EC:3.5.4.4 - FACTA Search

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Query: EC:3.5.4.4 (adenosine deaminase)
5,136 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The release of adenosine by isolated rat adipocytes into the incubation medium was studied in relation to fat cell size and concentration. Incubations were carried out for 60 min at 37 degrees C in Krebs-Ringer bicarbonate-albumin medium containing 6 mM glucose. 2'-Deoxycoformycin was added to inhibit endogenous adenosine deaminase activity (maximal suppression was achieved at 0.8 microM concentration of the inhibitor). The data show that (a) the amount of adenosine released into the medium was similar for the first and second 30-min incubation periods; (b) increasing adipocyte concentration markedly inhibited adenosine release; and (c) large fat cells (volume greater than 300 pl) released significantly more adenosine (per fat cell) into the medium than smaller fat cells (volume less than 180 pl) when incubated at concentrations of less than or equal to 350,000 cells/ml. Above this cell concentration, differences between adenosine release and cell size were not noted. Adenosine release by isolated rat adipocytes appears to be a precisely regulated process which is exquisitly sensitive to the number of fat cells in the incubation medium and, to a certain extent, to the adipocyte size.
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PMID:Adenosine release from isolated rat adipocytes: influence of fat cell concentration and cell size. 351 50

The regulation of the glucose transport system by catecholamines and insulin has been studied in isolated rat cardiomyocytes. In the basal state, 1-isoproterenol exhibited a biphasic concentration-dependent regulation of 3-O-methylglucose transport. At low concentrations (less than 10 nM), isoproterenol induced a maximal inhibition of 65-70% of the basal rates, while at higher concentrations (greater than 10 nM) a 25-70% stimulation of transport was observed. In the presence of adenosine deaminase, the inhibition of isoproterenol at low doses was attenuated. No effect of adenosine deaminase was observed on the stimulation of transport at high doses of isoproterenol. The inhibitory effect of isoproterenol returned when N6-phenylisopropyladenosine (a non-metabolizable analog of adenosine) was included along with adenosine deaminase. Dibutyryl cAMP and forskolin both inhibited basal transport rates. In the presence of maximally stimulating concentrations of insulin, cardiomyocyte 3-O-methylglucose transport was generally elevated 200-300% above basal levels. In the presence of isoproterenol, insulin stimulation was inhibited at both high and low concentrations of catecholamine, with maximum inhibition occurring at the lowest concentrations tested. When cells were incubated with both adenosine deaminase and isoproterenol, the inhibition of the insulin response was greater at all concentrations of catecholamine and was almost completely blocked at isoproterenol concentrations of 10 nM or less. Dibutyryl cAMP inhibited the insulin response to within 10% of basal transport levels, while forskolin completely inhibited all transport activity in the presence of insulin. These results suggest that catecholamines regulate basal and insulin-stimulated glucose transport via both cAMP-dependent and cAMP-independent mechanisms and that this regulation is modulated in the presence of extracellular adenosine.
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PMID:Interactions of insulin, catecholamines and adenosine in the regulation of glucose transport in isolated rat cardiac myocytes. 351 11

In the anterogradely perfused rat heart, physiological concentrations of insulin stimulated the rates and efficiencies of protein synthesis in both ventricles and atria. Half-maximal stimulation of ventricular protein synthesis was obtained at about 35 microU/ml. Glucose uptake and lactate release were also stimulated over this range of insulin concentrations. Adenosine deaminase increased protein synthesis rates in ventricles and atria in the presence of submaximally stimulating insulin concentrations (40 microU/ml) but had no effect in the absence of insulin or in the presence of maximally stimulating concentrations. The insulin sensitivities of glucose uptake and lactate release were also increased by adenosine deaminase. Adenosine may be a modulator of insulin sensitivity in the heart.
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PMID:Stimulation of protein synthesis, glucose uptake and lactate output by insulin and adenosine deaminase in the rat heart. 351 83

We have investigated the effects of adenosine on the stimulation of glucose oxidation and lipogenesis by oxytocin and insulin in rat epididymal adipocytes. The addition of adenosine deaminase (1 U/ml) to the assay medium reduced the maximal oxytocin response (glucose oxidation and lipogenesis) to between 25 and 50% of the maximum response in control cells. The maximal response to insulin was not appreciably affected under these conditions. The addition of adenosine (10 or 30 microM) increased the cell sensitivity to oxytocin by elevating the maximum rate of oxytocin-stimulated glucose metabolism. Adenosine also increased the cell sensitivity to insulin by decreasing its ED50. A change in ED50, however, was observed only when control or adenosine-treated cells were compared to adenosine deaminase-treated cells; but not when control and adenosine-treated cells were compared. On its own, adenosine also caused an appreciable increase in both glucose oxidation and lipogenesis (ED50 approximately equal to 3 microM adenosine). The difference in the effect of adenosine on oxytocin action, compared with the effect on insulin action, points to differences in the mechanisms by which insulin and oxytocin stimulate glucose metabolism in adipocytes.
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PMID:Adenosine modulation of fat cell responsiveness to insulin and oxytocin. 354 88

