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)

Calcium transport into inverted vesicles of Escherichia coli was observed to occur without an exogenous energy source when an artificial proton gradient was used. The orientation of the proton gradient was acid inside and alkaline outside. Either phosphate or oxalate was necessary for transport, as was found for respiratory-driven or ATP-driven uptake (Tsuchiya, T., and Rosen, B.P. (1975) J. Biol. Chem. 250, 7687-7692). Phosphate accumulation was found to occur in conjunction with calcium accumulation. Calcium transport driven by an artificial proton gradient was stimulated by dicyclohexylcarbodiimide, an inhibitor of the Mg2+ATPase (EC 3.6.1.3). Valinomycin, which catalyzes electrogenic potassium movement, stimulated calcium accumulation, while nigericin, which catalyzes electroneutral exchange of potassium and protons, inhibited both artificial proton gradient-driven transport and respiratory-driven transport. Other properties of the proton gradient-driven system and the previously reported energy-linked calcium transport system are similar, indicating that calcium is transported by the same carrier whether energy is supplied through an artificial proton gradient or an energized membrane state. These results suggest the existence of a calcium/proton antiport.
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PMID:Calcium transport driven by a proton gradient and inverted membrane vesicles of Escherichia coli. 0 8

In order to investigate the possible relations between the anionic permeability and the functions (or the structure ) of the inner mitochondrial membrane, three types of organelles isolated from S. cerevisiae were tested: mitochondria (aerobic culture), promitochondria (anaerobic culture) and CAP-mitochondria (aerobic culture with chloramphenicol added). By using the technique of swelling in isoosmotic potassium salts, after a derermination of the isotonic conditions, it was possible to discriminate between an electrogenic (valinomycin induced) or an electroneutral (both valinomycin and uncoupler induced) translocation. 1) Mitochondria: The permeability properties of mitochondria are energy dependent: a) Respiring mitochondria are permeable to Cl-; Mg2+, however, inhibits this translocation. Phosphate transport seems to be exclusively electrogenic and mersalyl sensitive, but swelling inhibition by that thiol reagent is restored by Mg2+. b) Non respiring mitochondria are impermeable to Cl-, but ATP addition restores the permeability. Thiocyanate permeates as the anionic form and acetate as the undissociated form. The phosphate transport, sensitive to mersalyl, seems to be partially electrogenic. 2) Promitochondria: Deficient of respiratory enzymes but containing an oligomycin sensitive ATPase, they are impermeable to Cl- only when Mg2+ is added. In these conditions, an electrogenic phosphate transport, sensitive to mersalyl, is observed. 3) CAP-mitochondria: Although CAP-mitochondria are cytochrome deficient and contain an oligomycin insensitive ATPase, they are also impermeable to Cl- in presence of Mg2+. As in fully differenciated mitochondria, an electroneutral phosphate entry is observed; Mg2+ is required for mersalyl sensitivity.
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PMID:[Permeability of yeast mitochondrial internal membrane: structure-activity relationship]. 13 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.
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PMID:Relationship between configuration, function, and permeability in calcium-treated mitochondria. 13 35

A microsomal fraction was isolated from the media-intima of the bovine carotid artery; the preparation is a mixed fraction of membranal and mitochondrial debris, which is able to bind Ca-ions and to take them up in the presence of ATP. The Ca-uptake is activated within a pCa range from 7--5. The involvement of two different systems in the Ca-uptake is discussed. A Ca-stimulatable ATPase was demonstrated, whose relationship with a Ca-transport system could not be established, however. The substrate for Ca-uptake is MgATP; in addition, free Mg has a stimulating effect. The Na/Kratio has no influence on the Ca-uptake. The influence of the pH-value on the Ca-binding and Ca-uptake was studied. Phosphate increased the Ca-uptake, while oxalate did not. The investigated system is discussed as a model for the action of vaso-active drugs.
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PMID:[Characterization of Ca-uptake by a microsomal fraction from vascular smooth muscle]. 15 43

