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Query: UMLS:C0011860 (type 2 diabetes)
 57,723 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Insulin resistance, a major predictor of type 2 diabetes mellitus, is genetically inherited in Pima Indians, a population with a high prevalence of the metabolically complex disease. Protein targeting to glycogen/PPP1R5 has recently been identified as a potential regulator of glycogen synthase, the rate-limiting enzyme of the insulin-induced glycogenesis. The gene is located on chromosome 10q23-24, where there is a suggestive linkage to insulin action in this population, establishing it as a functional and positional candidate gene. In this study, we discovered 2 novel polymorphisms upstream of the 5'UTR of the gene, with only one found in Pima Indians, but no polymorphism in the coding sequence. The genotype frequencies of the polymorphism and transcript levels of the gene in skeletal muscle do not correlate with insulin action in the subjects. These results exclude any significant role of protein targeting to glycogen/PPP1R5 in insulin resistance in Pima Indians.
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PMID:Protein targeting to glycogen/PPP1R5: screening of coding and flanking genomic regions for polymorphisms and association analysis with insulin action in Pima Indians. 1022 57

Evidence is presented that shows that free fatty acids (FFA) are one important link between obesity, insulin resistance, and type 2 diabetes. Plasma FFA levels are elevated in most obese subjects, and physiological elevations of plasma FFA inhibit insulin-stimulated glucose uptake into muscle. This peripheral insulin resistance is caused by an FFA-induced defect, which develops 3-4 hr after raising plasma FFA, in insulin-stimulated glucose transport or phosphorylation, or both. This resistance is also caused by a second defect, which develops after 4-6 hr, consisting of inhibition of glycogen synthase activity. Whether elevated plasma FFA levels inhibit insulin action on endogenous glucose production (EGP), that is, cause central insulin resistance, is more difficult to demonstrate. On the one hand, FFA increase gluconeogenesis, which enhances EGP; on the other hand, FFA increase insulin secretion, which decreases EGP. Basal plasma FFA support approximately one third of basal insulin secretion in diabetic and nondiabetic subjects and, hence, are responsible for some of the hyperinsulinemia in obese, normoglycemic patients. In addition, elevated plasma FFA levels potentiate glucose-stimulated insulin secretion acutely and during prolonged exposure (48 hr). It is hypothesized that obese subjects who are genetically predisposed to develop type 2 diabetes will become partially "lipid blind," that is, unable to compensate for their FFA-induced insulin resistance with FFA-induced insulin oversecretion. The resulting insulin resistance/secretion deficit will then have to be compensated for with glucose-induced insulin secretion, which, because of their partial "glucose blindness," will result in hyperglycemia and eventually in type 2 diabetes.
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PMID:Free fatty acids, insulin resistance, and type 2 diabetes mellitus. 1035 64

The author presents a review on candidate genes of proteins involved in the metabolism of glucose, lipids and other metabolites (glucose carriers, insulin receptors, proinsulin, glucokinase, amyline, glycogen synthase). One of the main causes of enhanced atherogenesis in patients with type II diabetes (NIDDM) are marked genetically conditioned deviations of the lipid, lipoprotein and apolipoprotein metabolism. In the metabolic dyshomeostasis of multiple metabolic syndrome participate in the process of atherogenesis also: isoforms of apolipoprotein E4, isoforms of apolipoprotein A-IV-1/1, hyperuricaemia, raised levels of the plasminogen activator inhibitor 1 (PAI-1), hyperfibrinogenaemia, hyperhomocysteinaemia and other metabolites (cytokines, endothelin etc.). Patients with a greated genetic sensitivity manifest diabetes sooner and more intensely and die at a younger age in particular from cardiovascular disease, but also on account of a higher incidence of tumours diseases.
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PMID:[Genetic predisposition in multiple metabolic syndrome. Part 2. Candidate genes in type II diabetes mellitus]. 1037 88

