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)

Rats were maintained on a vitamin E free diet containing 20% safflower oil for a period of 12 weeks at two dietary protein levels, 20% and 10% casein. Enhanced in vitro tissue lipid peroxidation and lysis of erythrocytes were noticed at both the protein levels. A reduction in body mass and tissue weights were observed in both the protein groups but more so at 20% protein level. Feeding of retinyl palmitate (100 000 IU/100 g body weight) for 4 consecutive days to -E rats inhibited liver and kidney in vitro lipid peroxidation. Ascorbic acid (150 mg/100 g body weight) given orally for 5 days to -E rats inhibited liver brain and kidney in vitro peroxidation. Lysis of erythrocytes from -E rats was further increased by dosing with both the vitamins "A" and "C", the latter being more effective. The stromal enzymes acetyl choline esterase and ATPase were lowered, following the hemolysis profile of the erythrocytes from the different groups. Glutathione content of erythrocytes were unaffected except in -E +C group. In all groups the higher protein level (20%) produced greater lysis as compared to 10% level. It is concluded that 20% protein is more injurious in vitamin E deficiency simultaneously made hypervitaminosis A or C.
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PMID:Effect of dietary protein and hypervitaminosis A or C on tissue peroxidation and erythrocyte lysis of vitamin E deficiency. 716 Sep 64

The heat shock protein GroEL from Escherichia coli is a tetradecameric oligomer that facilitates the refolding of nonnative polypeptides in an ATP-hydrolysis dependent reaction. A mutant in GroEL was prepared in which lysine 3 was substituted with glutamate, which destabilizes the oligomeric structure of GroEL (Horovitz, A., Bochkareva, E.S., and Girshovich, A.S. (1993) J. Biol. Chem. 268, 9957-9959). The highly expressed and purified GroELK3E was judged to be monomeric by sedimentation equilibrium, yielding a molecular weight of 54,500, despite a weak tendency of the mutant to reversibly form higher order aggregates above 4 mg ml-1. The monomeric variant appears to be folded based on the far UV circular dichroism spectrum, which shows significant alpha-helical content, but with slight differences in conformation relative to wild-type GroEL. The increase in exposed hydrophobic surface of the monomer was probed with the dye 4,4'-bis-1-anilino-3-naphthalenesulfonate (bis-ANS). The fluorescence of bis-ANS increases approximately 150-fold in the presence of the mutant, and about 4 mol of bis-ANS bind per mol of monomer, with a binding constant of 1.6 microM. Adenosine nucleotide binding to monomeric GroELK3E resulted in considerable quenching of bis-ANS fluorescence, correlating with significant structural changes as seen in the far UV circular dichroism, and permitted the measurement of binding isotherms for ATP and ADP. Hyperbolic ATP binding isotherms yield a dissociation constant of 82 microM, about 4-fold weaker than the K0.5 for ATP seen in steady-state kinetics assays of the wild-type GroEL ATPase.A similar difference was seen for ADP binding. These results suggest that the mutation disrupts the native tetradecameric quaternary structure through conformational changes that may also weaken nucleotide binding. The monomeric mutant exhibited no chaperone activity as evidenced by a filure to inhibit or facilitate the refolding of chemically denatured enolase, an inability to refold denatured rhodanese above spontaneous levels, and a lack of binding to alpha-casein, a competitor in many chaperonin-promoted refolding reactions. Thus, the formation of assembly incompetent monomers by the lysine 3 to glutamate mutation results in a dramatic decrease in the affinity for nonnative polypeptide chains and suggests that the oligomeric nature of GroEL is crucial for its molecular chaperone function.
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PMID:A monomeric variant of GroEL binds nucleotides but is inactive as a molecular chaperone. 765 15

