Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.6.3.1 (Mg2+-ATPase)
 1,484 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Actin, myosin, and a high molecular weight actin-binding protein were purified from chronic myelogenous leukemia (CML) leukocytes. CML leukocyte actin resembled skeletal muscle and other cytoplasmic actins by its subunit molecular weight, by its ability to polymerize in the presence of salts, and to activate the Mg2+-ATPase activity of rabbit skeletal muscle myosin. CML leukocyte myosin was similar to other vertebrate cytoplasmic myosins in having heavy chains and two light subunits. However, its apparent heavy-chain molecular weight and Stokes radius suggested that it was variably degraded during purification. Purified CML leukocyte myosin had average specific EDTA- AND Ca2+-activated ATPase activities of 125 and 151 nmol Pi released/mg protein per min, respectively and low specific Mg2+-ATPase activity. The Mg2+-ATPase activity of CML myosin was increased 200-fold by rabbit skeletal muscle F-actin, but the specific activity relative to that of actin-activated rabbit skeletal muscle myosin was low. CML leukocyte myosin, like other vertebrate cytoplasmic myosins, formed filaments in 0.1 M KCl solutions. Reduced and denatured CML leukocyte-actin-binding protein had a single high molecular weight subunit like a recently described actin-binding protein of rabbit pulmonary macrophages which promotes the polymerization and gelation of actin. Cytoplasmic extracts of CML leukocytes prepared with ice-cold 0.34-M sucrose solutions containing Mg2+-ATP, dithiothreitol, and EDTA at pH 7.0 underwent rapid gelation when warmed to 25 degrees C. Initially, the gel could be liquified by cooling to ice-bath temperature. With time, warmed cytoplasmic extract gels shrunk ("contracted") into aggregates. The following findings indicated that CML leukocyte actin-binding protein promoted the temperature-dependent gelation of actin in the cytoplasmic extracts and that CML leukocyte myosin was involved in the contraction of the actin gels: (a) Cytoplasmic extract gels initially contained actin as their major polypeptide component and consistent of tangled thin filaments; (b) Contracted aggregates of cytoplasmic extract gels contained by large quantities of myosin as well as actin; (c) Purified actin-binding protein underwent a temperature-dependent, reversible aggregation and caused low concentrations of purified muscle or CML leukocyte actins to gel in sucrose solutions; (d) The gels formed from purified actin plus purified actin-binding protein slowly contracted in the presence but not in the absence of purified CML leukocyte myosin; (e) Rabbit antiserum against purified CML leukocyte actin-binding protein but not against purified CML leukocyte myosin inhibited the gelation of warmed CML leukocyte extracts. Antiserum against CML leukocyte myosin had no effect on the gelation of CML leukocyte extracts but partially curtailed the contraction of the CML leukocyte extract gels and of gels formed from purified CML leukocyte actin-binding protein plus rabbit skeletal muscle actin.
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PMID:Interactions of actin, myosin, and an actin-binding protein of chronic myelogenous leukemia leukocytes. 13 21

The Wachstein-Meisel ATPase histochemical method has been previously used to demonstrate the ultrastructural localization of this enzyme in both whole liver and isolated plasma membranes following fixation in glutaraldehyde. In the present study biochemical assay, of liver plasma membrane enzymes following fixation in cold 2.5% glutaraldehyde showed that approximately 40% of Mg2+-ATPase, but only 4% of (Na+-K+)-ATPase activity remained in membranes from either control or ANIT-treated rats. In addition, 5'-nucleotidase activity was almost abolished by fixation. The present results indicate that the Wachstein-Meisel method, when applied to biliary canaliculi, can reliably be used to demonstrate the ultrastructural, histochemical localization of Mg2+-ATPase but not that of (NA+-K+)-ATPase. Furthermore, the method permits a valid comparison to be made of the relative Mg2+-ATPase activity in normal and chemically damaged biliary canaliculi.
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PMID:Liver plasma membrane enzyme activities following glutaraldehyde fixation. 13 43

