin-signalling pathway from the insulin receptor through the phosphatidylinositide-regulated kinases down to the complex of phosphatases that regulate glycogen synthesis in skeletal muscle were analyzed. We could not confirm that a Val985Met variant in the insulin receptor is associated with type 2 diabetes or that the Met326Val of the p85 alpha regulatory subunit of the phosphoinositide-3 kinase is associated with insulin resistance. We found no coding mutations (missense) in the insulin signalling protein kinases but we confirmed that the 5 bp deletion (PP1ARE) in the 3'-end of the PPP1R3 gene that encodes the glycogen-associated regulatory subunit of protein phosphatase-1 (PP1G) is associated with insulin resistance estimated as insulin mediated glucose uptake. In contrast to protein kinases in skeletal muscles the genes encoding beta-cell transcription factors (IPF-1, NeuroD1/BETA2, and Neurogenin 3) are polymorphic but we could not confirm that the Asp76Asn of IPF-1 is a susceptibility gene for late-onset type 2 diabetes. On the other hand we confirmed that the Ala45Thr variant in NeuroD1/BETA2 may represent a susceptibility gene for type 1 diabetes but none of these genes revealed any MODY-specific mutations. Also the gene encoding the ATP-regulatable potassium channels of the beta-cell (Kir6.2) is polymorphic but none of these polymorphisms associated with changes in glucose-induced insulin secretion. Reviewed in context of the existing data our studies support the candidate gene approach as a feasible method for directly either identifying or excluding any gene as a diabetes-susceptibility gene ("diabetogene").
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PMID:Candidate genes and late-onset type 2 diabetes mellitus. Susceptibility genes or common polymorphisms? 1469 50

The hormone leptin is secreted from white adipocytes, and serum levels of leptin correlate with adipose tissue mass. Leptin was first described to act on the satiety center in the hypothalamus through specific receptors (leptin receptor [ObR]) to restrict food intake and enhance energy expenditure. Important peripheral actions of leptin involve inhibition of insulin biosynthesis and secretion in pancreatic beta-cells. In turn, insulin stimulates leptin secretion from adipose tissue, establishing a hormonal regulatory feedback loop-the so-called "adipo-insular axis." Multiple signal transduction pathways are involved in leptin signaling in pancreatic beta-cells. We have identified the proinsulin gene and protein phosphatase 1 gene as leptin repressed genes and the gene for the suppressor of cytokine signaling 3 protein as a leptin-induced gene in pancreatic beta-cells. The molecular effects of leptin culminate to restrict insulin secretion and biosynthesis to adapt glucose homeostasis to the amount of body fat. In most overweight individuals, however, physiological regulation of body weight by leptin seems to be disturbed, representing "leptin resistance." This leptin resistance at the level of the pancreatic beta-cell may contribute to dysregulation of the adipo-insular axis and promote the development of hyperinsulinemia and manifest type 2 diabetes in overweight patients.
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PMID:Leptin effects on pancreatic beta-cell gene expression and function. 1474 81

In human type 2 diabetes, loss of glucose-stimulated insulin exocytosis from the pancreatic beta-cell is an early pathogenetic event. Mechanisms controlling insulin exocytosis are, however, not fully understood. We show here that inositol hexakisphosphate (InsP(6)), whose concentration transiently increases upon glucose stimulation, dose-dependently and differentially inhibits enzyme activities of ser/thr protein phosphatases in physiologically relevant concentrations. None of the hypoglycemic sulfonylureas tested affected protein phosphatase-1 or -2A activity at clinically relevant concentrations in these cells. Thus, an increase in cellular phosphorylation state, through inhibition of protein dephosphorylation by InsP(6), may be a novel regulatory mechanism linking glucose-stimulated polyphosphoinositide formation to insulin exocytosis in insulin-secreting cells.
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PMID:Inositol hexakisphosphate and sulfonylureas regulate beta-cell protein phosphatases. 1503 85


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