ClpA is the ATPase component of the ATP-dependent protease Ti (Clp) in Escherichia coli and contains two ATP-binding sites. A ClpA variant (referred to as ClpAT) carrying threonine in place of the 169th methionine has recently been shown to be highly soluble but indistinguishable from the wild-type, 84-kDa ClpA in its ability to hydrolyze ATP and to support the casein-degrading activity of ClpP. Therefore, site-directed mutagenesis was performed to generate mutations in either of the two ATP-binding sites of ClpAT (i.e. to replace the Lys220 or Lys501 with Thr). ClpAT/K220T hydrolyzed ATP and supported the ClpP-mediated proteolysis 10-50% as well as ClpAT depending on ATP concentration, while ClpAT/K501T was unable to cleave ATP or to support the proteolysis. Without ATP, ClpAT and both of its mutant forms behaved as trimeric molecules as analyzed by gel filtration on a Sephacryl S-300 column. With 0.5 mM ATP, ClpAT and ClpAT/K501T became hexamers, but ClpAT/K220T remained trimeric. With 2 mM ATP, however, ClpAT/K220T also behaved as a hexamer. These results suggest that the first ATP-binding site of ClpA is responsible for hexamer formation, while the second is essential for ATP hydrolysis. When trimeric ClpAT/K220T was incubated with the same amount of hexameric ClpAT/K501T (i.e. at 0.5 mM ATP) and then subjected to gel filtration as above, a majority of ClpAT/K220T ran together with ClpAT/K501T as hexameric molecules. Furthermore, ClpAT/K501T in the mixture strongly inhibited the ability of ClpAT/K220T to cleave ATP and to support the ClpP-mediated proteolysis. Similar results were obtained in the presence of 2 mM ATP and also with the mixture with ClpAT. On the other hand, the ATPase activity of the mixture of ClpAT and ClpAT/K220T was significantly higher than the sum of that of each protein, particularly in the presence of 2 mM ATP, although its ability to support the proteolysis by ClpP remained unchanged. These results suggest that a rapid exchange of the subunits, possibly as a trimeric unit, occurs between the ClpAT proteins in the presence of ATP and leads to the formation of mixed hexameric molecules.
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PMID:Distinctive roles of the two ATP-binding sites in ClpA, the ATPase component of protease Ti in Escherichia coli. 771 11

We have measured the ATPase activity of squid optic lobe kinesin bound to polystyrene beads in the presence of microtubules. We find that there is a substantial increase (> 10-fold) in the microtubule-activated ATPase activity for bead-bound kinesin over free kinesin. We tentatively attribute such cargo-activated ATPase activity to the presence of a self-inhibited form of kinesin in solution, which becomes activated when bound to a bead in the presence of alpha-casein. Further experiments are underway to unravel this phenomenon and, in addition, to associate the traveling distance of beads with the observed ATPase rate to determine the average number of ATP consumed per kinesin-bead per micron of travel along microtubule.
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PMID:Cargo-activated ATPase activity of kinesin. 778 91

Among ADP-ribosyltransferases reported in eucaryotes, arginine-specific transferases from turkey erythrocytes, chicken heterophils and rabbit skeletal muscle have been purified and extensively studied. They were reported to modify a number of proteins in vitro. ADP-ribosylation of Ha-ras-p21 and transducin by the turkey erythrocyte transferase inhibits their GTPase and GTP-binding activities. Chicken heterophil enzyme modifies several substrate proteins for protein kinases and decreases the phosphate-acceptor activity. Rabbit skeletal muscle Ca(2+)-ATPase is inhibited by ADP-ribosylation catalyzed by the muscle transferase. Three transferases all ADP-ribosylate small molecular weight guanidino compounds such as arginine, arginine methylester and agmatine and poly-L-arginine and nuclear histones. However, the observation that muscle transferase did not ADP-ribosylate casein or actin, both of which can be modified by the heterophil transferase under the same conditions indicates that substrate specificity of these two enzymes are different. Substrate-dependent effects were observed with polyions of nucleotides such that polyanions stimulate the ADP-ribosylation of possible target protein, p33 by chicken heterophil transferase but has no effect on the modification of casein by the same enzyme.
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PMID:Target protein for eucaryotic arginine-specific ADP-ribosyltransferase. 789 52

The clpA gene that encodes the ATPase subunit of the ATP-dependent protease Ti (Clp) in Escherichia coli contains a putative internal translational initiation site. Here we show that mutagenesis of its 5'-end AUG codon resulted in an exclusive synthesis of the 65-kDa protein (ClpA65), while mutation at the internal 169th AUG codon (Met) to ACG (Thr) produced only the 84-kDa protein (ClpA84T). On the other hand, the cells carrying the wild-type clpA gene produced both the 84- and 65-kDa proteins (ClpA84/65). While the purified ClpA84T and ClpA84/65 hydrolyzed ATP nearly as well as the 84-kDa ClpA alone (ClpA84), ClpA65 cleaved ATP at a rate less than 5% of that by ClpA84. Unlike ClpA84 and ClpA84T, ClpA65 could not support the casein-degrading activity of ClpP. Furthermore, ClpA65 inhibited the proteolysis by the mixture of ClpP with ClpA84 or ClpA84T but not that with ClpA84/65, which could support the proteolytic activity of ClpP only about 40% as well as ClpA84. Nevertheless, ClpA65 showed little or no effect on the basal or protein-activated ATPase activity of ClpA84, ClpA84T, or ClpA84/65 alone or in the presence of ClpP. These results suggest that ClpA65 may interfere the interaction of ClpA84 or ClpA84T with ClpP and, hence, impair their assembly into an active form of the ATP-dependent protease Ti.
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PMID:The 65-kDa protein derived from the internal translational initiation site of the clpA gene inhibits the ATP-dependent protease Ti in Escherichia coli. 796 29

