EC:3.6.1.3 - FACTA Search

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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 oxidative metabolism were studied in hepatopancreas, muscle, and hemolymph of the edible crab Scylla serrata, exposed to a sublethal concentration (2.5 ppm) of cadmium chloride. A significant decrease in glycogen, total carbohydrates, and pyruvate and an increase in lactate levels in hepatopancreas and muscle were observed. Hemolymph sugar levels were increased in experimental crabs. An increase in phosphorylase suggested increased glycogenolysis during cadmium toxicity. The decrease in lactate dehydrogenase activity and the increase in lactate content indicated reduced mobilization of pyruvate into the citric acid cycle. Krebs cycle enzymes such as succinate dehydrogenase and malate dehydrogenase were found to be decreased, suggesting impairment of mitochondrial oxidative metabolism as a consequence of cadmium toxicity. Glucose-6-phosphate dehydrogenase activity was increased, suggesting enhanced oxidation of glucose by the HMP pathway. Cytochrome-c oxidase and Mg2+ ATPase activity levels decreased, indicating impaired energy synthesis during cadmium stress. Acid and alkaline phosphatase activities increased, suggesting enhanced breakdown of phosphates to release energy in view of impaired ATPase system during cadmium exposure. A significant decrease in protein and free amino acid and an increase in ammonia, urea, and glutamine levels were observed in the tissues during exposure. An increase in protease, alanine aminotransaminase, and aspartate aminotransaminase suggested increased proteolysis and transamination of amino acids. The increase in glutamate dehydrogenase, AMP deaminase, and adenosine deaminase indicated increased ammonia production. The increased arginase and glutamine synthetase suggested the detoxification or mobilization of ammonia toward the production of urea and glutamine. These results suggest that cadmium affects oxidative metabolism and induces hyperammonemia, and crabs switch over their metabolic profiles toward compensatory mechanisms for the survivability in cadmium-polluted habitats.
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PMID:Changes in oxidative metabolism in selected tissues of the crab (Scylla serrata) in response to cadmium toxicity. 753 86

The role of simultaneously existing ATP-binding sites in the catalytic process of Na+/K(+)-ATPase is unclear. In order to learn whether blocking the E1ATP site affects the properties of the E2ATP site, the E1ATP site was inactivated by either fluorescein 5'-isothiocyanate, the non-phosphorylating Cr(H2O)4AdoPP[CH2]P or the phosphorylating Cr(H2O)4ATP. The properties of the remaining E2ATP site were studied by measuring 'backdoor phosphorylation' in the presence of ouabain, or K(+)-activated hydrolysis of p-nitrophenyl phosphate. The involvement of the E2ATP site was further tested by the effects of Co(NH3)4ATP, a specific inactivator of this site. When the E1ATP site was inactivated by fluorescein 5'-isothiocyanate or the non-phosphorylating Cr(H2O)4AdoPP[CH2]P, backdoor phosphorylation and the activity of K(+)-activated p-nitrophenylphosphatase remained unchanged. Both processes were lost, however, when the E2ATP site was additionally inactivated by Co(NH3)4ATP. Inactivation of the E1ATP site by fluorescein 5'-isothiocyanate or Cr(H2O)4AdoPP[CH2]P decreased the affinity of the p-nitrophenylphosphatase activity of the E2ATP site for the substrate p-nitrophenyl phosphate by four times. This is consistent with a former report showing that dephosphorylation in a fluorescein 5'-isothiocyanate-inactivated Na+/K(+)-ATPase has a lowered sensitivity for ATP [Scheiner-Bobis, G., Antonipillai, J. & Farley, R. A. (1993) Biochemistry 32, 9592-9599]. Inactivation of the E1ATP site by the phosphorylating Cr(H2O)4ATP, however, led to a loss of the property of the E2ATP site to hydrolyse K(+)-dependent p-nitrophenyl phosphate and to achieve backdoor phosphorylation. Evidently, ATP sites coexist in Na+/K(+)-ATPase, and binding of ATP to one site affects the property of the other site [Scheiner-Bobis, G., Esmann, M. & Schoner, W. (1989) Eur. J. Biochem. 183, 173-178]. Although the enzyme can be phosphorylated from both ATP sites, phosphorylation of the E1ATP site excludes the phosphorylation of the E2ATP site.
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PMID:Na+/K(+)-ATPase with a blocked E1ATP site still allows backdoor phosphorylation of the E2ATP site. 755 90

