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)

We recently reported that autophosphorylated rat brain protein kinase C (PKC) catalyzes a Ca2(+)- and phosphatidylserine- (PS-) dependent ATPase reaction. The Ca2(+)- and PS-dependent ATPase and histone kinase reactions of PKC each had a Km app(ATP) of 6 microM. Remarkably, the catalytic fragment of PKC lacked detectable ATPase activity. In this paper, we show that subsaturating concentrations of protein substrates accelerate the ATPase reaction catalyzed by PKC and that protein and peptide substrates of PKC induce ATPase catalysis by the catalytic fragment. At subsaturating concentrations, histone III-S and protamine sulfate each accelerated the ATPase activity of PKC in the presence of Ca2+ and PS by as much as 1.5-fold. At saturating concentrations, the protein substrates were inhibitory. Poly(L-lysine) failed to accelerate the ATPase activity, indicating that the acceleration observed with histone III-S and protamine sulfate was not simply a result of their gross physical properties. Furthermore, histone III-S induced the ATPase activity of the catalytic fragment of PKC, at both subsaturating and saturating histone concentrations. The induction of ATPase activity was also elicited by the peptide substrate Arg-Arg-Lys-Ala-Ser-Gly-Pro-Pro-Val, when the peptide was present at concentrations near its Km app. The induction of the ATPase activity by the nonapeptide provides strong evidence that the binding of phospho acceptor substrates to the active site of PKC can stimulate ATP hydrolysis. Taken together, our results indicate that PKC-catalyzed protein phosphorylation is inefficient, since it is accompanied by Pi production.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Stimulation of the ATPase activity of rat brain protein kinase C by phospho acceptor substrates of the enzyme. 184 1

Previous work suggested that the structural gene for the A system transporter and the mRNA for the alpha subunit of the Na+,K(+)-ATPase in Chinese hamster ovary cells CHO-K1 [wild type (WT)] are coordinately controlled by regulatory gene R1. This conclusion was based on analysis of a mutant for the A system, alar4. This mutant had a constitutive level of A system transport activity equal to the level found in derepressed WT cells and a 4 times increase in abundance of the alpha 1 subunit of Na+,K(+)-ATPase mRNA over that found in repressed WT. The level of Na+ per cell in alar4 was not significantly greater than that found in the WT. To further characterize the likely coregulation of both genes, we have studied the A system activity and Na+,K(+)-ATPase mRNA alpha 1-subunit levels in cells grown under various conditions that result in repression or derepression of the A system in the WT. System A activity increased up to 2-3 times the basal transport rate (repressed state) and Na+,K(+)-ATPase mRNA alpha 1-subunit levels showed a 3-fold increase after amino acid starvation (derepressed state). These changes occurred along with a decrease in intracellular Na+ levels. N-Methyl-alpha-aminoisobutyric acid and beta-alanine, previously shown to be corepressors for the A system, prevented to a similar extent A system derepression and Na+,K(+)-ATPase mRNA alpha 1-subunit accumulation. On the other hand, phenylalanine and lysine, amino acids that are not corepressors of the A system, failed to significantly prevent derepression of both genes. Hybrids between the WT and alar4 have the phenotype of the WT when grown under repressed conditions. These results give further support to the proposition that both the A system transporter and mRNA for the alpha 1 subunit of the Na+,K(+)-ATPase are coordinately controlled by regulatory gene R1 and elevated Na+ concentrations are not involved. No Na+,K(+)-ATPase activity was detected in derepressed cells. Activity was restored by the addition of monensin. However, this activity was no greater than that obtained in repressed cells. Indications are that the reduced Na+ content in derepressed cells inhibits Na+,K(+)-ATPase activity and that conditions that favored derepression do not allow for de novo synthesis of the Na+,K(+)-ATPase.
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PMID:Evidence for coordinate regulation of the A system for amino acid transport and the mRNA for the alpha 1 subunit of the Na+,K(+)-ATPase gene in Chinese hamster ovary cells. 184 56

The rat gastric H+,K(+)-ATPase alpha subunit gene was cloned and the nucleotide sequence of its 5'-upstream region was determined. Sequence comparison with the corresponding part of the human gene indicated the presence of highly conserved regions which may be important for specific transcription of the alpha subunit in gastric parietal cells. The amino-terminal sequence (Met-Gly-Lys-Ala-Glu-) of the rat enzyme was similar to those of the pig and human enzymes. The gene organization of the rat enzyme was also similar to that of the human gene: introns 1, 2 and 9 were located in exactly the same positions as those in the human gene, and, as in the latter, exon 6 was not separated by an intron. The sequences of introns 1 and 2 were highly conserved among the rat, human and pig genes, but were entirely different from those of Na+,K(+)-ATPase catalytic subunit genes. Northern blot hybridization indicated that the gene was transcribed only in gastric mucosa.
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PMID:Control region and gastric specific transcription of the rat H+,K(+)-ATPase alpha subunit gene. 184 40