The development of late onset non-insulin dependent diabetes mellitus (NIDDM) is due to a complicated interplay between genes and environment on one side, and the interaction between metabolic defects in various tissues including the pancreatic beta cell (decreased insulin secretion), skeletal muscle (insulin resistance), liver (increased gluconeogenesis), adipose tissue (increased lipolysis) and possibly gut incretin hormones (defective glucagon like peptide 1 (GLP1) secretion) on the other side. Evidence for a genetic component includes the finding of a variety of metabolic defects in various tissues in non-diabetic subjects with a genetic predisposition to NIDDM, higher concordance rates for abnormal glucose tolerance including NIDDM in monozygotic compared with dizygotic twins, and the more recent demonstration of different NIDDM susceptibility genes at the sites of Insulin Receptor Substrate 1 (IRS1), the beta-3 adrenergic receptor, and the sulfonylurea receptor. However, the latter susceptibility genes only explain a minor proportion of NIDDM in the general population, and the quantitative extent to which genetic versus non-genetic factors contribute to NIDDM is presently unsolved. Environmental components include both an early intrauterine component associated with low birth weight, and later postnatal components including low physical activity, high fat diet, and the subsequent development of obesity and elevated plasma and tissue free fatty acid levels. Our finding of lower birth weights in monozygotic twins compared with their non-diabetic genetically identical co-twins excludes the possibility that the association between NIDDM and low birth weight as demonstrated in several studies may solely be explained by a coincidence between a certain gene causing both a low birth weight and an increased risk of NIDDM. Young first degree relatives of patients with NIDDM are characterized by hyperinsulinaemia and peripheral insulin resistance, which in turn may be explained by a decreased insulin activation of the enzyme glycogen synthase in skeletal muscle. Therefore, a defective skeletal muscle glycogen synthase activation may represent an early phenotypic expression of a genetic defect contributing to an increased risk of later development of NIDDM. However, elderly insulin resistant non-diabetic co-twins (64 years old) of twins with overt NIDDM does not--in contrast to their NIDDM co-twins--have a significantly decreased insulin activation of glycogen synthase in skeletal muscle. This demonstrates that the defective muscle glycogen synthase insulin activation has an apparent non-genetic component, and that this key defect of metabolism can be escaped or postponed even in non-diabetic subjects with a presumably 100% genetic predisposition to NIDDM. The insulin activation of glycogen synthase in skeletal muscle is compensated or apparently normalised in NIDDM patients when studied during their ambient fasting hyperglycaemia and a subsequent isoglycaemic (hyperglycaemic) physiologic insulin infusion. This indicates that the prevailing hyperglycaemia in NIDDM subjects compensates for the defective insulin activation of glycogen synthase present in those subjects when studied during eulycaemia. Our data and those of others also indicates that hyperglycaemia in NIDDM compensates for the defects in insulin secretion, the disproportionately elevated hepatic glucose production, and to some extent for the increased lipid oxidation and the decreased glucose oxidation present in NIDDM patients. Accordingly, NIDDM subjects exhibit all of those defects of metabolism when studied during "experimental decompensation" when the ambient hyperglycaemia is normalized by a prior and later withdrawn intravenous insulin infusion. However, shortly after the withdrawal of the intravenous insulin infusion, the plasma glucose concentration increased spontaneously in the NIDDM patients. (ABSTRACT TRUNCATED)
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PMID:On the pathophysiology of late onset non-insulin dependent diabetes mellitus. Current controversies and new insights. 1042 79

Many recent data provide new, original insights into the mechanisms of action of the antidiabetic Metformin. Careful selection of most relevant data in terms of dosage prompted this original review, largely devoted to the drug action at the cell level and whose hypotheses/conclusions are tentatively interpreted according to corresponding basic scientific knowledge. Metformin interferes with several processes linked to HGP (gluconeogenesis, glycogenolysis and their regulatory mechanisms), lowering glucose production and resensitizing the liver to insulin. The hepatic drug effect is largely favoured by prevailing glycemia. In peripheral tissues, metformin potentiates the effects of both hyperglycemia and hyperinsulinemia. Increase in glucose-mediated glucose transport is mainly mediated by an improvement in the glucose transporter's intrinsic activity. Potentiation of the hormone effect relates to an increase in insulin receptor tyrosine kinase activity. Both mechanisms (insulin signalling and glucose transport) result in the activation of glycogen synthase, a limiting enzyme in the causal defects of NIDDM. Exciting findings show that, conversely, priming cells with very low insulin concentrations also leads to full expression of metformin's antidiabetic activity. Specific investigations confirm a working hypothesis defining the site of action as the cell membrane level. Indeed metformin corrects membrane fluidity and protein configuration disturbed by the diabetic state and which interfere with normal protein-protein or protein-lipid interactions required for proper functioning of the processes regulating glucose transport/metabolism. It is proposed that membrane changes largely represent a common denominator explaining metformin effects on various systems involved in receptor signalling and related functions.
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PMID:Membrane physiology as a basis for the cellular effects of metformin in insulin resistance and diabetes. 1044 22

