UMLS:C0028754 - FACTA Search

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Query: UMLS:C0028754 (obesity)
124,988 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Theophylline and its derivatives, such as aminophylline, have an established role as bronchodilators, although their mode of action in man is not clear. There is circumstantial evidence that therapeutic doses of theophylline may have a phosphodiesterase inhibiting effect, thus potentiating the effects of cyclic AMP. However, it remains to be established whether this is the primary mode of action of theophylline at the biochemical level. The pathways of theophylline metabolism have been clarified, although most of the enzymes involved have not been characterized. Hepatic microsomal enzyme induction by polycyclic hydrocarbons will increase the rate of theophylline elimination. There are a number of factors which influence theophylline clearance in adults, which is known to be highly variable. These factors include obesity, smoking habit, diet and the presence of such diseases as hepatic cirrhosis, acute pulmonary oedema, cor pulmonale and viral respiratory infection. There is a good correlation between plasma theophylline level and bronchodilator effect. This can be demonstrated at plasma levels as low as 5 microgram/ml, although optimal levels are usually greater than 10 microgram/ml. Unacceptable toxicity usually occurs in association with plasma levels greater than 20 microgram/ml. The maintenance of adequate plasma theophylline levels by the use of a sustained-release aminophylline tablet is discussed.
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PMID:Theophylline: biochemical pharmacology and pharmacokinetics. 22 Jan 19

Current concepts about the mechanisms underlying the therapeutic effects of dietary methylxanthines (caffeine, theophylline, and theobromine) favor their actions as antagonists of adenosine receptors, and attribute their other possible modes of action, namely those associated with translocation of intracellular calcium, inhibition of phosphodiesterase enzyme (PDE) activity, or the release of catecholamines, to high (near-toxic) doses. From studies measuring the respiration rate of brown adipose tissue (BAT), evidence is provided here that at concentrations compatible with therapeutic doses, the ability of methylxanthines (25 to 50 mumol/L) to potentiate the thermogenic effect of the sympathomimetic drug, ephedrine (0.25 mumol/L), particularly under conditions of caloric restriction, involves a minor contribution of adenosine antagonism, but could mainly be explained by the inhibition of PDE activity. In view of current interest in the pharmacological stimulation of metabolic rate to assist the management of obesity with low-calorie regimens, the targeting of PDE activity is therefore a rational approach in the search for drugs that could potentiate sympathomimetic stimulation of metabolic rate.
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PMID:Potentiation of the thermogenic antiobesity effects of ephedrine by dietary methylxanthines: adenosine antagonism or phosphodiesterase inhibition? 143 97

In an attempt to determine the mechanism of insulin resistance in the presence of obesity, we examined effects of insulin on insulin-sensitive phosphodiesterase (PDE) in spontaneously diabetic KK mice. Isolated fat cells prepared from epididymal adipose tissue were incubated, with or without insulin, for 10 min. In the case of subcellular fractionation, only membrane-bound PDE was activated by insulin, as was noted in the case of rat fat cells. The specific activity was decreased in KK mice compared with control C57BL/6 mice. The dose-response curve, expressed as a percent of the maximal insulin effect, shifted to the right and the increase of ED50 indicated a decreased insulin sensitivity in the KK mice. The maximal insulin effect did not change, either when expressed as a percent of the basal enzyme activity or when expressed on a per cell basis. Specific binding of [125I]-insulin in fat cells increased in KK mice and curvilinear Scatchard plots showed an increase of the high-affinity sites. These data indicate that impairment of PDE activation in fat cells of KK mice relates to postreceptor defects and the uncoupling may result in a decreased sensitivity.
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PMID:Insulin resistance of fat cells from spontaneously diabetic KK mice. Analysis of insulin-sensitive phosphodiesterase. 299 83

An insulin-sensitive subcellular system was developed from rat adipocytes consisting of plasma membranes and mitochondria. Direct addition of insulin, concanavalin A or anti-insulin receptor antibody to this system resulted in the production of a mediator substance from the plasma membrane that caused dephosphorylation of the alpha subunit of pyruvate dehydrogenase in the mitochondria with concomitant activation of the enzyme. The mediator activated pyruvate dehydrogenase by activating the pyruvate dehydrogenase phosphatase and not by inhibiting the pyruvate dehydrogenase kinase. This was similar to the mechanism by which insulin causes activation of the enzyme in the intact cell. The insulin-sensitive mediator material from the adipocyte plasma membrane was acid-stable with a molecular weight of 1,000 to 1,500. Our laboratory has shown that the mediator that activates pyruvate dehydrogenase was present in intact adipocytes, hepatoma cells, and IM-9 lymphocytes. Insulin altered the amount or activity of the mediator consistent with the effect of the hormone on the cell. Other laboratories have shown similar effects on skeletal muscle and liver. We have shown the mediator to mimic insulin action on the low Km cyclic adenosine monophosphate (AMP) phosphodiesterase and the (calcium++-magnesium++)-adenosine triphosphatase (Ca++-Mg++)-ATPase of adipocyte plasma membranes in addition to pyruvate dehydrogenase. Other laboratories have shown the mediator to activate glycogen synthase. A body of direct and indirect evidence exists that demonstrates that more than one mediator exists. The chemical nature of the mediator is unknown but probably represents a new family of intracellular mediators of hormone action. These mediators may have clinical relevance in postreceptor defects of obesity and type II diabetes (noninsulin-dependent diabetes mellitus).
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PMID:The chemical mediators of insulin action: possible targets for postreceptor defects. 633 85