Carbamoyl phosphate synthetase from Escherichia coli catalyzes the synthesis of carbamoyl phosphate from bicarbonate, ammonia, and two molecules of MgATP. The enzyme is composed of two nonidentical subunits. The small subunit catalyzes the hydrolysis of glutamine to glutamate and ammonia. The large subunit catalyzes the formation of carbamoyl phosphate and has the binding sites for bicarbonate, ammonia, MgATP, and the allosteric ligands IMP, UMP, and ornithine. The allosteric ligands are believed to bind to the extreme C-terminal portion of the large subunit. Truncation mutants were constructed to investigate the allosteric binding domain. Stop codons were introduced at various locations along the carB gene in order to delete amino acids from the carboxy-terminal end of the large subunit. Removal of 14-119 amino acids from the carboxy-terminal end of the large subunit resulted in significant decreases in all of the enzymatic activities catalyzed by the enzyme. A 40-fold decrease in the glutamine-dependent ATPase activity was observed for the delta 14 truncation. Similar losses in activity were also observed for the delta 50, delta 65, delta 91, and delta 119 mutant proteins. However, formation of carbamoyl phosphate was detected even after the deletion of 119 amino acids from the carboxy-terminal end of the large subunit. No allosteric effects were observed for UMP with either the delta 91 or delta 119 truncation mutants, but alterations in the catalytic activity were observed in the presence of ornithine even after the removal of the last 119 amino acids from the large subunit of CPS. Six conserved amino acids within the allosteric domain were mutated.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Regulatory changes in the control of carbamoyl phosphate synthetase induced by truncation and mutagenesis of the allosteric binding domain. 757 87

1-Hydroxyethane-1,1-diphosphonate (EHDP) and a variety of other diphosphonates, and also pyrophosphate, at millimolar levels were found to inhibit the growth of Streptococcus mutans GS-5. Inhibition appeared to be due mainly to chelation of Mg2+ and could be readily reversed through addition of Mg2+, or less effectively, by other divalent cations. The trianionic forms of the diphosphonates or pyrophosphate were more effective inhibitors than the dianionic forms. Diphosphonates and pyrophosphate did not inhibit glycolysis by S. mutans, assayed in terms of glucose utilization, or arginolysis by Streptococcus rattus FA-1, assayed in terms of ammonia production. However, they did act as buffers to moderate pH changes. Diphosphonates also were inhibitors of the F-ATPase of S. mutans by complex mechanisms only partly reversible with divalent cations. They also were inhibitors of the pyrophosphatase of the organism. However, intact cells were impermeable to the compounds, and inhibition of cytoplasmic or membrane enzymes did not appear to be involved in growth inhibition.
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PMID:Inhibition of streptococcal growth, F-ATPase and pyrophosphatase by diphosphonates. 764 73

The photoreduction, without reductant dithionite, of N2 to NH3 or acetylene to ethylene catalysed by nitrogenase in the presence of Mg2+. ATP, eosin and NADH in the light has been established. There is an optimum NADH concentration for each particular eosin concentration. When the ratio of the iron protein component of nitrogenase from Azotobacter vinelandii (Av2)/the molybdenum-iron protein component of nitrogenase from A. vinelandii (Av1) is equal to 3 for 4 x 10(-5) M eosin the optimum NADH concentration is 5 x 10(-4) M. The rate of photoreduction (per one electron) of acetylene or N2 under identical conditions was shown to be similar. The photoreductant-dependent ATPase activity, in the presence of a given photochemical system in the light, was revealed. Eosin is shown to be the inhibitor of the coupling site. Concentrations of 8 x 10(-6) -1 x 10(-4) M eosin do not inhibit the ATPase activity. The inhibition of substrate-reduction activity depends on the ratio of the nitrogenase components. Under conditions where the Av2/Av1 ratio is equal to 1 the rate of photochemical reduction is higher than in the presence of dithionite: the total electron flux through nitrogenase being increased 2.2-fold. We suggest that in this case the nitrogenase complex (1:1) works without dissociation.
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PMID:The photoreduction of nitrogenase. 768 Aug 58