Escherichia coli ClpAP protease is an ATP-dependent protease composed of the proteolytic component ClpP and a regulatory ATPase, ClpA. ClpAP protease degraded a variety of peptide bonds in protein and peptide substrates at a slow rate (kcat < or = 30 min-1/subunit of ClpP), but showed very high activity (kcat > or = 800 min-1) for a synthetic peptide composed of the first 19 amino acids of ClpP, MSYSGERDNFAPHMALVPV, referred to as the propeptide. The propeptide was not degraded by ClpP alone, but was degraded in the presence of ClpA and ClpP. Degradation was activated by nonhydrolyzable analogs of ATP, indicating that nucleotide-promoted interaction between ClpA and ClpP is sufficient to activate ClpP for propeptide cleavage. The propeptide, as well as truncated forms lacking either the first 9 or the last 3 amino acids, was cleaved at the same Met-Ala bond at which autoprocessing occurs in vivo. No hydrolysis of FAPHMALVPV derivatives was observed when Met was replaced by Glu, Lys, Ser, Tyr, Ile, and D-Met, but cleavage at the same position did occur with Leu or Trp substitutions. A peptide composed of a tandem repeat of FAPHMALVPV was cleaved between both Met-Ala bonds (Kcat values > or = 39 min-1). Propeptides inhibited degradation of alpha-casein by competition for a binding site on ClpA, and they stimulated the basal ATPase activity of ClpA in the absence of ClpP. Peptides and protein substrates interact at an allosteric site on ClpA, which appears to be the site at which specific substrates are recognized by the Clp protease.
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PMID:Activity and specificity of Escherichia coli ClpAP protease in cleaving model peptide substrates. 802 81

The enzymatic activities of uPA, and a collagenase-like proteinase in the post-nuclear fraction of cell homogenates of a metastatic carcinomatous cell line following X-ray irradiation were examined by the use of chromogenic substrates and by casein- or gelatin-containing zymographies and electrophoretic gel stained with avidin-conjugated peroxidase. Enhanced activities were observed in these cells, while those of 5'nucleotidase and Na(+)-K(+)-ATPase were attenuated. A partial purification and characterization of the collagenase showed that it was able to hydrolyze the heat-denatured type-I collagen more efficiently than the native one. The activation of both uPA and collagenase enables an efficient degradation of matrix barrier proteins. These findings suggest that following a certain dose range of X-ray irradiation, tumor cells may increase their ability to migrate and invade through the enhancement of uPA and collagenase activities.
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PMID:The concomitant augmentation of urokinase-type plasminogen activator and collagenase-like proteinase activities in X-ray irradiated cells of a human metastatic carcinomatous line. 809

Paramecium dyneins were tested as substrates for phosphorylation by cAMP-dependent protein kinase, cGMP-dependent protein kinase, and two Ca(2+)-dependent protein kinases that were partially purified from Paramecium extracts. Only cAMP-dependent protein kinase caused significant phosphorylation. The major phosphorylated species was a 29 kDa protein that was present in both 22 S and 12 S dyneins; its phosphate-accepting activity peaked with 22 S dynein. In vitro phosphorylation was maximal at five minutes, then decreased. This decrease in phosphorylation was inhibited by the addition of vanadate or NaF. The 29 kDa protein was not phosphorylated by a heterologous cAMP-dependent protein kinase, the bovine catalytic subunit. Phosphorylation of dynein did not change its ATPase activity. In sucrose gradient fractions from the last step of dynein purification, phosphorylation by an endogenous kinase occurred. This phosphorylation could not be attributed to the small amounts of cAMP- and cGMP-dependent protein kinases known to be present, nor was it Ca(2+)-dependent. This previously uncharacterized ciliary protein kinase used casein as an in vitro substrate.
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PMID:In vitro phosphorylation of ciliary dyneins by protein kinases from Paramecium. 812 14

Activation of lipid peroxidation (LPP) processes in the hepatocytes of animals suffering from toxic hepatitis leads to disorders of membrane function and causes disorders of transports processes (activity of adenosine triphosphatase, active sodium transport) in them. Administration of prostaglandin E2 (PGE2) as a potent antioxidant simultaneously with casein hydrolysate to animals with experimental pathology intensifies the effect of the nitrous preparation and promotes normalization of the studied processes (LPP, adenosine triphosphatase activity, active sodium transport). Thus, through its action on LPP and the transport systems, PGE2 influences the effect of casein hydrolysate.
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PMID:[Biochemical mechanisms of the effect of prostaglandin E2 on the effect of parenteral nitrogenous nutrition]. 818 94

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