EC:3.5.4.4 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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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)

Blood samples from 509 Macushi and 623 Wapishana Amerindians of of Northern Brazil and Southern Guyana have been analyzed with reference to the occurrence of rare variants and genetic polymorphisms of the following 25 systems: (i) Erythrocyte enzymes: acid phosphatase-1, adenosine deaminase, adenylate kinase-k, carbonic anhydrase-1, carbonic anhydrase-2, esterase A1,2,3, esterase D, galactose-1-phosphate uridyltransferase, isocitrate dehydrogenase, lactate dehydrogenase, malate dehydrogenase, nucleoside phosphorylase, peptidase A, peptidase B, phosphoglucomutase 1, phosphoglucomutase 2, phosphogluconate dehydrogenase, phosphohexoseisomerase, triosephosphate isomerase and (ii) Serum proteins: albumin, ceruloplasmin, haptoglobin, hemoglobin A2 and transferrin. Fifteen different rare variants were detected, involving 11 of these systems. In addition, a previously undescribed variant of ESA 1,2,3 which achieves polymorphic proportions in both these tribes is described. Excluding this variant, the frequency of rare variants is 1.1/1000 in 12510 determinations in the Macushi and 4.7/1000 in 15396 determinations in the Wapishana. The ESA 1,2,3 polymorphism was not observed in 382 Makiritare, 232 Yanomama, 146 Piaroa, 404 Cayapo, 190 Kraho and 112 Moro. Irregularities in the intratribal distribution of this polymorphism in the Macushi and Wapishana render a decision as to the tribe of origin impossible at present. Gene frequencies are also given for previously described polymorphisms of 5 systems: haptoglobin, phosphoglucomutase 1, erythrocyte acid phosphatase, esterase D, and galactose-1-phosphate-uridyl-transferase.
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PMID:Genetic studies of the Macushi and Wapishana Indians. I. Rare genetic variants and a "private polymorphism' of esterase A. 87 Apr 12

To investigate the inhibitory effect of adenosine released by endothelium on neutrophil superoxide (O2-) production, we treated confluent monolayers of cultured human umbilical vein endothelial cells with the enzyme adenosine deaminase, and then added human neutrophils. Superoxide (O2-) production by human neutrophils stimulated with 10(-6) M formyl-methionyl-leucyl-phenylalanine was inhibited by 49% in the presence of a confluent monolayer of human umbilical vein endothelial cells (5.1 +/- 0.1 versus 2.6 +/- 0.3 nmols O2-/10(6) neutrophils). Addition of 0.25 U/ml adenosine deaminase to neutrophils plus endothelial cells restored formyl-methionyl-leucyl-phenylalanine-stimulated neutrophil superoxide production to the level seen with neutrophils alone. Deoxycoformycin (10(-4) M), an inhibitor of adenosine deaminase activity, prevented the increase in superoxide production associated with adenosine deaminase addition. The adenosine analogue 5'-(N-ethylcarboxamido)- adenosine (3 x 10(-4) M) caused increased inhibition of formyl-methionyl-leucylphenylalanine-stimulated superoxide release by neutrophils in the presence of endothelial cells and prevented neutrophil-mediated endothelial cell damage, as measured by release of 3H-2-deoxy-D-glucose. Pairing 2-chloroadenosine (10(-5) M) or 5'-(N-ethylcarboxamido)-adenosine (3 x 10(-4) M) with a cyclic adenosine monophosphate phosphodiesterase inhibitor, 3-isobutyl-l-methyl-xanthine (10-4 M), produced greater inhibition of neutrophil superoxide production than occurred with either compound alone. The results support the hypothesis that vascular endothelial cells protect themselves from neutrophil attack by releasing adenosine to inhibit superoxide production.
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PMID:Inhibition of neutrophil superoxide production by adenosine released from vascular endothelial cells. 171 81