Intravenous norepinephrine increases glycerol release and blood flow in adipose tissue. The vasodilation may be an indirect effect of norepinephrine through the production of adenosine. Adenosine increases glucose uptake and inhibits lipolysis in vitro. To test whether adenosine regulates blood flow and/or metabolism in vivo, adenosine deaminase (ADA) was infused intra-arterially into the inguinal fat pads of anesthetized dogs. In unstimulated tissues, ADA (n = 7) significantly increased vascular resistance and significantly decreased glucose uptake compared with the effects of a control (boiled deaminase, n = 6) infusion. ADA completely blocked the norepinephrine-induced vasodilation (n = 6). No potentiation of basal or catecholamine-stimulated lipolysis was observed with ADA. The presence of ADA in the interstitial space was verified by analysis of lymph effluents. Interstitial levels of ADA were inversely correlated with the tissue contents of adenosine. These data support the hypothesis that adenosine is a regulator of blood flow in basal and stimulated adipose tissue. Adenosine also appears to regulate glucose uptake, but not lipolysis, in vivo.
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PMID:Adenosine regulates blood flow and glucose uptake in adipose tissue of dogs. 371 62

The effect of glucose on lipolytic regulation was studied in isolated human adipocytes. Glucose enhanced adipocyte glycerol release in the presence and absence of the beta-adrenergic agent ritodrine by 150-200% of control rates. The glucose effect was maximal at just greater than 1 mM glucose and could not be attributed to prevention of a time-dependent decline in lipolysis. Glucose not only increased lipolytic stimulation at each of several concentrations of ritodrine but also enhanced the sensitivity to stimulation at low concentrations of the agent. Ritodrine-stimulated lipolysis was inhibited by insulin by 50-60%; although glucose increased absolute rates of lipolysis, it did not affect the relative inhibition of lipolysis by insulin or the sensitivity to the hormone. In investigating a possible cause of the glucose effect on lipolysis, it was found that the addition of adenosine deaminase increased lipolytic rates in the absence of glucose and blunted the relative stimulation of lipolysis by glucose, the latter implicating extracellular adenosine in the mechanism of the glucose effect.
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PMID:Potentiation by glucose of lipolytic responsiveness of human adipocytes. 372 Oct 62

To test whether extracellular adenosine participates in the local regulation of intestinal blood flow during nutrient absorption, the serosa of the jejunum was continuously suffused with adenosine deaminase (7 micrograms protein/ml) or theophylline (10(-4) M) in Ringer's solution. Using video microscopy, blood flow was calculated in submucosal arterioles from diameter and red cell velocity measurements. After a steady-state baseline, oleic acid (20 mM) + glucose (56 mM) were added to a bile salt solution suffusing the mucosa. Baseline arteriolar diameters and blood flows were 52 +/- 2 micron and 20 +/- 2 nl/sec with the serosal suffusate containing Ringer's; these values were not significantly altered by theophylline or deaminase treatment. During suffusion of the mucosa with a nutrient solution, diameter and blood flow transiently increased and these responses were not altered by deaminase or theophylline. Thereafter, diameter and blood flow stabilized at lower values for the duration of absorption. Diameter and blood flow were increased to 111 +/- 1% and 134 +/- 5% of control during absorption with Ringer's; the corresponding values were significantly lower with deaminase or theophylline. After absorption, diameter and blood flow stabilized near baseline with Ringer's within 7-12 minutes; the corresponding values were significantly lower with deaminase or theophylline for at least 30 minutes. Since deaminase and theophylline produced similar effects on absorptive hyperemia, adenosine might participate with other factors in the local regulation of that response. Adenosine applied to the serosa caused dose-dependent increases in calculated blood flow with a threshold near 10(-5) M and a maximum near 10(-3) M. In contrast, even 10(-2) M adenosine in the mucosal suffusate did not increase blood flow above baseline.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Possible role for adenosine in local regulation of absorptive hyperemia in rat intestine. 379 85

