EC:3.6.1.3 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.6.1.3 (ATPase)
65,361 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Changes in the erythrocyte membrane cation carrier following lithium ingestion in normal human subjects were studied; ouabain sensitive potassium influx fell significantly during the lithium treated phase. Lithium was fed to rats and no change in erythrocyte Na-K ATPase was shown. These findings contrast with studies of lithium in manic depressive psychosis. The fluctuations in the erythrocyte membrane cation carrier were studied in 5 normal subjects over 12 weeks and the correlations between the parameters calculated. The erythrocyte sodium concentration correlated positively with the ouabain sensitive potassium influx. This too contrasts with findings in manic depressive psychosis.
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PMID:Lithium and erythrocyte membrane cation carrier studies in normal and manic depressive subjects. 14 80

Platelets were examined to enable a simultaneous investigation to be made of indolylamine and electrolyte metabolism in affective disorder. No significant differences were detected in either platelet membrane ATPase or adenyl cyclase specific activity in any of the groups of patients studied, when compared with appropriate controls. A reduced Vmax and y for the 5-hydroxy-tryptamine uptake process into platelets was observed in both unipolar and bipolar depressed groups. The Km for this process was not significantly different in any of the patients from that found in control subjects. Lithium therapy was shown not to influence significantly any of the platelet parameters examined. It is suggested that membrane enzyme changes found in some peripheral cells in patients suffering from affective disorder, i.e. reduced Na+ + K+ - ATPase activity in erythrocytes in depression, is not common to all peripheral cells and may or may not reflect central nervous system changes.
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PMID:Studies on human blood platelets in affective disorder. 15 82

It has recently been demonstrated that both Tl+ and Li+ produce concentration- and time-dependent positive inotropic effects in guinea-pig atrial preparations although Tl+ inhibits and Li+ stimulates isolated Na+,K+-ATPase in vitro. In order to elucidate the mechanism of the positive inotropic actions of these cations, the effects of Tl+ and Li+ on sodium pump activity were studied. Active 86Rb uptake in guinea-pig ventricular slices, an estimate of sodium pump activity, was highly sensitive to the inhibitory effect of the cardiac glycosides. Preincubation of slices with Tl+ caused a dose- and time-dependent inhibition of active 86Rb uptake. Similar concentration- and time-dependent inhibition of active 86Rb uptake was observed when Na+ in a Krebs-Henseleit solution was partially replaced with Li+. Lithium, however, stimulated a partially purified Na+,K+-ATPase in vitro. During heart slice incubation, Tl+ and Li+ accumulated in a time-dependent manner. This accumulation was not readily reversible when slices were transferred into Tl+- or Li+-free solutions. It appears that the inhibition of sodium pump activity is related to the positive inotropic action of these cations.
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PMID:Effects of lithium and thallous ions on sodium pump activity in the guinea-pig heart and their relationship to the positive inotropic action. 21 86

We have studied extracellular ionic changes induced by iontophoretic application of excitatory amino acids in rat hippocampal slices. In contrast to kinetics of changes in [Ca2+]o, kinetics of changes in [K+]o, [Na+]o, [Cl-]o as well as in extracellular space size were comparable for different glutamate receptor agonists. Thus, alpha-amino-3-hydroxy-5-methylisoxazolepropionic acid (AMPA), quisqualate (quis), and kainate caused reductions in [Ca2+]o followed by an increase of [Ca2+]o above baseline, whereas glutamate, aspartate, N-methyl-D-aspartate (NMDA), and DL-homocysteic acid caused only reductions in [Ca2+]o. After blocking the NMDA receptors with ketamine and 2-amino-5- phosphonovaleric acid (2-APV), glutamate-induced decreases in [Ca2+]o were followed by an overshoot. Reduction of the transmembrane Na+ gradient by lowering [Na+]o, blocking of the Na(+)-K+ ATPase by lowering [K+]o, and application of ouabain blocked the overshoots after quis application, whereas vanadate, a blocker of the Ca(2+)-Mg2+ ATPase, had no effects. Lithium enhanced the reductions in [Ca2+]o and blocked the overshoots. Amiloride also reduced the overshoots. All organic Ca2+ entry blockers diminished reductions of [Ca2+]o but increased the overshoots. Inorganic Ca2+ antagonists had variable effects. Ni2+ had similar effects as the organic Ca2+ entry blockers while Cd2+ reduced both the [Ca2+]o decreases as well as the subsequent overshoots. Co2+ had initially a similar action as Ni2+. With prolonged application, [Ca2+]o decreases became augmented and, during wash, overshoots could no longer be elicited. We suggest that the overshoots in [Ca2+]o are due to a combined effect of extracellular space shrinkage and activation of the Na+/Ca2+ exchangers. This would imply that NMDA receptor activation blocks extrusion of Ca2+ from the cells. We tested the hypothesis that quis-induced intracellular Ca2+ release and extrusion of Ca2+ from the cells contributed to the overshoots. Dantrolene was without effect on the quis-induced signals, while ryanodine reduced the overshoots. Caffeine on the other hand diminished the [Ca2+]o decreases with no effects on the overshoots. To test for possible second messenger routes by which NMDA receptor activation might slow Ca2+ extrusion from cells, we investigated the effects of arachidonic acid and N-monomethyl-D- arginine on the quis-induced signals. While these agents reduced decreases in [Ca2+]o, they had no clear effects on the overshoots. Thus a possible route by which NMDA receptor activation may affect Ca2+ extrusion from cells has still to be elucidated.
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PMID:Pharmacological properties of excitatory amino acid induced changes in extracellular calcium concentration in rat hippocampal slices. 129 71