The effects of adenosine and the nonmetabolizable adenosine analogue N6-(L-2-phenylisopropyl)adenosine (PIA) on glucose transport or metabolism were determined in purified myocardial sarcolemmal vesicles, isolated cardiocytes, and perfused hearts. Adenosine (100 microM) did not affect hexose transport in myocytes. Also, adenosine deaminase, added to metabolize adenosine to inosine, did not alter transport of hexose into myocytes regardless of whether or not insulin was present. In contrast, PIA effectively inhibited 3-O-methyl-D-glucose uptake in myocytes even during insulin stimulation. PIA inhibited D-glucose-specific transport in both rat and bovine cardiac sarcolemmal vesicles (Ki = 26 microM at [D-glucose] = 5 mM). However, insulin did not affect glucose transport in sarcolemmal vesicles, which implies that receptor-coupled processes probably are not intact in this preparation. Thus, inhibition of PIA may not be receptor mediated. Also, PIA inhibited binding of cytochalasin B to bovine cardiac sarcolemmal vesicles, which supports the idea that PIA inhibits glucose flux by binding to the glucose transporter. To determine if adenosine altered glucose metabolism rather than transport, we measured the rate of 3H2O production from metabolism of D-[2-3H]glucose in paced rat hearts ([D-glucose] = 5.5 mM, [pyruvate] = 0.2 mM) perfused with a range of PIA or adenosine concentrations with or without 0.01 microM insulin. Adenosine (0.01-100 microM) in the presence or absence of insulin increased coronary flow but did not change glycolytic rates. Similar results were obtained with PIA (no insulin) rather than adenosine in the perfusate. However, with glucose as the only exogenous substrate, 100 microM PIA inhibited glycolysis by approximately 50%.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Myocardial glucose utilization. Failure of adenosine to alter it and inhibition by the adenosine analogue N6-(L-2-phenylisopropyl)adenosine. 187 73

Incubation of rat adipocytes with 1 microM glucagon plus adenosine deaminase (5 micrograms/ml) inhibited maximally insulin-stimulated 3-O-methyl-D-glucose (MeGlc) transport by approximately 70%, concomitant with 30% and 55% decreases in insulin binding and cellular ATP, respectively. In contrast, under conditions where cellular ATP levels are well preserved (i.e. high albumin concentration in the medium), the inhibition of transport was reduced to about 30%, but that of insulin binding was not. Because depletion of the cellular ATP level by more than 60% by metabolic inhibitors induced 40% or more inhibition of insulin-stimulated MeGlc transport, the greater inhibition of the transport with the low albumin concentration appears to be caused in part by the secondary effect of ATP loss. The relationship between the amount of cell-bound insulin and hormone-stimulated transport activity showed that glucagon does not modulate insulin action at the step of insulin binding to its receptors. Furthermore, glucagon suppressed insulin-stimulated MeGlc transport, mainly through an attenuation of the hormone-induced increase in maximum velocity. The data show that glucagon modulates the process of signal transduction of insulin action. However, the possibility that glucagon directly modulates the process of translocation or the intrinsic activity of the glucose transporters cannot be eliminated.
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PMID:Glucagon inhibits insulin activation of glucose transport in rat adipocytes mainly through a postbinding process. 220 31

Pentostatin, an unusual nucleoside of natural origin, has been used for the treatment of hairy cell leukemia, as an immunosuppressant agent, and as an inhibitor of adenosine deaminase. The studies of the physicochemical properties and solution stability of pentostatin are important to the development of a parenteral formulation for extensive preclinical and clinical testing. Pentostatin displayed apparent pKa values at 25 +/- 0.1 degree C and ionic strength of 0.15 M of 2.03 +/- 0.03 and 5.57 +/- 0.14 (spectrophotometric) and 5.50 +/- 0.02 (potentiometric) for N1 and the amidine nitrogen in the seven-membered ring, respectively, which are the most likely protonation sites. The rates of degradation of pentostatin were determined as a function of pH, buffer concentration, and temperature. In the pH range 1.0-4.0, pentostatin undergoes acid-catalyzed glycosidic cleavage leading to the formation of the base compound, and 2-deoxyribose. A carbonium ion mechanism in which C-N bond cleavage was the rate-determining step was consistent with the data. In the pH range 6.5-10.5, the imine bond at C5 position in pentostatin is hydrolyzed to form the corresponding formamide. Pentostatin hydrolysis in this pH range was independent of pH. At pH greater than 11, pentostatin decomposes to nonchromophoric products probably through multiple-step base-catalyzed hydrolytic mechanisms. Pentostatin appears to be quite stable after reconstitution of a lyophilized experimental dosage form. Care must be taken if pentostatin is extensively diluted with 5% dextrose in water, as pentostatin stability is compromised at pH values less than 5.
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PMID:Chemical stability of pentostatin (NSC-218321), a cytotoxic and immunosuppressant agent. 236 13