In summary, we propose that acute ammonia intoxication leads to increased extracellular concentration of glutamate in brain and results in activation of the NMDA receptor. Activation of this receptor mediates ATP depletion and ammonia toxicity since blocking the NMDA receptor with MK-801 prevents both phenomena. Ammonia-induced metabolic alterations (in glycogen, glucose, pyruvate, lactate, glutamine, glutamate, etc) are not prevented by MK-801 and, therefore, it seems that they do not play a direct role in ammonia-induced ATP depletion nor in the molecular mechanism of acute ammonia toxicity. The above results suggest that ammonia-induced ATP depletion is due to activation of Na+/K(+)-ATPase, which, in turn, is a consequence of decreased phosphorylation by protein kinase C. This can be due to decreased activity of PKC or to increased activity of a protein phosphatase. We also show that L-carnitine prevents glutamate toxicity in primary neuronal cultures. The results shown indicate that carnitine increases the affinity of glutamate for the quisqualate type (including metabotropic) of glutamate receptors. Also, blocking the metabotropic receptor with AP-3 prevents the protective effect of L-carnitine, indicating that activation of this receptor mediates the protective effect of carnitine. We suggest that the protective effect of carnitine against acute ammonia toxicity in animals is due to the protection against glutamate neurotoxicity according to the above mechanisms.
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PMID:Molecular mechanism of acute ammonia toxicity and of its prevention by L-carnitine. 774 Oct 17

A model for transport of ammonia and ammonium ions across cell membranes is presented. The model suggests that ammonium ions compete with potassium ions for inward transport, over the cytoplasmic membrane, via potassium transport proteins like the Na+/K(+)-ATPase and the Na+K+2Cl(-)-cotransporter. It also explains the difference between the ammonia/ammonium that is added to the cells and which is formed by the cells during metabolism of amino acids, especially glutamine and glutamate. The ammonium transport and subsequent events lead to predictable intracellular and extracellular pH (pHe) changes. Experiments which verified the model and the predicted consequences were performed by measurements of the pHe in concentrated cell suspensions. Addition of ammonium ions caused a time-dependent pHe increase which was inhibited by potassium ions. The test system is not per se specific for transport measurements but the effect of potassium ions on the pHe strongly favors our suggested model. Simple diffusion of ammonium ions would not be counteracted by potassium ions. The results show that ammonium ion transport in the murine myeloma cell line (Sp2/0-Ag14) used is inhibited by an excess of potassium ions. Results from experiments with specific inhibitors of suggested transport proteins were not conclusive. It is postulated that one important toxic effect of ammonia/ammonium is an increased demand for maintenance energy, caused by the need to maintain ion gradients over the cytoplasmic membrane. The results also suggest that potassium ions can be used to detoxify ammonia/ammonium in animal cell cultivations.
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PMID:Mechanisms of ammonia and ammonium ion toxicity in animal cells: transport across cell membranes. 776 10

The uptake of radiolabelled neurotransmitters: glutamate (GLU), GABA, and dopamine (DA) and the activity of the vacuolar type H(+)-pumping ATPase (H(+)-ATPase), were measured in crude synaptic vesicles treated in vitro with a neurotoxic (3 mM) dose of NH4+ (acetate or chloride), or isolated from rats with a moderate increase of brain ammonia (to approximately 0.6 mM) induced by i.p. administration of ammonium acetate (HA rats) or a hepatotoxin-thioacetamide (HE rats). In vitro treatment with ammonium salts increased the sodium-independent, chloride-dependent uptake of GLU but did not stimulate the uptake of GABA or DA. The in vitro treatment also stimulated the H(+)-ATPase activity. Since H(+)-ATPase generates the electrochemical gradient driving synaptic vesicular neurotransmitter transport, its stimulation by ammonia may have facilitated GLU uptake. However the GLU specificity of the effect must be related to other factors differentially affecting GLU uptake and the uptake of other neurotransmitters. Enhanced GLU accumulation in the synaptic vesicles may contribute to the increase of synaptic GLU exocytosis previously reported to accompany acute increases of brain ammonia to toxic levels. However, GLU uptake and H(+)-ATPase activity, but also the uptake of GABA and DA, were unchanged in synaptic vesicles prepared from rats with HA or HE. This indicates that changes in GLU and/or GABA release reported for moderate hyperammonemic conditions must be elicited by factors unrelated to the synaptic vesicular transport of the amino acids.
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PMID:Ammonia added in vitro, but not moderate hyperammonemia in vivo, stimulates glutamate uptake and H(+)-ATPase activity in synaptic vesicles of the rat brain. 783 67