Calcium functions as an intracellular second messenger, transducing a variety of hormonal, electrical, and mechanical stimuli by activating a wide range of enzymes. There is evidence, ranging from definitive to strongly presumptive in quality, that lithium can alter many calcium-dependent processes. The list of enzyme systems dependent on calcium and altered by lithium includes adenylate cyclase, glycogen synthase, inositol-1-phosphatase, and calcium adenosine triphosphatase (ATPase). Lithium also interferes with calcium regulation of receptor sensitivity, parathyroid hormone release, microtubule structure, and other systems. All of the neural mechanisms that are hypothesized to explain various psychopharmacological treatments of bipolar illness involve functions that are critically controlled by calcium. Moreover, in every instance, a known action of lithium on calcium function could account for lithium's therapeutic or prophylactic results. From these considerations the dual hypotheses emerge that bipolar illnesses arise from disorders in calcium-regulated functions and that lithium acts by reversing or counterbalancing the effects of these calcium dysfunctions.
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PMID:Lithium mechanisms in bipolar illness and altered intracellular calcium functions. 242 87

1. We have measured cation transport in vivo in seven healthy volunteers under control conditions and after they had taken lithium carbonate for 21 days in doses which maintained the serum lithium concentration in the range 0.6-0.8 mmol/l. 2. We have measured cation transport in vivo after the administration of an oral load of rubidium chloride, and have found that, although intra-erythrocytic concentrations of rubidium were significantly lower 1 h after the administration of rubidium when the subjects were taking lithium, there was a significant increase in the rate of uptake of rubidium into the erythrocytes over the subsequent period of the test, suggesting a direct stimulation of sodium, potassium-activated adenosine triphosphatase by lithium. 3. Lithium administration did not affect the plasma concentration versus time profile of rubidium after the rubidium load, implying that the lithium-stimulated uptake of rubidium which occurs in erythrocytes does not necessarily occur in other cell types. 4. These results suggest that previous studies of cation transport using peripheral cells and assay systems in vitro do not necessarily reflect changes in cation transport in vivo in excitable tissues.
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PMID:Measurement of cation transport in vivo in healthy volunteers after the oral administration of lithium carbonate. 254 Sep 32

Effects of lithium in vivo and in vitro on the two molecular forms of Na+,K(+)-ATPase in rat brain were investigated. Inhibition by strophanthidin, affinity to monovalent cations and cellular localization of the enzyme were used to differentiate the two molecular forms. K+ dependent p-nitrophenylphosphatase activity and strophanthidin inhibition studies revealed selective increase in the activity of low affinity form but not high affinity form of the enzyme following lithium treatment. Na+ sensitivity of neither forms of Na+,K(+)-ATPase was changed but K+ sensitivity of low affinity form was increased due to lithium. Lithium showed biphasic effects on low affinity form of the enzyme; activation at low concentration and inhibition at high concentration. The results suggest that lithium in vivo regulates the concentration of extra cellular potassium by selectively acting at K+ site of low affinity form of the enzyme (astroglial) but not on high affinity form (neuronal enzyme) and leading to changes in neuronal depolarization.
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PMID:Effect of lithium on regulation of two molecular forms of Na+,K(+)-ATPase in rat brain. 256 98