This paper examines the modulation of insulin-stimulated glucose transport activity in rat adipose cells by ligands for receptors (R) that mediate stimulation (Rs; lipolytic) or inhibition (Ri; antilipolytic) of adenylate cyclase. The changes in glucose transport activity and cAMP, as assessed by 3-O-methylglucose uptake and (-/+) cAMP-dependent protein kinase (A-kinase) activity ratios, respectively, were monitored under conditions that maintain steady-state A-kinase activity ratios (Honnor, R. C., Dhillon, G. S., and Londos, C. (1985) J. Biol. Chem. 260, 15122-15129). Removal of endogenous adenosine with adenosine deaminase decreased insulin-stimulated glucose transport activity by approximately 30%, which was prevented or restored with Ri agonists such as phenylisopropyladenosine, nicotinic acid, and prostaglandin E1. These changes in transport activity were not accompanied by changes in A-kinase activity ratios, indicating that Ri-mediated effects on transport are independent of cAMP changes. Addition of an Rs ligand, isoproterenol, in the presence of adenosine increased kinase activity but did not change glucose transport activity. Conversely, upon removal of adenosine, addition of Rs ligands such as isoproterenol, adrenocorticotropic hormone, or glucagon strongly inhibited transport (approximately 50%) and stimulated kinase activity. However, subsequent addition of phenylisopropyladenosine nearly restored transport activity without alteration of A-kinase activity. These data and additional kinetic experiments suggest that Rs-mediated glucose transport modulations are also independent of cAMP. The interchangeability of ligands for both Rs and Ri receptors in modulating transport activity suggests that these cAMP-independent effects are mediated by the stimulatory (Ns) and inhibitory (Ni) guanyl nucleotide-binding regulatory proteins of adenylate cyclase. All Rs-and Ri-induced changes in transport activity occurred without a change in glucose transporter distribution, as assessed by D-glucose-inhibitable cytochalasin B binding, suggesting that Rs and Ri ligands modulate the intrinsic activity of the glucose transporter present in the plasma membrane.
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PMID:Regulation of insulin-stimulated glucose transport in the isolated rat adipocyte. cAMP-independent effects of lipolytic and antilipolytic agents. 302 4

Ecto-5'-nucleotidase (ecto-5'-NU) of platelets was enhanced by concanavalin A (Con A). This effect of Con A was antagonized by alpha-methyl-D-mannose, a specific antagonist of Con A binding to glycoprotein. Coformycin, an adenosine deaminase inhibitor, did not change the effect of Con A on the ecto-5'-NU. Uptake of adenosine by platelets was not affected by Con A. It was suggested that the ecto-5'-NU of platelet might be a direct and primary site of action of Con A.
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PMID:Effect of concanavalin A on 5'-nucleotidase activity of rabbit blood platelets. 303 67

The effect of insulin and factors which have insulin-like activity on the kinetic parameters of 3-O-methyl-D-glucose (MeGlc) transport in rat adipocytes were assessed. Carrier-mediated uptake of MeGlc was estimated by the difference in the amounts of [14C]MeGlc and L-[3H]glucose taken up in cells under equilibrium exchange conditions at 37 degrees C. The Km and Vmax values in basal cells were 17.4 mM and 0.24 nmol/10(6) cells/s, respectively. Removal of endogenous adenosine by adenosine deaminase resulted in a 26% decrease in the basal rate due to a slight increase in the Km (19.6 mM) and a decrease in the Vmax value (0.20 nmol/10(6) cells/s). The maximum concentration (10 nM) of insulin decreased the Km to approximately one-half of the basal (7.1 mM) concomitant with an 8.5-fold increase in the Vmax value (2.04 nmol/10(6) cells/s). Submaximal concentrations (50 and 150 pM) of insulin, N6-phenylisopropyladenosine (1 microM), mechanical agitation of cells by centrifugal force (160 x g), low temperature (15 degrees C), 12-O-tetradecanoylphorbol-13-acetate (1 microM), and hydrogen peroxide (10 mM) all decreased the basal Km value to a range of 13.5-7.3 mM, concomitant with a 1.7-7.4-fold increase in the Vmax. A possible explanation for the alterations in the kinetic parameters may be that insulin and other factors cause the translocation of the mobile low-Km glucose transporters from an intracellular site to the cell surface, where the stationary high-Km transporters are located. Thus, when the Km and Vmax values of the hypothetical high-Km transporters were assumed to be 20 mM and 0.20 nmol/10(6) cells/s, respectively, and the Km of the low-Km transporters was assumed to be 7 mM, the theoretical Km decreased from 20 to 7.5 mM as the Vmax of the low-Km transporters increased from near 0 to 2.0 nmol/10(6) cells/s. The relation between empirical Km and Vmax values as affected by several agents and conditions followed closely the relation predicted by the above two-transporter model.
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PMID:Reassessment of the translocation hypothesis by kinetic studies on hexose transport in isolated rat adipocytes. 304 14