We have cloned the coding region of a human gene, whose predicted amino acid sequence shows 88% homology and higher correspondence in functional domains to the rat cGMP inhibited phosphodiesterase gene (PDE3A). In concordance with the expression data of the rat PDE3A gene, a 5.3-kb transcript of the human cGMP-inhibited phosphodiesterase gene is shown in Northern blot analysis to be highly expressed in adipose tissue. In addition, weaker expression is seen in pancreas, skeletal muscle, liver, placenta, and heart. cDNA clones from the homologue mouse gene were isolated and sequenced spanning a highly conserved region coding for a C-terminal located catalytic core region of this enzyme family. Using a genomic cosmid clone of human PDE3A for fluorescence in situ hybridization, the gene was mapped to chromosomal region 11p15 and regionally sublocalized by PCR on a human-hamster somatic hybrid-cell mapping panel to 11p15.1-p2. Based on comparative linkage data in mouse and rat this chromosomal location is suggested to contain genes involved in complex diseases like obesity and diabetes mellitus type II. Therefore, a possible involvement of the human PDE3A gene in these polygenic traits is discussed, taking into account the prominent role of the rat PDE3A gene product in the antilipolytic action of insulin in adipocytes.
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PMID:Molecular cloning and chromosomal assignment of the human homologue of the rat cGMP-inhibited phosphodiesterase 1 (PDE3A)--a gene involved in fat metabolism located at 11p 15.1. 892 98

Physiological investigation has demonstrated that the central nervous system monitors body composition and adjusts energy intake and expenditure to stabilize total adipose tissue mass. Genetic variations in the signalling molecules involved in this regulatory system account for the heritable component of body fat content. The application of molecular techniques to rodent models of Mendelian obesity has resulted in the characterization of five loci at which mutations produce an abnormal accumulation of body fat. The genes at these loci include agouti, which encodes a molecule that antagonizes the binding of alpha melanocyte-stimulating hormone to its receptor; fat, which encodes carboxypeptidase E; tubby, which encodes a putative phosphodiesterase; obese, which encodes a circulating satiety protein; and diabetes, which encodes the receptor for the obese gene product. A more detailed understanding of the functional interrelationships of these genes should lead to important new insights into the causes and potential therapies for human obesity.
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PMID:Obesity genes and the regulation of body fat content. 893 64

With a view of understanding the potential roles of phosphodiesterase (PDE)3 in the acceleration of atherosclerosis in diabetes, we have analyzed the in vivo levels of low Km cAMP PDE3 and PDE4 activities as well as PDE3A and PDE3B mRNA in a relevant animal model. The JCR:LA-cp rat is a unique strain that develops obesity, insulin resistance, and vasculopathy when homozygous for the autosomal recessive cp gene (cp/cp). Lean rats, bred (designated +/?) as a 2:1 mixture of animals that are heterozygous (cp/+) or homozygous normal (+/+), are metabolically normal. We find that PDE3 activity is the major low Km cAMP activity in the aorta of cp/cp rats and is approximately twofold higher than that in lean +/? rats. PDE3A mRNA levels in middle-aged cp/cp rats are also elevated, approximately threefold, compared with those of +/? rats or young 12-week-old cp/cp rats. Thus, in the aorta of atherosclerosis-prone insulin-resistant cp/cp rats, PDE3A gene expression is upregulated, resulting in significantly higher PDE3 activity. This upregulation of PDE3A mRNA levels was a rather unique phenomenon to the aorta of JCR:LA-cp rats compared with that in the aorta of other rat strains. This result is consistent with our hypothesis that an increased PDE3 activity in aortic smooth muscle cells may contribute to accelerated atherosclerosis in diabetes. Furthermore, determination of PDE3 activity and PDE3A and PDE3B mRNA levels in heart and white and brown fat tissues of JCR:LA-cp rats revealed that PDE3B mRNA and activity in white adipose tissue is downregulated in this diabetic animal model, and that PDE3A and PDE3B genes are tissue-specifically expressed and differentially regulated in aorta and adipose tissue, respectively, under hyperinsulinemic conditions.
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PMID:Cyclic nucleotide phosphodiesterase 3 expression in vivo: evidence for tissue-specific expression of phosphodiesterase 3A or 3B mRNA and activity in the aorta and adipose tissue of atherosclerosis-prone insulin-resistant rats. 964 39