A mutant Escherichia coli, selected for resistance to the antibiotic neomycin, was unable to utilize nonfermentable carbon sources for growth. Two strains were selected from this mutant on the basis of their ability to grow utilizing succinate as a carbon source. All three strains had approximately equal amounts of the Mg2+-adenosine triphosphatase (ATPase) (EC 3.6.1.3) protein, but the activity of the enzyme differed in each strain. The Mg2+-ATPase from each of the three strains lost activity upon solubilization and appeared to undergo rapid dissociation once solubilized. This dissociation is similar to that described for the wild type after cold exposure.
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PMID:Properties of Escherichia coli mutants with alterations in Mg2+-adenosine triphosphatase. 13 56

Subcellular fraction (brush border, mitochondria, microsomes and plasma membranes) are isolated from the rat intestinal epithelial cells. A comparison was made between the effect of cold storage, freeze-thawing, heating and of some chemicals (DMSO, DTT, glycerol, sucrose) on the stability of Mg2+ and (Na+-K+) dependent ATPases in these fractions in order to determine possible difference linked to the localization in the enterocyte. Enzymatic activities were found more stable at -20 degrees C than at +4 degrees C. Microsomal (Na+-K+)-ATPase increased in activity until the 8th day, then declined. Brush border (Na+-K+)-ATPase was the least resistant of all fractions. For Mg2+-ATPase, that from mitochondria was that had lost much more activity (84%) in 15 days at +4 degrees C. With freeze-thawing there was a comparable decrease in all activities (20-35%). by heating between 35 and 60 degrees C, Mg2+-ATPase was shown to be more heat resistant than (Na+-K+)-ATPase. The addition of some stabilizing chemicals (DMSO, glycerol, sucrose) improved the heat stability of the two enzymes: better results were obtained with glycerol for Mg2+-ATPase and sucrose for (Na+-K+)-ATPase. These differences might be due to the compositon in membraine lipids or to the nature of the enzymes studied.
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PMID:Studies on intestinal adenosine triphosphatases. II. Stabilitiies in different rat subcellular fractions. 14 Aug

Radiation inactivation technique was employed to measure the functional size of adenosine triphosphatase of spinach chloroplasts. The functional size for acid-base-induced ATP synthesis was 450 +/- 24 kilodaltons; for phenazine methosulfate-mediated ATP synthesis, 613 +/- 33 kilodaltons; and for methanol-activated ATP hydrolysis, 280 +/- 14 kilodaltons. The difference (170 +/- 57 kilodaltons) between 450 +/- 24 and 280 +/- 14 kilodaltons is explained to be the molecular mass of proton channel (coupling factor 0) across the thylakoid membrane. Our data suggest that the stoichiometry of subunits I, II, and III of coupling factor 0 is 1:2:15. Ca2+- and Mg2+-ATPase activated by methanol, heat, and trypsin digestion have a similar functional size. However, anions such as SO3(2-) and CO3(2-) increased the molecular mass for both ATPase's (except trypsin-activated Mg2+-ATPase) by 12-30%. Soluble coupling factor 1 has a larger target size than that of membrane-bound. This is interpreted as the cold effect during irradiation.
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PMID:Radiation inactivation analysis of chloroplast CF0-CF1 ATPase. 296 17