Normally trypsin has negligible activity after being dissolved in sodium dodecyl sulfate (SDS), and so it has had little utility for proteolytic fingerprinting during gel electrophoresis. Here it is demonstrated that trypsin retained activity in SDS if it was first complexed to either of two soybean-derived protease inhibitors: trypsin inhibitor (Kunitz) or trypsin-chymotrypsin inhibitor (Bowman-Birk). The inhibitors alone did not cause proteolysis. Heating or acidification in SDS inactivated the inhibitor-dependent tryptic activity, as did prior treatment with tosyl lysine chloromethyl ketone, a covalent affinity reagent for trypsin. Quenching of samples with acid at intervals prior to gel electrophoresis revealed that proteolysis did not occur in sample buffer (pH 6.8), but only at higher pH and during gel electrophoresis. Exposure of trypsin to SDS prior to addition of trypsin inhibitor resulted in an irreversible loss of activity with a half-life of about 10 s. It is proposed that the trypsin inhibitors stabilize trypsin by retarding its denaturation in SDS. The substrate for these experiments was the alpha subunit of the Na,K-ATPase. The same pattern of Na,K-ATPase fragments was obtained with bovine and porcine trypsin and with rat and porcine Na,K-ATPases. Different fragments resulted when chymotrypsin or elastase were substituted for trypsin; these proteases were active in the absence of an inhibitor, and were not markedly stabilized by interaction with soybean trypsin-chymotrypsin inhibitor (Bowman-Birk).
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PMID:Trypsin inhibitor paradoxically stabilizes trypsin activity in sodium dodecyl sulfate, facilitating proteolytic fingerprinting. 186 77

Caldesmon is a major actin-binding protein identified in smooth muscle and many non-muscle cells. It also interacts with calmodulin and a number of other acidic proteins. We have shown previously that the polypeptide stretch from Val629 to Ser666 near the C terminus contains a calmodulin binding site (Wang, C.-L. A., Wang, L.-W. C., Xu, S., Lu, R. C., Saavedra-Alanis, V., and Bryan, J. (1991) J. Biol. Chem. 266, 9166-9172). On the other hand, Bartegi et al. (Bartegi, A., Fattoum, A., Derancourt, J., and Kassab, R. (1990) J. Biol. Chem. 265, 15231-15238) reported a cyanogen bromide fragment beginning at Trp659 which is also capable of binding both calmodulin and actin. A comparison of the overlapping sequence between these two peptides suggests that this calmodulin binding site is localized in a 7-residue segment, 659Trp-Glu-Lys-Gly-Asn-Val-Phe665. We have chemically synthesized an 18-residue peptide (GS17C, from Gly651 to Ser667 with an added cysteine at the C terminus) that contains this segment. This peptide was purified by high performance liquid chromatography and labeled with fluorescent probes at the terminal cysteine residue. We found that GS17C indeed binds calmodulin in a Ca(2+)-dependent manner (Kd = 8 x 10(-7) M) and appears to compete with caldesmon. Interestingly, this synthetic peptide also co-sediments with F-actin, binding to actin being displaceable by calmodulin, as in the case of the native caldesmon. But GS17C does not have any effect on the actomyosin ATPase activity, indicating that this peptide segment does not contain the inhibitory region.
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PMID:A calmodulin-binding peptide of caldesmon. 193 4

We have cloned and sequenced over 9 kb of the mitochondrial genome from the sea star Pisaster ochraceus. Within a continuous 8.0-kb fragment are located the genes for NADH dehydrogenase subunits 1, 2, 3, and 4L (ND1, ND2, ND3, and ND4L), cytochrome oxidase subunits I, II, and III (COI, COII, and COIII), and adenosine triphosphatase subunits 6 and 8 (ATPase 6 and ATPase 8). This large fragment also contains a cluster of 13 tRNA genes between ND1 and COI as well as the genes for isoleucine tRNA between ND1 and ND2, arginine tRNA between COI and ND4L, lysine tRNA between COII and ATPase 8, and the serine (UCN) tRNA between COIII and ND3. The genes for the other five tRNAs lie outside this fragment. The gene for phenylalanine tRNA is located between cytochrome b and the 12S ribosomal genes. The genes for tRNA(glu) and tRNA(thr) are 3' to 12S ribosomal gene. The tRNAs for histidine and serine (AGN) are adjacent to each other and lie between ND4 and ND5. These data confirm the novel gene order in mitochondrial DNA (mtDNA) of sea stars and delineate additional distinctions between the sea star and other mtDNA molecules.
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PMID:Nucleotide sequence of nine protein-coding genes and 22 tRNAs in the mitochondrial DNA of the sea star Pisaster ochraceus. 197 16