Phosphate depletion (PD) causes impaired insulin secretion and metabolic derangements in pancreatic islets. We studied PD, pair-weighed (PW), and PD and PW rats treated with verapamil (PD-V and PW-V) to examine the mechanisms of these derangements. Cytosolic calcium ([Ca2+]i) in PD islets was higher than that in PW, PD-V, and PW-V islets, and the values in the latter three groups were not different. Both basal and stimulated ATP in PD islets were lower than those in PW, PW-V, or PD-V islets. The maximum velocity (Vmax) of Ca(2+)-ATPase and the Km and Vmax of Na+,K(+)-ATPase were reduced in PD islets. In both PD-V and PW-V, the Vmax of Ca(2+)-ATPase was higher than that in PD, but lower than that in PW. Both initial and second phases of insulin secretion by PD islets were lower than those by PW and PW-V islets. In PD-V rats, insulin secretion was greater than that in PD rats, but only the second phase was significantly higher. The data are consistent with either of the following possibilities: 1) PD causes a change in the permeability of islets, allowing increased entry of Ca2+ into them and a fall in ATP of islets; the latter would impair the activity of both ATPases, leading to reduced Ca2+ extrusion from islets and, hence, an elevation in their [Ca2+]i; or 2) the primary defect in PD is a reduction in the activities of ATPases of islets due to the fall in ATP secondary to phosphorus deficiency. The decreased Ca2+ extrusion that ensues, even in the face of normal Ca2+ entry, will result in high [Ca2+]i. In either of these scenarios the rise in [Ca2+]i would inhibit mitochondrial oxygen consumption and ATP production, further lowering the ATP content of the islets. The higher [Ca2+]i and low ATP of PD underlie the impaired insulin secretion. Verapamil, by blocking normal or augmented Ca2+ entry into the islets, mitigates or prevents the derangements in islet function and metabolism.
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PMID:Verapamil corrects abnormal metabolism of pancreatic islets and insulin secretion in phosphate depletion. 130 29

The question of the possible identity of catalytic and regulatory proton pathways in the chloroplast FoF1 ATPase has been studied using different energy-transfer inhibitors. Venturicidin, a reversible inhibitor of Fo, affects neither the delta mu H(+)-dependent thiol reduction of the membrane-bound chloroplast ATPase nor its ability to be activated by the proton gradient. It seems therefore to block only the proton flow required by the catalytic function of the enzymes. Venturicidin, however, also slows down the deactivation of the thiol-reduced ATPases during uncoupled ATP hydrolysis, following a delta mu H+ activation, but phloridzin, a reversible F1 inhibitor, has the same effect. Tentoxin, an irreversible F1 inhibitor, decreases the rate of ATP hydrolysis but does not affect the rate of deactivation. These findings suggest that catalytic and regulatory H(+)-binding sites are different. No distinction can be made, if any, between protons involved in unmasking the thiol-sensitive groups of F1 and in activating the enzyme. The effect of venturicidin and phloridzin on the deactivation is consistent with an inhibitory effect of newly formed--by ATP hydrolysis--ADP molecules, which might affect the enzyme without passing through the medium. Phosphate at millimolar concentration has an effect similar to low concentrations of phloridzin and venturicidin, probably by a simple back-reaction effect.
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PMID:An attempt to discriminate catalytic and regulatory proton binding sites in membrane-bound, thiol-reduced chloroplast ATPase. 131 60

Phosphate depletion (PD) causes a rise in basal level of cytosolic calcium ([Ca2+]i) of pancreatic islets, a decrease in their basal and stimulated ATP content, a reduction in the maximum velocity (Vmax) of Ca2+ adenosine triphosphatase (ATPase) and Na(+)-K+ ATPase, impaired glucose-induced calcium signal and decreased glucose-induced insulin secretion. The sequence of events that lead to these derangements during the evolution of PD are not defined. The present study examined this issue by measuring the metabolic and functional profile of pancreatic islets weekly during the evolution of PD over a period of 6 weeks, and whether phosphate repletion reverses these abnormalities. The results show that initial abnormalities are a rise in Vmax of Ca2+ ATPase and modest rise in basal [Ca2+]i. This was followed by a fall in basal and stimulated ATP content. With the fall in ATP content, the Vmax of Ca2+ ATPase and Na(+)-K+ ATPase decreases and the rise in [Ca2+]i becomes more pronounced. A decrease in glucose-induced insulin secretion becomes evident with the fall in ATP, the decrease in glucose-induced calcium signal, and/or delta[Ca2+]i/basal[Ca2+]i. All functional and metabolic derangements of the pancreatic islets returned to normal after phosphate repletion. Taken together, our data are consistent with the notion that PD is associated with an initial increase in calcium influx into the islets. This is followed by modest but significant rise in [Ca2+]i which, in turn, would inhibit mitochondrial oxidation and ATP generation leading to a decrease in ATP content. The latter compromises the activity of Ca2+ ATPase and Na(+)-K+ ATPase which are involved, directly or indirectly, in calcium extrusion out of the islets. The increased influx of calcium combined with decreased calcium extrusion is followed by a further rise in basal levels of [Ca2+]i. This sequence of events continues until a steady state is reached and is characterized by reduced basal and stimulated ATP content, reduced Vmax of Ca2+ ATPase and Na(+)-K+ ATPase and elevated basal level of [Ca2+]i. Phosphate repletion reverses all these abnormalities.
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PMID:Evolution of metabolic and functional derangements of pancreatic islets in phosphate depletion. 133 Apr 95