Erythrocyte membrane Mg2+ ATPase and Na+-K+ ATPase were measured in patients with affective disorder, their well relatives, and normal controls during euthymic moods. On the average, the Mg2+ ATPase activity was high in subjects belonging to affective disorder families. However, the difference between normal and affective disordered individuals was not statistically significant. Only the well individuals from affective disorder pedigrees as a group had significantly higher than normal Mg2+ ATPase activity (p less than 0.05). The Na+-K+ ATPase activity was similar for all the groups, including normal, bipolar manic-depressive (with or without lithium), unipolar depressive, and well individuals. Lithium treatment did not seem to have any effect on Mg2+ ATPase. Even though the values of Na+-K+ ATPase in the lithium-treated group were high, it is not certain that this was due to lithium per se.
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PMID:Erythrocyte membrane sodium-potassium and magnesium ATPase in primary affective disorder. 298 55

When Na,K-ATPase containing occluded rubidium ions is exposed to orthophosphate, in the presence of magnesium ions, there is a rapid release of half or all of the occluded ions. This behaviour is observed irrespective of whether the occluded-rubidium form of the enzyme is generated by putting the unphosphorylated enzyme in a sodium-free medium containing rubidium ions, or by allowing rubidium ions to catalyse the hydrolysis of phosphoenzyme made by adding ATP to enzyme suspended in a medium containing sodium and magnesium ions. The release of occluded rubidium ions by orthophosphate requires the presence of magnesium, presumably because phosphorylation is necessary. Whether the addition of orthophosphate causes the rapid release of all or of half of the occluded rubidium depends on whether free rubidium (or potassium, thallium or (probably) caesium ions) are present in the medium at the time the orthophosphate is added. In the absence of free ions of these species, all of the occluded rubidium is released. In their presence (in adequate concentration), only half of the occluded rubidium is released. The relative effectiveness of the different potassium congeners in preventing the rapid release of 50% of the occluded rubidium when orthophosphate is added is: thallium greater than rubidium greater than potassium greater than caesium. Lithium and sodium are ineffective even at high concentrations, and sodium ions strongly antagonize the effect of free rubidium ions. In a sodium-free, Tris medium, the concentration of free rubidium ions necessary for a half-maximal effect is about 30 microM. In a medium containing 250 microM-free rubidium, the concentration of sodium necessary to reduce the effect of free rubidium by 50% is about 500 microM. These figures are compatible with the hypothesis that the free rubidium or other ions act at the potassium-loading sites at the extracellular face of the pump. By starting with enzyme occluding unlabelled rubidium, and using 86Rb-labelled free rubidium, it is possible to show that the free ions that prevent the rapid release of half of the occluded ions themselves become occluded. These experiments are significant in two ways. First, they provide direct evidence for the existence of a second route for the release of occluded rubidium (and therefore presumably of occluded potassium) ions. Secondly, they seem to require that the release of occluded ions by this route occurs in an ordered fashion.
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PMID:Evidence for the ordered release of rubidium ions occluded within the Na,K-ATPase of mammalian kidney. 300 Dec 96

Endocytotic vesicles (i.e., endosomes) were prepared from rabbit renal cortex following the intravenous injection of horseradish peroxidase. The endosomal population was derived from a 100,000-g pellet and was found at equilibrium in the lightest area of a sucrose density gradient. This population was separate from other organelles as determined by enzyme markers and had a 2.5-fold enrichment of horseradish peroxidase specific activity compared with the homogenate specific activity corrected for soluble horseradish peroxidase activity. The endosomes contain an oligomycin-insensitive, electrogenic H+-translocating ATPase. They also contain an electroneutral Na+-H+ exchanger. This exchanger is not inhibited by amiloride, and lithium is not a substrate for the exchanger. Lithium does inhibit the Na+-H+ exchanger when added prior to the addition of sodium. The Michaelis constant for sodium of the endosomal Na+-H+ exchanger was found to be 10.0 mM. These data indicate that a population of endosomes from rabbit renal cortex contain an electrogenic H+-ATPase and an electroneutral Na+-H+ exchanger and that the exchanger is distinct from the brush-border membrane Na+-H+ antiporter.
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PMID:Electrically neutral Na+-H+ exchange in endosomes obtained from rabbit renal cortex. 302 Sep 98

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