The human erythrocyte membrane carriers for hexoses and nucleosides have several structural features in common. In order to assess functional similarities, the effects of adenosine derivatives on hexose transport and cytochalasin B binding sites were studied. Adenosine inhibited zero-trans uptake of 3-O-methylglucose half-maximally at 5 mM, while more hydrophobic adenosine deaminase-resistant derivatives were ten- to 20-fold more potent transport inhibitors. However, degradation of adenosine accounted for very little of this difference in potency. Hexose transport was rapidly inhibited by N6-(L-2-phenylisopropyl)adenosine at 5 degrees C in a dose-dependent fashion (EC50 = 240 microM), to lower the transport Vmax without affecting the Km. A direct interaction with the carrier protein was further indicated by the finding that N6-(L-2-phenylisopropyl)adenosine competitively inhibited [3H]cytochalasin B binding to erythrocytes (Ki = 143 microM) and decreased [3H]cytochalasin B photolabeling of hexose carriers in erythrocyte ghosts. The cross-reactivity of adenosine and several of its derivatives with the hexose carrier suggests further homologies between the carriers for hexoses and nucleosides, possibly related to their ability to transport hydrophilic molecules through the lipid core of the plasma membrane.
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PMID:Inhibition of hexose transport by adenosine derivatives in human erythrocytes. 337 99

The interaction between catecholamines and insulin in regulating glucose transport in isolated rat adipose cells has been evaluated. In the absence of insulin, 1 microM isoproterenol stimulates 3-O-methylglucose transport approximately 2-fold. However, isoproterenol in combination with adenosine deaminase inhibits glucose transport activity approximately 60%. N6-Phenylisopropyladenosine, a nonmetabolizable adenosine analogue, substantially reverses this inhibitory effect and actually stimulates glucose transport activity approximately 2-fold in the absence of isoproterenol. Dibutyryl cAMP inhibits glucose transport activity approximately 75% regardless of adenosine deaminase. While none of these agents significantly influences the basal concentration of plasma membrane glucose transporters, as assessed by specific D-glucose-inhibitable cytochalasin B binding, isoproterenol or dibutyryl cAMP in combination with adenosine deaminase reduces that in the low density microsomes 19 and 58%, respectively. In the presence of insulin, both isoproterenol and adenosine deaminase alone inhibit glucose transport activity approximately 25%. However, only the latter is accompanied by a corresponding decrease in the insulin-stimulated concentration of plasma membrane glucose transporters. Together, isoproterenol and adenosine deaminase inhibit insulin-stimulated glucose transport activity approximately 75%, even in the presence of 5 mM glucose to maintain cellular ATP levels. A similar inhibition is observed with dibutyryl cAMP. However, these agents decrease the insulin-stimulated concentration of plasma membrane glucose transporters only approximately 45%. Nevertheless, all of these inhibitory effects occur through decreases in the transport Vmax. In addition, N6-phenylisopropyladenosine partially reverses the inhibitory effects induced by the presence of adenosine deaminase. These results suggest that catecholamines counter-regulate basal and insulin-stimulated glucose transport in rat adipose cells through a cAMP-mediated mechanism, but only in part by modulating the translocation of glucose transporters.
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PMID:Counter-regulation of insulin-stimulated glucose transport by catecholamines in the isolated rat adipose cell. 608 11

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