A variety of systems use nucleoside triphosphate hydrolysis to control or provide energy for biological processes, mediated through protein-protein interactions. The nature of this coupling may vary, but often there is a degree of similarity. In this paper, two systems are compared: actomyosin in muscle and p21ras in a signal transduction pathway as yet undefined. The mechanism of the nucleotide triphosphate hydrolysis and the consequent changes in the protein-nucleotide complex have been investigated, to understand how the coupling to biological function is achieved. The basal nucleoside triphosphatase mechanisms are compared and the roles of proteins that activate the hydrolysis, actin and GAP, are discussed. The cleavage process was probed by stereochemical techniques to determine the basic mechanism, of either a phosphorylated enzyme intermediate or direct displacement of nucleoside diphosphate by water. Phosphate-water oxygen exchange probes were used to investigate nucleoside triphosphate and inorganic phosphate release steps. A new method of probing the kinetics of inorganic phosphate release directly has been developed. In muscle, this process seems likely to be related directly to force generation. In the GAP-ras system, measurement of phosphate release is allowing the mechanism of the GAP-p21ras interaction to be probed.
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PMID:The role of nucleoside triphosphate hydrolysis in transducing systems: p21ras and muscle. 135 Dec 91

The uptake of [32P]KH2PO4 by Percoll-purified human fibroblast lysosomes at pH 7.0 was investigated to determine if lysosomes contain a transport system recognizing phosphate. Lysosomal phosphate uptake was linear for the first 2 min, attained a steady state by 8-10 min at 37 degrees C, and was not Na+ or K+ dependent. Upon entering lysosomes, [32P]phosphate was rapidly metabolized to trichloroacetic acid-soluble and trichloroacetic acid-insoluble products. After 1-min incubations, 50% of the radioactivity recovered from lysosomes was in the form of inorganic phosphate; and after a 2.5-min incubation, 27% of the radioactivity was recovered as inorganic phosphate. When lysosomes are loaded with radioactivity by incubation with 0.03 mM [32P]KH2PO4 for 25 min and then washed at 4 degrees C, lysosomes fail to release the accumulated radioactivity during a subsequent incubation at 37 degrees C. Lysosomal phosphate uptake gave linear Arrhenius plots (Q10 = 1.8) and was inversely proportional to medium osmolarity. Phosphate uptake was maximal at pH 5-6, half-maximal at pH 7.1, with little transport activity at pH greater than 8, suggesting that the transport system recognizes the monobasic form of phosphate. Lysosomal phosphate uptake is saturable, displaying a Km of 5 microM at pH 7.0 and 37 degrees C. High specificity for phosphate is demonstrated since large concentrations of Na2SO4, NaHCO3, KCl, NaCl, 5'-AMP, or the anion transport inhibitor, 4,4'-diisothiocyanatostilbene-2,2'-disulfonate, have no effect on lysosomal phosphate transport. In contrast, the phosphate analog, arsenate, strongly inhibits lysosomal phosphate uptake in a competitive manner with a Ki of 7 microM. Pyridoxal phosphate, CTP, adenosine 5'-(beta,gamma-imino)triphosphate (AMP-PNP), and glucose 6-phosphate were found to be noncompetitive inhibitors of lysosomal phosphate uptake displaying Ki values of 80-250 microM. When lysosomes are incubated with [gamma-32P]ATP, the lysosomal membrane ATPase hydrolyzes the ATP to form inorganic phosphate which then enters lysosomes by this lysosomal phosphate transport route.
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PMID:Characterization of a phosphate transport system in human fibroblast lysosomes. 182 4

Near-UV irradiation in the presence of vanadate cleaves the heavy chain of myosin subfragment 1 at three specific sites located at 23, 31, and 74 kDa from the N-terminus. Increasing the pH from 6.0 to 8.5, gradually, reduces the efficiency of the cleavage and completely eliminates the 31-kDa cut. Actin specifically inhibits the photocleavage at the sites located 31 and 74 kDa from the N-terminus. ATP strongly protects from cleavage at the 23- and 31-kDa sites and less strongly from the cut at the 74-kDa site. ADP and pyrophosphate have similar, but less pronounced, effects as ATP. Orthophosphate inhibits the photocleavage at the 23- and 74-kDa sites with a similar efficiency. In the ternary actin-S-1-ATP complex, the photocleavage is inhibited at all sites, and the effects of actin and ATP are additive. Photocleavages affect the K+(EDTA)-, Ca2(+)-, and actin-activated ATPase activity of subfragment 1. Loss of all three ATPases is caused by cleavage at the 23-kDa site, while the cut at the 74-kDa site only leads to the loss of actin-activated ATPase activity. It is concluded that subfragment 1 contains at least two distinct phosphate binding sites, the first being part of the "consensus" ATP binding site wherein the 23-kDa photocleavage site is located. This site is responsible for the binding and hydrolysis of ATP. It is possible that the 31-kDa cleavage site is also associated with the "consensus" site through a loop. The 74-kDa cleavage site is a part of another phosphate binding site which may play a role in the regulation of the myosin-actin interaction.
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PMID:Effect of actin, ATP, phosphates, and pH on vanadate-induced photocleavage of myosin subfragment 1. 182 26


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