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)

Ciliary or flagellar movement is the model of microtubule-dependent motility, the best studied at the molecular level. It is based on the relative sliding of outer doublets of microtubules that are linked at their proximal end to the basal structure and interconnected by associated proteins, among which dynein ATPase is at the origin of the movement. It is regulated from inside and outside media by various diffusible factors such as Ca2+, cyclic adenosine monophosphate (cAMP), polypeptides and so on (see other conferences presented during this meeting). Other motility processes are based on microtubules: vesicle and organelle transport through the cytoplasm (axonal flow in neurons, pigment granule movements in fish chromatophores, movements of particles along heliozoan axopods, etc.) could be mediated by microtubule motors such as kinesin or MAP 1C. Kinesin and MAP 1C, like dynein, are proteins that bind to microtubules and show an ATPase activity associated with force production. They differ from each other by their structure, and biochemical and pharmacological properties. The movements of chromosomes during mitosis and meiosis have long been studied, but are still poorly understood at the molecular level; this topic will be discussed in the light of recent data. Other constituents of the cytoskeleton are certainly involved in cellular motility: actin microfilaments and their motor myosin, intermediate filaments, non-actin filaments, all organized around the Microtubule Organizing Center (MTOC). As more information becomes available, it seems increasingly obvious that these various networks are closely interconnected and that each component probably modulates, resists, or favors properties of its partners, contributing to cellular and intracellular motility.
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PMID:From cilia and flagella to intracellular motility and back again: a review of a few aspects of microtubule-based motility. 246 57

Fast axonal transport is manifested at the sub-cellular level as the anterograde or retrograde movement of membrane-bounded organelles along microtubules. Earlier work implicated the protein kinesin as the motor for anterograde axonal transport. More recent work indicates that a brain microtubule-associated protein, MAP 1C, is responsible for retrograde transport. Of additional interest, MAP 1C has been found to be a cytoplasmic form of the ciliary and flagellar ATPase dynein, indicating a much more general functional role for this enzyme in cells than had been suspected.
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PMID:The role of dynein in retrograde axonal transport. 246 13

The microtubule-dynein complex consisting of 22S dynein from Tetrahymena cilia and MAP-free microtubules was subjected to treatment with various concentrations of 1-ethyl-3-[3-(dimethylamino)-propyl]carbodiimide (EDC), a zero-length cross-linker, at 28 degrees C for 1 h. Following cross-linking of the microtubule-dynein complex, nearly all of the ATPase activity cosedimented with the microtubules in the presence of ATP. Electron microscopic observation by negative staining revealed that, following treatment with 1 mM EDC, the complex did not dissociate in the presence of ATP, although the dynein decoration pattern was disordered. The complex treated with 3 mM EDC exhibited normal microtubule-dynein patterns even after the addition of ATP. The ATPase activity of the microtubule-dynein complex was enhanced about 30-fold by the treatment with 1-3 mM EDC. These results indicate that the ATPase activation was caused by the close proximity of the dynein ATPase sites to the microtubules and provide further support for the functional interaction of all three dynein heads with the microtubule. The maximal specific activity was 12 mumol min-1 (mg of dynein)-1, corresponding to a turnover rate of 150 s-1, which may be the rate-limiting step at infinite microtubule concentration and may represent the maximum rate of force production in the axoneme.
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PMID:Activation of the dynein adenosinetriphosphatase by cross-linking to microtubules. 253 Oct 6

Kinesin from porcine brain was prepared by a procedure based on the strong binding of the protein to microtubules in the presence of sodium fluoride and ATP. The protocol reduces the requirement for taxol and AMP-PNP. The kinesin is active in terms of its ability to move microtubules on glass slides and its ATPase. The ATPase of this kinesin is about 8 nmol/min/mg; it is activated to 19 nmol/min/mg in the presence of microtubules. The relationship between gliding velocity and ATP concentration follows Michaelis-Menten kinetics. Using the motility assay, the maximal velocity is 0.78 micron/sec, and the Km value is 150 microM for ATP. For GTP the corresponding values are 0.38 micron/sec and 1.7 mM. ADP is a competitive inhibitor (Ki = 0.29 mM). Crude preparations of kinesin do not support motility on glass slides, whereas gel-filtered kinesin does. A search for potential inhibitory factors showed that one of them is MAP2; however, its inhibitory effect becomes visible only in certain conditions. MAP2 bound to microtubules does not inhibit kinesin-induced motility. However, when MAP2 and kinesin are preadsorbed to the glass surface independently of microtubules, MAP2 prevents the interaction of kinesin with microtubules, as if it formed a "lawn" that acted as a spacer and thus repelled the MAP-free microtubules or crosslinked the MAP-containing ones. The repelling effect of MAP2 domains (projection or assembly fragments obtained by chymotryptic cleavage) added separately is less pronounced and can be overcome by kinesin. These results reinforce the view of MAP2 as a spacer molecule.
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PMID:Interaction between kinesin, microtubules, and microtubule-associated protein 2. 253 84

