EC:3.6.1.3 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Target Concepts:

Query: EC:3.6.1.3 (ATPase)
65,361 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Methylxanthines (MX) inhibit cell division in sea urchin and clam eggs. This inhibitory effect is not mediated via cAMP. MX also inhibit respiration in marine eggs, at concentrations which inhibit cleavage. Studies showed that no changes occurred in ATP and ADP levels in the presence of inhibitory concentrations of MX, indicating an extra-mitochondrial site of action for the drug. Subsequent studies revealed decreased levels of NADP+ and NADPH, when eggs were incubated with inhibitory concentrations of MX, but no change in levels of NAD+ and NADH. MX did not affect the pentose phosphate shunt pathway and did not have any effect on the enzyme NAD+ -kinase. Further studies showed a marked inhibitory effect on the glutathione reductase activity of MX-treated eggs. Reduced glutathione (GSH) could reverse the cleavage inhibitory effect of MX. Moreover, diamide, a thiol-oxidizing agent specific for GSH in living cells, caused inhibition of cell division in sea urchin eggs. Diamide added to eggs containing mitotic apparatus (MA) could prevent cleavage by causing a dissolution of the formed MA. Both MX and diamide inhibit a Ca2+-activated ATPase in whole eggs. The enzyme can be reactivated by sulfhydryl reducing agents added in the assay mixture. In addition, diamide causes an inhibition of microtubule polymerization, reversible with dithioerythritol. All experimental evidence so far suggests that inhibition of mitosis in sea urchin eggs by MX is mediated by perturbations of the in vivo thiol-disulfide status of target systems, with a primary effect on glutathione levels.
...
PMID:Effects of caffeine and other methylxanthines on the development and metabolism of sea urchin eggs. Involvement of NADP and glutathione. 1 15

The presence and some properties of an NAD+ transport system were examined in PA5, a Mg, Ca-ATPase [EC 3.6.1.3]-defective mutant strain of Escherichia coli W2252. NAD+ uptake was stimulated by exogenous energy sources and dependent on external substrate concentrations with an apparent Km of about 25 micrometer. Most of the radioactivity from [14C]-NAD+ accumulated in the cells was identified as NAD+. [14C]NAD+ uptake was competively inhibited by unlabeled NAD+, NADP+, NMN+ or nicotinamide. Similar uptake activity was also observed in W2252.
...
PMID:Transport of nicotinamide adenine dinucleotide in an unc mutant of Escherichia coli. 3 59

NAD+ reduction catalyzed by transhydrogenase (EC 1.6.1.1) from E. coli membrane particles at the expense of NADPH oxidation is coupled with phenyldicarbaundecaborate (PCB-) absorption by the particles. This process is inhibited by oxidative phosphorylation protonophorous uncouplers and by equilibration of concentrations of the substrates and products of the transhydrogenase reaction. Elimination of the water-soluble part of membrane ATPase results in the inhibition of PCB- absorption at the expense of the transhydrogenase reaction energy. Treatment of the particles by dicyclohexyl carbodiimide increases the transhydrogenase-coupled absorption of PCB-. The transhydrogenase-induced increase of pPCB in the suspension of particles is directly correlated with the ratio of ([NADPH].[NAD+])/([NADP+].[NADH]). When this value is equal to 1, no energy-dependent increase of pPCB was observed. NADP+ reduction at the expense of NADH oxidation leads to a decrease in the amount of PCB- absorbed by the particles at the expense of ATP hydrolysis energy. The experimental data suggest that NADPH oxidation in the course of the transhydrogenase reaction is coupled with the formation of a membrane potential with a positive charge localized inside the particles.
...
PMID:[Transhydrogenase as an additional site of energy accumulation in the E. coli respiratory chain]. 3 31

Low levels of calcium (100 nmol/mg) added to beef heart mitochondria induced a configurational transition from the aggregated to the orthodox state and a simultaneous uncoupling of oxidative phosphorylation. The primary effect of calcium was to cause a nonspecific increase in the permeability of the inner membrane, resulting in entry of sucrose into the matrix space and the observed configurational transition. The uncoupling and permeability change induced by calcium could readily be reversed by lowering the calcium:magnesium ratio in the presence of either substrate or ATP. The configurational state, however, remained orthodox. This, along with studies of hypotonically induced orthodox mitochondria in which the membrane remained coupled and impermeable until after the addition of calcium, led to the conclusion that coupling was related to the permeability state of the inner membrane rather than the configurational state. Phosphate, arsenate, or oleic acid was found to cause a transition similar to that induced by calcium. Studies with the specific calcium transport inhibitors, EGTA, ruthenium red, and lanthanum revealed that endogenous calcium is required for the anion-induced transitions. A single mechanism was further indicated by a common sensitivity to N-ethylmaleimide. Strontium was ineffective as an inducer of the transition, even though it is transported by the same mechanism as calcium. This indicates that there are additional calcium-binding sites responsible for triggering the transition. Magnesium and calcium appeared to compete for these additional sites, since magnesium competitively inhibited the calcium-induced transition, but had no effect on calcium uptake. Calcium was found to potently inhibit the respiration of all NAD+-requiring substrates prior to the transition. Strontium also produced this inhibition without a subsequent transition. ATPase activity was induced at the exact time of transition with calcium and was not induced by strontium. This suggests that calcium-induced ATPase uniquely required the transition for activity, in contrast to the ATPase induced by uncoupler or valinomycin. The results of this work indicate that mitochondria have a built-in mechanism which responds to low levels of calcium, phosphate, and fatty acids, resulting in simultaneous changes, including increased permeability, inducation of ATPase, uncoupling of oxidative phosphorylation, and loss of respiratory control.
...
PMID:Relationship between configuration, function, and permeability in calcium-treated mitochondria. 13 35