Zucker diabetic fatty rats develop type 2 diabetes concomitantly with peripheral insulin resistance. Hepatocytes from these rats and their control lean counterparts have been cultured, and a number of key parameters of glucose metabolism have been determined. Glucokinase activity was 4.5-fold lower in hepatocytes from diabetic rats than in hepatocytes from healthy ones. In contrast, hexokinase activity was about 2-fold higher in hepatocytes from diabetic animals than in healthy ones. Glucose-6-phosphatase activity was not significantly different. Despite the altered ratios of glucokinase to hexokinase activity, intracellular glucose 6-phosphate concentrations were similar in the two types of cells when they where incubated with 1-25 mM glucose. However, glycogen levels and glycogen synthase activity ratio were lower in hepatocytes from diabetic animals. Total pyruvate kinase activity and its activity ratio as well as fructose 2,6-bisphosphate concentration and lactate production were also lower in cells from diabetic animals. All of these data indicate that glucose metabolism is clearly impaired in hepatocytes from Zucker diabetic fatty rats. Glucokinase overexpression using adenovirus restored glucose metabolism in diabetic hepatocytes. In glucokinase-overexpressing cells, glucose 6-phosphate levels increased. Moreover, glycogen deposition was greatly enhanced due to the activation of glycogen synthase. Pyruvate kinase was also activated, and fructose-2,6-bisphosphate concentration and lactate production were increased in glucokinase-overexpressing diabetic hepatocytes. Overexpression of hexokinase I did not increase glycogen deposition. In conclusion, hepatocytes from Zucker diabetic fatty rats showed depressed glycogen and glycolytic metabolism, but glucokinase overexpression improved their glucose utilization and storage.
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PMID:Glucokinase overexpression restores glucose utilization and storage in cultured hepatocytes from male Zucker diabetic fatty rats. 1054 7

Metformin is regarded as an antihyperglycaemic agent because it lowers blood glucose concentrations in type 2 (non-insulin-dependent) diabetes without causing overt hypoglycaemia. Its clinical efficacy requires the presence of insulin and involves several therapeutic effects. Of these effects, some are mediated via increased insulin action, and some are not directly insulin dependent. Metformin acts on the liver to suppress gluconeogenesis mainly by potentiating the effect of insulin, reducing hepatic extraction of certain substrates (e.g. lactate) and opposing the effects of glucagon. In addition, metformin can reduce the overall rate of glycogenolysis and decrease the activity of hepatic glucose-6-phosphatase. Insulin-stimulated glucose uptake into skeletal muscle is enhanced by metformin. This has been attributed in part to increased movement of insulin-sensitive glucose transporters into the cell membrane. Metformin also appears to increase the functional properties of insulin- and glucose-sensitive transporters. The increased cellular uptake of glucose is associated with increased glycogen synthase activity and glycogen storage. Other effects involved in the blood glucose-lowering effect of metformin include an insulin-independent suppression of fatty acid oxidation and a reduction in hypertriglyceridaemia. These effects reduce the energy supply for gluconeogenesis and serve to balance the glucose-fatty acid (Randle) cycle. Increased glucose turnover, particularly in the splanchnic bed, may also contribute to the blood glucose-lowering capability of metformin. Metformin improves insulin sensitivity by increasing insulin-mediated insulin receptor tyrosine kinase activity, which activates post-receptor insulin signalling pathways. Some other effects of metformin may result from changes in membrane fluidity in hyperglycaemic states. Metformin therefore improves hepatic and peripheral sensitivity to insulin, with both direct and indirect effects on liver and muscle. It also exerts effects that are independent of insulin but cannot substitute for this hormone. These effects collectively reduce insulin resistance and glucotoxicity in type 2 diabetes.
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PMID:The antihyperglycaemic effect of metformin: therapeutic and cellular mechanisms. 1057 23