A reconstituted system for examining directed organelle movements along purified microtubules has been developed. Axoplasm from the squid giant axon was separated into soluble supernatant and organelle-enriched fractions. Movement of axoplasmic organelles along MAP-free microtubules occurred consistently only after addition of axoplasmic supernatant and ATP. The velocity of such organelle movement (1.6 micron/sec) was the same as in dissociated axoplasm. The axoplasmic supernatant also supported movement of microtubules along a glass surface and movement of carboxylated latex beads along microtubules at 0.5 micron/sec. The direction of microtubule movement on glass was opposite to that of organelle and bead movement on microtubules. The factors supporting movements of microtubules, beads, and organelles were sensitive to heat, trypsin, AMP-PNP and 100 microM vanadate. All of these movements may be driven by a single, soluble ATPase that binds reversibly to organelles, beads, or glass and generates a translocating force on a microtubule.
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PMID:Organelle, bead, and microtubule translocations promoted by soluble factors from the squid giant axon. 257 87

We recently found that the brain cytosolic microtubule-associated protein 1C (MAP 1C) is a microtubule-activated ATPase, capable of translocating microtubules in vitro in the direction corresponding to retrograde transport. (Paschal, B. M., H. S. Shpetner, and R. B. Vallee. 1987b. J. Cell Biol. 105:1273-1282; Paschal, B. M., and R. B. Vallee. 1987. Nature [Lond.]. 330:181-183.). Biochemical analysis of this protein (op. cit.) as well as scanning transmission electron microscopy revealed that MAP 1C is a brain cytoplasmic form of the ciliary and flagellar ATPase dynein (Vallee, R. B., J. S. Wall, B. M. Paschal, and H. S. Shpetner. 1988. Nature [Lond.]. 332:561-563). We have now characterized the ATPase activity of the brain enzyme in detail. We found that microtubule activation required polymeric tubulin and saturated with increasing tubulin concentration. The maximum activity at saturating tubulin (Vmax) varied from 186 to 239 nmol/min per mg. At low ionic strength, the Km for microtubules was 0.16 mg/ml tubulin, substantially lower than that previously reported for axonemal dynein. The microtubule-stimulated activity was extremely sensitive to changes in ionic strength and sulfhydryl oxidation state, both of which primarily affected the microtubule concentrations required for half-maximal activation. In a number of respects the brain dynein was enzymatically similar to both axonemal and egg dyneins. Thus, the ATPase required divalent cations, calcium stimulating activity less effectively than magnesium. The MgATPase was inhibited by metavandate (Ki = 5-10 microM for the microtubule-stimulated activity), 1 mM NEM, and 1 mM EHNA. In contrast to other dyneins, the brain enzyme hydrolyzed CTP, TTP, and GTP at higher rates than ATP. Thus, the enzymological properties of the brain cytoplasmic dynein are clearly related to those of other dyneins, though the brain enzyme is unique in its substrate specificity and in its high sensitivity to stimulation by microtubules.
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PMID:Characterization of the microtubule-activated ATPase of brain cytoplasmic dynein (MAP 1C). 297 Oct 69

Microtubules are involved in several forms of intracellular motility, including mitosis and organelle movement. Fast axonal transport is a highly ordered form of organelle motility that operates in both the anterograde (outwards from the cell body) and retrograde (from the periphery towards the cell body) direction. Similar microtubule-associated movement is observed in non-neuronal cells, and might be involved in secretion, endocytosis and the positioning of organelles within the cell. Kinesin is a mechanochemical protein that produces force along microtubules in an anterograde direction. We recently found that the brain microtubule-associated protein MAP 1C (ref. 7) is a microtubule-activated ATPase and, like kinesin, can translocate microtubules in an in vitro assay for microtubule-associated motility. MAP 1C seemed to be related to the ciliary and flagellar ATPase, dynein, which is thought to produce force in a direction opposite to that observed for kinesin. Here we report that MAP 1C, in fact, acts in a direction opposite to kinesin, and has the properties of a retrograde translocator.
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PMID:Retrograde transport by the microtubule-associated protein MAP 1C. 367 Apr 2