Normal adult albino and Sprague-Dawley rats, under intraperitoneal Nembutal anesthesia, were used to demonstrate enzymatic activity in the choroid plexus and ventricular ependyma. The brain tissues were perfused or immersed with cold 2% glutaraldehyde and 8% sucrose in 0.1 M cacodylate buffer (pH 7.2-7.4) for 30 min and washed overnight in the same buffer solution., The choroid plexus (lateral and fourth ventricles) and ventricular ependyma (lateral ventricle) were trimmed from the fixed and washed brain tissues, which were frozen and sectioned. For histo- and cyto-chemical study, the sections were immersed in the following incubation media; for Na+, K+-ATPase (ouabain-sensitive, K+-dependent, p-nitrophenylphosphatase: p-NPPase) according to the one-step method of Mayahara et al. (1978): for Mg2+- ATPase, Wachstein-Meisel's incubation medium (1957); for adenylate cyclase (AC), following Araki and Saito's lead citrate method (1979). The cytochemical findings gave the following results. In the choroid plexus, the ouabain-sensitive electron-dense reaction products of NA+, K+-ATPase (p-NPPase) were strongly positive in the microvilli and along the inner surface of microvilli, without showing any Mg2+-ATPase and AC activities, and all three enzymatic activities were positive along the basal plasmalemmas and negative along the lateral and apical (not including microvilli) plasmalemmas. In the ventricular ependyma, Na+,K+-ATPase (P-NPPase) activity was not found, and the reaction product of AC was observed on the apical plasmalemmas and those of Mg2+-ATPase along the basal plasmalemmas. These cytochemical findings are helpful in understanding the regulation of cerebrospinal fluid production through Na+, K+-ATPase (p-NPPase) and cyclic AMP (AC).
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PMID:Cytochemical study on enzyme activity associated with cerebrospinal fluid secretion in the choroid plexus and ventricular ependyma. 611 20

The oxysterol binding protein homologue Kes1p has been implicated in nonvesicular sterol transport in Saccharomyces cerevisiae. Kes1p also represses formation of protein transport vesicles from the trans-Golgi network (TGN) through an unknown mechanism. Here, we show that potential phospholipid translocases in the Drs2/Dnf family (type IV P-type ATPases [P4-ATPases]) are downstream targets of Kes1p repression. Disruption of KES1 suppresses the cold-sensitive (cs) growth defect of drs2Delta, which correlates with an enhanced ability of Dnf P4-ATPases to functionally substitute for Drs2p. Loss of Kes1p also suppresses a drs2-ts allele in a strain deficient for Dnf P4-ATPases, suggesting that Kes1p antagonizes Drs2p activity in vivo. Indeed, Drs2-dependent phosphatidylserine translocase (flippase) activity is hyperactive in TGN membranes from kes1Delta cells and is potently attenuated by addition of recombinant Kes1p. Surprisingly, Drs2p also antagonizes Kes1p activity in vivo. Drs2p deficiency causes a markedly increased rate of cholesterol transport from the plasma membrane to the endoplasmic reticulum (ER) and redistribution of endogenous ergosterol to intracellular membranes, phenotypes that are Kes1p dependent. These data suggest a homeostatic feedback mechanism in which appropriately regulated flippase activity in the Golgi complex helps establish a plasma membrane phospholipid organization that resists sterol extraction by a sterol binding protein.
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PMID:Control of protein and sterol trafficking by antagonistic activities of a type IV P-type ATPase and oxysterol binding protein homologue. 1940 96

The generation and analysis of clones of cells with a genotype different from the rest of an organism has been used for studying molecular mechanisms underlying development. Genetic mosaics in Drosophila typically involve derivation of homozygous daughter cells from heterozygous precursors through mitotic recombination. MARCM (mosaic analysis with a repressible cell marker) couples loss of heterozygosity with derepression of a marker gene. This permits unique labeling of specific homozygous daughter cells, and thus makes mosaic analysis possible in the complex nervous system. The principle of MARCM involves the generation of GAL80-minus homozygous daughter cells in otherwise heterozygous tissues, therefore allowing GAL4-dependent activation of upstream activation sequence (UAS)-reporter specifically in the homozygous cells of interest. To make MARCM clones, it is necessary to generate organisms carrying at least five genetic elements (flippase [FLP], flippase recognition targets [FRTs], tubP-GAL80, GAL4, and UAS-marker) in specific configurations. Induction of FLP in neural precursors can be temporally controlled using a heat-shock promoter or spatially regulated using a tissue-specific promoter. Mitotic recombination in a neuroblast (NB) may yield a multicellular NB clone (progeny of the renewed NB) or a two-cell clone (progeny of the derived ganglion mother cell [GMC]). Single-cell clones can be obtained following mitotic recombination in GMCs. Phenotypic analysis of mosaic brains can be greatly simplified using a GAL4 driver that is only expressed in neurons of interest. One can also mark different subcellular structures of the clones using distinct UAS reporters. This protocol outlines the steps involved in standard MARCM analysis.
Cold Spring Harb Protoc 2012 Dec 01
PMID:Generation of standard wild-type MARCM clones for analysis of drosophila brain development. 2320 32