In Western countries 25-35% of the population have insulin resistance syndrome characteristics. The defects most likely to explain the insulin resistance of the insulin resistance syndrome include: 1) the glucose transport system of skeletal muscle (GLUT-4) and its different signalling proteins and enzymes; 2) glucose phosphorylation by hexokinase; 3) glycogen synthase activity and 4) competition between glucose and fatty acid oxidation (glucose-fatty acid cycle). High carbohydrate/low fat diets deteriorate insulin sensitivity on the short term. However, on the long term, high fat/low carbohydrate diets have a lower satiating power, induce low leptin levels and eventually lead to higher energy consumption, obesity and more insulin resistance. Moderately high-carbohydrate (45-55% of the daily calories)/low-fat diets seem to be a good choice with regard to the prevention of diabetes and cardiovascular risk factors as far as the carbohydrates are rich in fibers. Long-term interventions with regular exercise programs show a 1/3 decrease in the appearance of overt diabetes in glucose intolerant subjects. Furthermore, diet and exercise interventions "normalise" the mortality rate of patients with impared glucose tolerance. Therefore, moderately high carbohydrate/low fat diets are most likely to prevent obesity and type 2 diabetes. Triglycerides should be monitored and, in some cases, a part of the carbohydrates could be replaced by fat rich in monounsaturated fatty acids. However, total caloric intake is of utmost importance, as weight gain is the major determinant for the onset of insulin resistance and glucose intolerance. Regular (when possible daily) exercise, decreases cardiovascular risk. With regard to insulin resistance, resistance training seems to offer some advantages over aerobic endurance activities.
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PMID:Interaction of physical activity and diet: implications for insulin-glucose dynamics. 1061 74

The PPP1R3 gene encoding the G-subunit of protein phosphatase-1 has three polymorphisms in linkage disequilibrium in the Pima Indians: an mRNA-destabilizing element in the 3'-untranslated region (ARE1/ARE2 alleles), Arg883Ser, and Asp905Tyr substitutions. The ARE2 allele, Arg883, and Asp905 variants are associated with insulin resistance and higher prevalence of type 2 diabetes in the Pima Indians. The ARE2 allele is associated with lower PPP1R3 transcript and protein levels in muscle tissue. Here we determined the functional contribution of the amino acid substitutions independent of the ARE alleles to insulin-stimulated glycogen synthesis by adenoviral-mediated gene expression in L6 myotubes. Similar overexpression levels of the G-subunit variants increased glycogen synthase fractional activity in the presence ( approximately 1. 5-fold) of insulin compared to control myotubes transduced with adenovirus encoding beta-galactosidase. The glycogen synthesis rate of myotubes overexpressing the G-subunit variants also increased by approximately 1.7-fold over the control with and without insulin. However, these measures were not significantly different among the variants. This study does not support a role for Arg883 and Asp905 variants independent of the ARE2 allele in the impaired insulin-stimulated glycogen synthesis in the muscle of Pima Indians.
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PMID:Functional analyses of amino acid substitutions Arg883Ser and Asp905Tyr of protein phosphatase-1 G-subunit. 1087 97

Little information is available in the literature on the effect of L-carnitine to improve glucose disposal in healthy control subjects and type 2 diabetic patients. No data are reported on the pharmacological properties of acetyl-L-carnitine (ALC) in type 2 diabetes mellitus. The present study evaluates glucose uptake and oxidation rates with either ALC or placebo administration in 18 type 2 diabetic patients. On different days, each patient received both a primed-constant infusion of ALC (5 mg/kg body weight [BW] priming bolus and either 0.025, 0.1, or 1.0 mg/kg BW/min constant infusion) and a comparable placebo formulation. During the infusion period, continuous indirect calorimetric monitoring and a euglycemic-hyperinsulinemic clamp (EHC) study were performed. The total end-clamp glucose tissue uptake (M value) was significantly increased by the administration of ALC (from 3.8 to 5.2 mg/kg/min, P = .006), and the dose dependence of this effect reached borderline statistical significance (P = .037). The increase in the M/I ratio was also highly significant after ALC administration (from 3.9 to 5.8 x 10(-2) mg/kg/min/(microUI/mL, P < .001), while no statistically significant effect was attributable to the different dosages. The increase in the M value was related to increased glucose storage (highly significant effect of ALC) rather than increased glucose oxidation (no statistical significance). In conclusion, the effect of ALC on glucose disposal has no relationship to the amount administered. This could be due to an effect of ALC on the enzymes involved in both the glycolytic and gluconeogenetic pathways, and a possible reversibility of glycogen synthase inhibition in diabetic subjects.
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PMID:Acetyl-L-carnitine infusion increases glucose disposal in type 2 diabetic patients. 1087 93


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