Injection of large doses of ammonia into rats leads to depletion of brain ATP. However, the molecular mechanism leading to ATP depletion is not clear. The aim of the present work was to assess whether ammonium-induced depletion of ATP is mediated by activation of the NMDA receptor. It is shown that injection of MK-801, an antagonist of the NMDA receptor, prevented ammonia-induced ATP depletion but did not prevent changes in glutamine, glutamate, glycogen, glucose, and ketone bodies. Ammonia injection increased Na+,K(+)-ATPase activity by 76%. This increase was also prevented by previous injection of MK-801. The molecular mechanism leading to activation of the ATPase was further studied. Na+,K(+)-ATPase activity in samples from ammonia-injected rats was normalized by "in vitro" incubation with phorbol 12-myristate 13-acetate, an activator of protein kinase C. The results obtained suggest that ammonia-induced ATP depletion is mediated by activation of the NMDA receptor, which results in decreased protein kinase C-mediated phosphorylation of Na+,K(+)-ATPase and, therefore, increased activity of the ATPase and increased consumption of ATP.
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PMID:Brain ATP depletion induced by acute ammonia intoxication in rats is mediated by activation of the NMDA receptor and Na+,K(+)-ATPase. 796 37

Pathways for ammonia transport have been incorporated within a model of rat proximal tubule [A. M. Weinstein. Am. J. Physiol. 263 (Renal Fluid Electrolyte Physiol. 32): F784-F798, 1992]. The luminal membrane includes a Na+/NH4+ exchanger, while at the peritubular membrane there is uptake of NH4+ on the Na(+)-K(+)-adenosinetriphosphatase (Na(+)-K(+)-ATPase); both luminal and peritubular cell membranes contain conductive pathways for NH4+. The model equations have been expanded to include cellular ammoniagenesis. The principal focus of this study is the interplay of forces that can raise proximal tubule fluid total ammonia concentration 10-fold higher than in arterial plasma. Analysis of a cellular model reveals that luminal membrane Na+/NH4+ exchange, cellular production of ammonia, and peritubular membrane NH4+ uptake (via Na(+)-K(+)-ATPase or via K+ channel) all act in parallel to drive ammonia secretion. This derives from the cellular interconversion of NH4+ and NH3 and the free permeation of NH3 across cell membranes. It implies that inhibition of the luminal membrane transporter does not block the contribution of peritubular uptake to the overall active transport of ammonia. Conversely, when inhibition of the luminal membrane Na+/NH4+ entry (i.e., Na+/H+ inhibition) depresses transcellular Na+ flux, then the decrease of NH4+ flux through the peritubular Na+ pump enhances the apparent importance of the luminal membrane pathway. This analysis is confirmed in the numerical calculations and is a departure from the Ussing paradigm of series membrane Na+ transport. Although active secretion of ammonia by this tubule is substantial, the relative contribution of luminal Na+/NH4+ exchange and of peritubular uptake via the Na+ pump remains uncertain. The determination of peritubular capillary NH4+ concentration will be crucial to resolving this uncertainty, with lower concentration (i.e., closer to systemic arterial ammonia) obligating greater luminal membrane Na+/NH4+ exchange.
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PMID:Ammonia transport in a mathematical model of rat proximal tubule. 806 84

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