Genetic mosaics in Drosophila typically involve derivation of homozygous daughter cells from heterozygous precursors through mitotic recombination. MARCM (mosaic analysis with a repressible cell marker) couples loss of heterozygosity with derepression of a marker gene, permitting unique labeling of specific homozygous daughter cells. The generation of GAL80-minus homozygous daughter cells in otherwise heterozygous tissues allows GAL4-dependent activation of upstream activation sequence (UAS)-reporter specifically in the homozygous cells of interest. To make MARCM clones, organisms must carry at least five genetic elements (flippase [FLP], flippase recognition targets [FRTs], tubP-GAL80, GAL4, and UAS-marker) in specific configurations. One major application of MARCM, as described here, is to study cell-autonomous function(s) of a gene within single cells or a group of cells in otherwise unperturbed organisms. A mutation of interest distal to one FRT site is put in trans to a tubP-GAL80-containing chromosome arm that carries the same FRT. The resulting MARCM clones, which are negative for tubP-GAL80 and thus specifically marked, will become homozygous for the mutation in otherwise heterozygous organisms. By including a UAS-transgene, one can perform rescue experiments in the mutant MARCM clones. Conversely, if the mutation is placed on the same chromosome arm as tubP-GAL80, MARCM-labeled cells will be homozygous wild-type and may lie adjacent to sister cells that are homozygous mutant. This variant, called reverse MARCM, allows one to determine non-cell-autonomous effects of a mutation.
Cold Spring Harb Protoc 2013 Jan 01
PMID:Reverse genetics by loss-of-function mosaic analysis in Drosophila. 2328 32

Genetic mosaics in Drosophila typically involve derivation of homozygous daughter cells from heterozygous precursors through mitotic recombination. MARCM (mosaic analysis with a repressible cell marker) couples loss of heterozygosity with derepression of a marker gene, permitting unique labeling of specific homozygous daughter cells. The generation of GAL80-minus homozygous daughter cells in otherwise heterozygous tissues allows GAL4-dependent activation of upstream activation sequence (UAS)-reporter specifically in the homozygous cells of interest. To make MARCM clones, organisms must carry at least five genetic elements (flippase [FLP], flippase recognition targets [FRTs], tubP-GAL80, GAL4, and UAS-marker) in specific configurations. In neurons whose progenitors can be efficiently targeted for mitotic recombination, genetic mosaic screens can be used to systematically uncover cell-autonomous genes that are required for development or function. This technique involves the generation of numerous FRT lines carrying various independent mutations, followed by derivation and phenotypic analysis of MARCM clones using these mutant FRT lines in combination with an MARCM-enabling stock that carries all the other genetic elements required for MARCM. Mutants of interest are recovered based on the MARCM phenotypes, which are imaged live using diverse fluorescent markers. Mutant genes that underlie the phenotypes of interest can then be identified by conventional genetics including derivation and analysis of series of recombinant chromosomes. Besides chemical mutagenesis, genes on a particular FRT chromosome may be randomly disrupted by P element insertion. This protocol describes procedures specifically used for genetic mosaic screens in the mushroom bodies (MBs).
Cold Spring Harb Protoc 2013 Jan 01
PMID:Genetic mosaic screens in Drosophila mushroom bodies. 2328 33


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