Decreased lipolytic effect of catecholamines in adipose tissue has repeatedly been demonstrated in obesity and may be a cause of excess accumulation of body fat. However, the mechanisms behind this lipolysis defect are unclear. The role of hormone-sensitive lipase was examined using abdominal subcutaneous adipocytes from 34 obese drug-free and otherwise healthy males or females and 14 non-obese control subjects. The enzyme catalyzes the rate-limiting step of the lipolysis pathway. The maximum lipolytic capacity of fat cells was significantly decreased in obesity when measured using either a non-selective beta-adrenergic receptor agonist (isoprenaline) or a phosphodiesterase resistant cyclic AMP analogue (dibutyryl cyclic AMP). Likewise, enzyme activity, protein expression, and mRNA of hormone-sensitive lipase were significantly decreased in adipocytes of obese subjects. The findings were not influenced by age or gender. The data suggest that a decreased expression of hormone-sensitive lipase in subcutaneous fat cells, which in turn causes decreased enzyme function and impaired lipolytic capacity of adipocytes, is present in obesity. Impaired expression of the hormone-sensitive lipase gene might at least in part explain the enzyme defect.
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PMID:Decreased expression and function of adipocyte hormone-sensitive lipase in subcutaneous fat cells of obese subjects. 1055 9

In obese humans, insulin resistance is accompanied by elevated levels of plasma cell membrane glycoprotein (PC-1) and decreased insulin receptor (IR) tyrosine kinase activity in skeletal muscle. PC-1 overexpression inhibits IR tyrosine kinase and possibly other downstream signaling events. The rhesus monkey in captivity is susceptible to obesity with concomitant insulin resistance. In the present study we analyzed obese (n = 10, 29.4% +/- 1.2% body fat) and non-obese (n = 12, 19.4% +/- 1.9% body fat) rhesus monkeys. Glucose clearance during an euglycemic hyperinsulinemic (400 mU/m(2) body surface area/min) clamp was lower for the obese group (non-obese, 9.7 +/- 0.9; obese, 3.2 +/- 0.7 mg/kg fat-free mass [FFM]/min; P <.01). We performed vastus lateralis muscle biopsies prior to and during the clamp. We measured PC-1 levels in these muscle samples to determine whether PC-1 content is elevated in this primate model of insulin resistance. PC-1 levels were determined by assay of phosphodiesterase activity and specific PC-1 enzyme-linked immunosorbent assay (ELISA). In the obese group, both PC-1 content and activity were 2-fold higher than in the non-obese group (P <.05). In order to investigate the ability of insulin to stimulate IR signaling in vivo in these 2 groups of monkeys, we then measured tyrosine autophosphorylation of the IR by specific ELISA. The increase in IR autophosphorylation in the non-obese group was twice that of the obese group (fold increase over basal: non-obese, 3.7 +/- 0.3; obese, 1.9 +/- 0.6; P <.05). We conclude that insulin resistance secondary to obesity in rhesus monkeys is associated with increased levels of PC-1 and decreased IR signaling capacity in skeletal muscle.
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PMID:Elevated plasma cell membrane glycoprotein levels and diminished insulin receptor autophosphorylation in obese, insulin-resistant rhesus monkeys. 1191 55

Cardiovascular diseases represent a significant cause of morbidity and mortality in diabetes. Of the many animal models used in the study of non-insulin-dependent (type 2) diabetes, the JCR:LA-cp rat is unique in that it develops insulin resistance in the presence of obesity and manifests both peripheral and coronary vasculopathies. In this animal model, arterial vascular smooth muscle cells (VSMCs) from homozygous obese (cp/cp) rats, but not from age-matched healthy (+/+ or + /cp, collectively defined +/?) littermates, display an " activated" phenotype in vitro and in vivo and have an elevated level of cAMP phosphodiesterase (PDE) activity. In this report, we confirm that cp/cp rat aortic VSMCs have an elevated level of PDE3 activity and show that only particulate PDE3 (PDE3B) activity is elevated. In marked contrast to results obtained in + /? VSMCs, simultaneous activation of adenylyl cyclase and inhibition of PDE3 activity in cp/cp VSMCs synergistically increased cAMP. Although PDE3 inhibition did not potentiate the antimigratory effects of forskolin on +/? VSMCs, PDE3 inhibition did markedly potentiate the forskolin-induced inhibition of migration of cp/cp-derived VSMCs. Although PDE3 activity was elevated in cp/cp rat aortic VSMCs, levels of expression of cytosolic PDE3 (PDE3A) and PDE3B in +/? and cp/cp VSMCs, as well as activation of these enzymes following activation of the cAMP-protein kinase A signaling cascade, were not different. Our data are consistent with an increased role for PDE3 in regulating cAMP-dependent signaling in cp/cp VSMCs and identify PDE3 as a cellular activity potentially responsible for the phenotype of cp/cp VSMCs.
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PMID:Altered phosphodiesterase 3-mediated cAMP hydrolysis contributes to a hypermotile phenotype in obese JCR:LA-cp rat aortic vascular smooth muscle cells: implications for diabetes-associated cardiovascular disease. 1191 44

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