Yeast cells can respond and adapt to osmotic stress. In our attempt to clarify the molecular mechanisms of cellular responses to osmotic stress, we cloned seven cDNAs for hyperosmolarity-responsive (HOR) genes from Saccharomyces cerevisiae by a differential screening method. Structural analysis of the clones revealed that those designated HOR1, HOR3, HOR4, HOR5 and HOR6 encoded glycerol-3-phosphate dehydrogenase (Gpd1p), glucokinase (Glk1p), hexose transporter (Hxt1p), heat-shock protein 12 (Hsp12p) and Na+, K+, Li(+)-ATPase (Ena1p), respectively. HOR2 and HOR7 corresponded to novel genes. Gpd1p is a key enzyme in the synthesis of glycerol, which is a major osmoprotectant in S. cerevisiae. Cloning of HOR1/GPD1 as a HOR gene indicates that the accumulation of glycerol in yeast cells under hyperosmotic stress is, at least in part, caused by an increase in the level of GPDH protein. We performed a series of Northern blot analyses using HOR cDNAs as probes and RNAs prepared from cells grown under various conditions and from various mutant cells. The results suggested that all the HOR genes are regulated by common signal transduction pathways. However, the fact that they exhibited certain distinct responses indicated that they might also be regulated by specific pathways in addition to the common pathways. Ca2+ seemed to be involved in the signaling systems. In addition, Hog1p, one of the MAP kinases in yeast, appeared to be involved in the regulation of expression of HOR genes, although its function seemed to be insufficient for the overall regulation of expression of these genes.
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PMID:Cloning and characterization of seven cDNAs for hyperosmolarity-responsive (HOR) genes of Saccharomyces cerevisiae. 750 Sep 33

Cardiac functions are regulated by both contractile proteins and calcium regulatory proteins. In cardiac hypertrophy, an increase in protein synthesis can be partitioned into an increase in both capacity and efficiency of synthesis. beta-cardiac myosin heavy chain (beta-MHC) isoform is predominantly expressed while alpha-MHC is suppressed in pressure overload hypertrophy. The SR Ca(2+)-ATPase is also markedly decreased in pressure overloaded hearts, while in thyrotoxic hearts both are increased. The signal transduction system in cardiac hypertrophy can be examined by stretching cardiac myocytes grown up on deformable membranes. In our analysis, stretching myocytes stimulated protein kinase C, MAP-II kinase and S6 kinase, all of which may lead to the induction of fetal-type cardiac genes and accelerated protein synthesis. Analyses of the subcellular mechanisms of cardiac hypertrophy will provide important insights into understanding of the molecular basis of heart failure.
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PMID:[Molecular basis for heart failure]. 833 89

Cardiac functions are regulated by both contractile proteins and calcium regulatory proteins. Alterations of these are considered involved in impaired contractile and diastolic functions in hypertrophied hearts. In this study, we analyzed molecular changes during the development of cardiac hypertrophy. Cardiac hypertrophy was induced by constricting the pulmonary artery in rabbits or the aorta in rats. In rabbit right ventricular hypertrophy, protein synthesis was increased to 1.8 times the control 2-4 days after pulmonary constriction. This increase in protein synthesis could be classified as an increase in both capacity and efficiency of synthesis. beta-cardiac myosin heavy chain (beta-MHC) isoform was predominantly expressed and alpha-MHC was suppressed in pressure overload hypertrophy. The switch from alpha- to beta-MHC occurred at the mRNA level. Ca(2+)-ATPase of sarcoplasmic reticulum (SR) is important because it regulates intracellular Ca2+ levels during relaxation. In pressure-overload hypertrophy, the SR Ca(2+)-ATPase was markedly decreased in both the enzyme activities and mRNA levels, while in thyrotoxic hearts both were increased. Interstitial cells also undergo phenotypic modulation which was demonstrated by the induction of nonmuscle-type MHC in pressure-overload hypertrophy. The signal transduction system in cardiac hypertrophy was examined by stretching cardiac myocytes grown on deformable membranes. In our analysis, stretching myocytes stimulated protein kinase C, MAP-II kinase and S6 kinase, all of which may lead to the induction of fetal-type cardiac genes and accelerated protein synthesis. These analyses of subcellular adaptation in cardiac hypertrophy provide important insights into understanding molecular mechanisms of cardiac functions.
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PMID:[Molecular basis for cardiac functions]. 835 May 1

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