2-Deoxyglucose uptake (3 min) and 3-O-methylglucose transport (2 s) was measured in rat adipocytes preincubated with 5 microM epinephrine plus adenosine deaminase as described by Green (Green, A. (1983) FEBS Lett. 152, 261-264). 2-Deoxyglucose uptake was about 95% depressed in insulin-treated, but not in 'basal', cells preincubated with epinephrine plus adenosine deaminase for 60 min in broad agreement with Green's report. However, this depression was caused by a decrease in sugar phosphorylation rather than transport. In similarly incubated cells, transport of 3-O-methylglucose, a sugar analogue not phosphorylated in the adipocytes, was not affected by catecholamine plus adenosine deaminase. However, a decrease in transport of about 60% was observed both in the absence and the presence of insulin when the albumin concentration was high enough and the cell concentration low enough to prevent accumulation of free fatty acids in the medium. In addition, the insulin sensitivity with regard to hexose transport was markedly reduced. Transport was approximately doubled in cells incubated with 5 microM epinephrine in the absence of adenosine deaminase. Thus, epinephrine at a high concentration stimulates hexose transport in the absence of adenosine deaminase (presence of adenosine) whereas it inhibits both basal and insulin-stimulated transport in the presence of adenosine deaminase (absence of adenosine).
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PMID:The effect of catecholamines and adenosine deaminase on the glucose transport system in rat adipocytes. 389 Sep 59

The effects of prostaglandin E2 were studied on glucose metabolism (3-O-methylglucose transport, CO2 production and lipogenesis) in human adipocytes. Initially, the effects of endogenously produced adenosine and prostaglandins were indirectly demonstrated by using adenosine deaminase and indomethacin in the incubations. From these studies it was found that adenosine deaminase (5 micrograms/ml) had a pronounced effect on adipocyte glucose metabolism in vitro. In the basal (nonhormonal-stimulated) state, glucose transport, CO2 production and lipogenesis were inhibited by about 30% (P less than 0.05). Furthermore, adenosine deaminase significantly inhibited the isoproterenol- and insulin-stimulated CO2 production and lipogenesis (P less than 0.01). Indomethacin (50 microM) had a consistently inhibitory effect on the insulin-stimulated CO2 production (P less than 0.05), whereas indomethacin had no significant effects on basal or isoproterenol-stimulated glucose metabolism. In contrast to the relatively minor effect of endogenous prostaglandins, the addition of exogenous prostaglandin E2 significantly stimulated the glucose transport, glucose oxidation and lipogenesis in human adipocytes, especially in the presence of adenosine deaminase. Half-maximal stimulation was obtained at prostaglandin E2 concentrations of 2.2, 0.8 and 0.8 nM, respectively. The effect of prostaglandin E2 was specific, since the structurally related prostaglandin, prostaglandin F2 alpha, had practically no effect on glucose metabolism. The maximal effect of prostaglandin E2 (1 microM) on glucose metabolism was 30-35% of the maximal insulin (1 nM) effect. When insulin and prostaglandin E2 were added together, the effect of prostaglandin E2 on glucose metabolism was additive at all insulin concentrations tested.
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PMID:Effects of prostaglandin E2, indomethacin and adenosine deaminase on basal and insulin-stimulated glucose metabolism in human adipocytes. 391 86

The exact pathway whereby the initial catabolism of the adenine nucleotides proceeds from AMP and the possibility of a recycling of adenosine were investigated in human erythrocytes. Adenine nucleotide catabolism, reflected by the production of hypoxanthine, is very slow under physiologic conditions and can be greatly increased by suppression of glucose or alkalinization of the medium. Experiments with inhibitors of adenosine deaminase and adenosine kinase demonstrated that under physiologic conditions the initial catabolism of AMP proceeds by way of a deamination of AMP, followed by dephosphorylation of inosine monophosphate, and that no recycling occurs between AMP and adenosine. Under glucose deprivation, approximately 75% of the 20-fold increase of the catabolism of the adenine nucleotides proceeded by way of a dephosphorylation of AMP followed by deamination of adenosine, and a small recycling of this nucleoside could be evidenced. Inhibition of adenosine transport showed that the dephosphorylation of AMP occurred intracellularly. When the incubation medium was alkalinized in the presence of glucose, the 15-fold increase in the conversion of AMP to hypoxanthine proceeded exclusively by way of AMP deaminase but a small recycling of adenosine could also be evidenced. The threefold elevation of intraerythrocytic inorganic phosphate (Pi) during glucose deprivation and its 50% decrease during alkalinization as well as experiments in which extracellular Pi was modified, indicate that the dephosphorylation of red blood cell AMP is mainly responsive to variations of AMP, whereas its deamination is more sensitive to Pi.
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PMID:Pathways of adenine nucleotide catabolism in erythrocytes. 394 80

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