1. DL-8-Methyldihydrolipoate was shown to be a potent inhibitor of mitochondrial oxidative phosphorylation and ATP-driven energy-linked reactions. 2. ADP-stimulated respiration utilizing pyruvate + malate and succinate in both ox heart and rat liver mitochondria is inhibited; oxidative phosphorylation using pyruvate + malate, succinate and ascorbate + NNN'N'-tetramethyl-p-phenylenediamine as substrates is also inhibited; uncoupler-stimulated respiration is unaffected regardless of the substrate used. 3. Mitochondrial oligomycin-sensitive adenosine triphosphatase is inhibited in both the membrane-bound form and the purified detergent-dispersed preparation. 4. ATP-driven transhydrogenase and the ATP-driven energy-linked reduction of NAD+ by succinate in ox heart submitochondrial particles are inhibited, whereas the respiratory-chain-driven transhydrogenase is unaffected. 5. DL-8-Methyl-lipoate has no immediate effect on the above reactions, demonstrating the requirement for the reduced form for inhibition. 6. The inhibitory properties of DL-8-methyldihydrolipoate are analogous to those of oligomycin and provide further evidence of a role for lipoic acid in oxidative phosphorylation.
...
PMID:Studies of energy-linked reactions. Inhibition of oxidative phosphorylation by DL-8-methyldihydrolipoate. 14 82

1. Citreoviridin was a potent inhibitor of the soluble mitochondrial ATPase (adenosine triphosphatase) similar to the closely related aurovertins B and D. 2. Citreoviridin inhibited the following mitochondrial energy-linked reactions also: ADP-stimulated respiration in whole mitochondria from ox heart and rat liver; ATP-driven reduction of NAD+ by succinate; ATP-driven NAD transhydrogenase and ATPase from ox heart submitochondrial particles. 3. The dissociation constant (KD) calculated by a simple law-of-mass-action treatment for the citreoviridin--ATPase complex was 0.5--4.2micron for ox-heart mitochondrial preparations and 0.15micron for rat liver mitochondria. 4. Monoacetylation of citreoviridin decreased its inhibitory potency (KD=2--25micron, ox heart; KD=0.7micron, rat liver). Diacetylation greatly decreased the inhibitory potency (KD=60--215micron, ox heart). 5. Hydrogenation of citreoviridin monoacetate diminished its inhibitory potency considerably. 6. No significant enhancement of fluorescence was observed when citreoviridin interacted with the mitochondrial ATPase.
...
PMID:Citreoviridin, a specific inhibitor of the mitochondiral adenosine triphosphatase. 14 74

Despite continuous interest in cardiac hypertrophy, our knowledge of its molecular aspects is still elementary. Recently, however, several advancements of particular interest have been made: (a) Nuclei of muscle and nonmuscle cells have been separated, allowing for the first time the study of nuclear activity in specified cells (18). (b) Cardiac growth induced by pressure-overload (72) or by hormone treatment (26) has been shown to lead to myosin of altered ATPase, and strong evidence suggests that new species of myosin molecules thus appear. (c) The basis for assessment of protein synthesis and degradation has been established (46, 48). (d) Methods are being developed to supplement radioautography in evaluating cell proliferation (42, 59, 69). (e) In spontaneously hypertensive rats it has been shown that blood pressure might not be the sole factor responsible for cardiac enlargement, but that hypertrophy can be the result of genetic cardiovascular abnormality (19, 66). (f) A hypothesis relating the extent of energy utilization to the nuclear activity via NAD+ metabolism has been proposed, which allows for experimental verification (43).
...
PMID:Molecular aspects of cardiac hypertrophy. 15 20