The phosphorylation in vivo and in vitro of the arginine-ornithine and the lysine-arginine-ornithine (LAO) periplasmic transport proteins of Escherichia coli K-12 was previously reported (Celis, R. T. F. (1984) Eur. J. Biochem. 145, 403-411). The phosphorylative reaction required ATP (as a direct energy donor), Mg2+, and a kinase that can be released by osmotic shock treatment of the cells. The enzyme was purified to electrophoretic homogeneity. The enzyme exhibited an ATPase activity and a kinase activity. Polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate gave an apparent molecular weight of 43,000 for the enzyme. The native protein showed the same molecular weight, suggesting that the protein is a monomer. The protein showed an apparent isoelectric point of 4.8 on isoelectric focusing. The two enzymatic reactions required a divalent cation and the apparent Km value for Mg2+ for the kinase activity was 0.5 mM. Mn2+ and Co2+ served as well as Mg2+, whereas Zn2+ and Ca2+ did not support activity. The ATPase activity of the enzyme yielded an apparent Km value for ATP of 50 microM. A similar value, Km of 100 microM, was calculated for the kinase activity with different concentrations of ATP. The enzyme showed a pH optimum of 7.3.
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PMID:Purification and properties of a kinase from Escherichia coli K-12 that phosphorylates two periplasmic transport proteins. 210 51

Photoaffinity labeling of the active site of the yeast plasma membrane H(+)-ATPase has been studied with 2-azido-AMP and 2-azido-ATP. The ATPase activity of the enzyme decreases as the time of photolysis of the photoactive nucleotides in the presence of the enzyme increases. The covalent incorporation of [alpha-32P]2-azido-AMP into the enzyme and the inhibition of ATPase activity have comparable time courses. ATP protects the ATPase from incorporation of and photoinactivation by 2-azido-ATP or 2-azido-AMP. In the dark, 2-azido-ATP inhibits the ATPase at concentrations comparable to the apparent Michaelis constant for MgATP. After photolysis and proteolysis of the protein, three overlapping peptides labeled by the nucleotide analogues were purified by reversed-phase high performance liquid chromatography and sequenced. The peptides are derived from a region of the ATPase that is highly conserved in related cation pumps forming a phosphorylated intermediate during the catalytic cycle. Labeling with both nucleotide analogues occurs in peptides containing residues from aspartate 560 to lysine 566. The amino acids in this region conform to a consensus sequence for ATP binding derived from phosphofructokinase.
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PMID:The ATP binding site of the yeast plasma membrane proton-translocating ATPase. 213 52

Bacterial periplasmic transport systems require the function of a specific substrate-binding protein, located in the periplasm, and several cytoplasmic membrane transport components. In Escherichia coli K-12, the arginine-ornithine transport system requires an arginine-ornithine-binding protein and the lysine-arginine-ornithine (LAO) transport system includes a LAO-binding protein. Both periplasmic proteins can be phosphorylated by a single kinase. The enzyme exhibits a kinase activity and an ATPase activity. A mutant, defective in the phosphorylation of the arginine-ornithine and the LAO periplasmic proteins, was isolated and characterized. The defective enzymatic activity was reflected in substantially reduced levels of transport activity of the periplasmic transport systems that include each of the binding proteins. The binding proteins, extracted from the mutant, showed no detectable alterations in terms of quantity, electrophoretic mobility, or affinity constants. An apparent Km value of 1.0 mM was calculated for the ATPase activity of the defective enzyme. The ATPase activity of the wild-type enzyme yielded an apparent Km value of 50 microM. The amount of inorganic phosphate incorporated in vivo and in vitro into the binding proteins by the activity of the defective kinase was reduced to very low levels. A structural gene for the phosphorylating enzyme was located near the serA marker on the linkage map of E. coli. These results indicate that phosphorylation of the periplasmic transport protein is obligatorily linked to the normal function of the periplasmic transport system.
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PMID:Mutant of Escherichia coli K-12 with defective phosphorylation of two periplasmic transport proteins. 213 58

The three beta subunits of the isolated Escherichia coli F1-ATPase react independently with chemical reagents (Stan-Lotter, H. and Bragg, P.D. (1986) Arch. Biochem. Biophys. 284, 116-120). Thus, one beta subunit is readily cross-linked to the epsilon subunit, Another reacts with N,N'-dicyclohexylcarbodiimide (DCCD), and the third one is modified on a lysine residue by 4-chloro-7-nitrobenzofurazan (NbfCl). The binding site for the ATP analog, 2-azido-ATP, was not associated with a specific type of beta subunit (Bragg, P.D. and Hou, C. (1989) Biochim. Biophys. Acta 974, 24-29). We now show that this binding site is a catalytic site as opposed to a noncatalytic nucleotide-binding site. NbfCl reacted with a tyrosine residue on the DCCD-reacting beta subunit in contrast to the different subunit location of the lysine residue labeled by the reagent. Thus, O to N transfer of the Nbf group in the free F1-ATPase involves transfer between subunits. The chemical labelling pattern of membrane-bound F1-ATPase differed from that of free F1. The strict asymmetry of labeling of the free F1-ATPase was not observed. Thus, double labeling of beta subunits by several reagents was found. This suggests that the asymmetry was not induced by chemical modification, but is inherent in the structure of the ATPase.
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PMID:Reaction of membrane-bound F1-adenosine triphosphatase of Escherichia coli with chemical ligands and the asymmetry of beta subunits. 213 13

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