1. A large series of 3' esters of ADP has been synthesized. Several of these can serve as photoaffinity labels; others exhibit fluorescent properties. The corresponding AMP and ATP derivatives have also been synthesized in some cases. 2. The influence of the 3'-O-acyl nucleotides on energy-linked functions of beef-heart submitochondrial particles has been investigated. The following results were obtained. a) 3'Esters of ADP are powerful and highly specific inhibitors of oxidative phosphorylation. The inhibition is competitive to ADP and Ki values as low as 0.05 microM, for the 3'-O-(1)naphthoyl ester of ADP, could be observed. b) The inhibition of oxidative phosphorylation by 3' esters of ADP appears to be non-competitive versus inorganic phosphate. c) The nucleotide analogs are not phosphorylated themselves. The corresponding ATP analogs can not drive energy-linked process. d) The 3' esters of AMP are ineffective as inhibitors, whereas the ATP derivatives are only comparatively weak inhibitors. e) Uncoupled or solubilized ATPase is almost two orders of magnitude less sensitive against inhibition by 3' esters than coupled systems. The analogs exert maximal inhibition specifically in systems involving an 'energized' state of the coupling device. f) Azido-group-bearing analogs can be used for irreversible photoinactivation of the coupling ATPase. Photoinactivation also is most efficient when carried out with 'energized' particles. g) The inhibitory properties are similar also in ATP-driven NAD+ reduction by succinate, and in the uncoupler-sensitive ATP in equilibrium with Pi exchange. The required concentrations for half-maximal inhibition are somewhat higher than in oxidative phosphorylation, but lower than with uncoupled ATPase. 3. From molecular models, from substituent properties, and from the conditions required for inhibition it is concluded that these highly effective analogs of ADP may act as conformation-specific probes at the catalytic site of oxidative phosphorylation. The results are interpreted in terms of a model suggesting that, in the process of ATP synthesis, a hydrophobic cavity on the enzyme is exposed only in the energized state, accepting the large 3' substituent. The substituent is assumed to inhibit phosphoryl transfer and/or conformational transitions inherent in the process of ADP phosphorylation by steric hinderance.
...
PMID:3' Esters of ADP as energy-transfer inhibitors and probes of the catalytic site of oxidative phosphorylation. 15 76

1. In addition to the previously studied 8-azido-ATP, 8-azido-ADP is a suitable photoaffinity label for beef-heart mitochondrial ATPase (F1). 2. Photolysis at 350 nm of 8-azido-ADP in the presence of isolated F1 leads to inactivation of ATPase activity. Both ATP and ADP (but not AMP) protect against the inactivation. 3. In the absence of Mg2+, 8-azido-ADP binds almost equally to the alpha and beta subunits of F1, whereas in the presence of Mg2+ the alpha subunits are predominantly labelled. 4. The ATPase activity is completely inhibited when two molecules of 8-azido-ADP are bound per molecule F1. 5. 8-Azido-ATP and ATP are competitive substrates for F1, indicating that in the presence of Mg2+ 8-azido-ATP binds to the same site as ATP. 6. The amount of tightly bound nucleotides in F1 is not significantly changed upon incubation with 8-azido-ATP either in the light or the dark. 7. 8-Azido-ATP is also a suitadrial particles, photolabelling leading to inactivation of ATPase activity. 9. Oxidative phosphorylation and the ATP-driven reduction of NAD+ by succinate are also inhibited by photolabelling Mg-ATP particles with 8-azido-ATP. 10. In contrast to the uncoupled ATPase activity, where the two ATP-binding sites do not interact, cooperation between the two sites is required for ATP hydrolysis coupled to reduction of NAD+ by succinate.
...
PMID:Localisation of adenine nucleotide-binding sites on beef-heart mitochondrial ATPase by photolabelling with 8-azido-ADP and 8-azido-ATP. 15 87

Rhodopseudomonas palustris is grown photosynthetically on thiosulfate. As pointed out earlier, the chromatophore deficient cell-free fraction S-144,000 catalyzes the thiosulfate-linked ATP-dependent reversal of electron transfer in anaerobiosis, thus providing reducing equivalents in the form of NADH. Under aerobic conditions, this fraction also catalyzes the oxidation of NADH, ferro-cytochrome c, or ascorbate. ATP, ADP, and PPi are active in retarding the aerobic electron flow. The electron retardation is stimulated by the addition of Mg2+ due to a Mg2+-stimulated ATPase present. The ATPase system in S-144,000 hydrolyzes ATP, ADP, and PPi. Similarly, ATP or ADP, or even PPi can function as energy sources in order to achieve the reduction of pyridine nucleotide. The ATPase turnover is diminished by NADH or NAD+. Admixture of ascorbate results in an increased ATPase activity. Exactly the enhanced amount of adenine nucleotide hydrolysis caused by the addition of ascorbate is inhibited by cyanide.
...
PMID:Respiratory electron flow and ATPase system in photosynthetically grown Rhodopseudomonas palustris. 17 Jul 51

1 2 3 4 5 6 7 Next >>