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)

Studies involving 32P labeling and wet ashing of isolated dynein reveal that isolated dynein contains approximately 6 mol of phosphate predominantly distributed over four polypeptides of molecular masses of 78, 76, 47, and 23 kDa. Dynein must, therefore, be phosphorylated to at least this extent in vivo. The catalytic subunit of cAMP-dependent protein kinase and an axonemal cAMP-dependent protein kinase contaminating the dynein preparation can further phosphorylate dynein in vitro. Each kinase can place up to 0.5 mol of phosphate on native dynein polypeptides of molecular masses of 78 and 34 kDa. Removal of two of the phosphates on isolated dynein by either acid or alkaline phosphatase results in a 28% decrease in the specific activity of dynein in the presence or absence of microtubules. Selective attenuation of the microtubule-activated ATPase, but not the uncoupled free dynein ATPase, would be indicative of a regulatory function of the phosphates. The in vivo regulation of the dynein ATPase by the two phosphates accessible to acid or alkaline phosphatase is therefore subject to question. Other phosphates on dynein must be examined for their effect on the microtubule-dynein cross-bridge cycle and motility before phosphorylation can definitively be established as a mode of dynein regulation.
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PMID:Phosphorylation of Tetrahymena 22 S dynein. 214 71

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

A Mg2+-dependent ATPase activity has been purified from trout sperm axonemes which has properties characteristic of a dynein ATPase. A polyclonal antiserum prepared against the dynein heavy chains has been used to isolate dynein heavy chain (DYHC) cDNAs from a trout testis lambda gt11 cDNA expression library. beta-galactosidase fusion proteins produced in lambda gt11 by these trout cDNAs cross-reacted with a heterologous anti-sea urchin dynein antiserum. Northern blot analyses demonstrated that the RNA transcripts detected have sizes (7.5 - 12 kb) consistent with those expected for the dynein heavy chains. All the DYHC cDNAs encode portions of a highly unusual DNA coding sequence comprised of 21 bp direct repeats. The predicted open reading frame of this repeat is Ile/Leu-His-Val-Ile-Gln-Tyr-Ser and is characteristic of an extensive alpha-helical coiled-coil domain. The presence of an in-frame translation termination codon indicates that this domain is located at the carboxyl-terminus of the DYHC. Southern blot analyses demonstrated a low, if not single, copy number for this gene and conservation of this domain in other vertebrates. DYHC transcripts reach their highest level in testis, but are also abundant in brain tissue.
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PMID:Isolation of dynein heavy chain cDNAs from trout testis which predict an extensive carboxyl-terminal alpha-helical coiled-coil domain. 252 45

The effects of microtubules on the phosphate-water oxygen exchange reactions catalyzed by dynein were examined in order to determine the mechanism by which microtubules activate the ATPase. Microtubules inhibited the rate of medium exchange observed during net ATP hydrolysis. Inhibition of the exchange reaction was proportional to the extent of microtubule activation of ATP turnover with no effect on the partition coefficient. These data argue that microtubules do not increase the rate of release of phosphate from dynein; rather, they increase the rate of ADP release. Microtubules markedly inhibited medium phosphate-water exchange reactions observed in the presence of ADP and Pi. With increasing concentrations of ADP, the rate of exchange increased in parallel to the dissociation of dynein from the microtubules, suggesting that only free dynein and not the microtubule-dynein complex catalyzes the exchange reaction. The rates of dynein binding to microtubules in the absence and presence of saturating ADP were 1.6 X 10(6) and 9.8 X 10(5) M-1 s-1, respectively. ADP inhibited the rate of the ATP-induced dissociation of the microtubule-dynein complex with an apparent Kd = 0.37 mM for the binding of ADP to the microtubule-dynein complex. However, the rate of dissociation of ADP from the M.D.ADP complex was quite fast (approximately 1000 s-1). These data support the postulate of a high-energy dynein-ADP intermediate and indicate that microtubules activate the dynein ATPase by enhancing the rate of ADP release.
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PMID:Microtubules accelerate ADP release by dynein. 253 Oct 5

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

Quantitative analyses of ATP hydrolysis coupled to movement of eukaryotic flagella is important for understanding the relationship between ATP hydrolysis and movement. The difference in ATPase activity between intact motile axonemes (that is the cytoskeletal core of flagella) and homogenized or immotile axonemes has been assumed to be coupled to movement. However, recent findings on rates of steps in the dynein ATPase cycle and the effect of interaction with microtubules on those steps call for reassessment of movement-coupled ATPase. From these studies, it is clear that dynein ATPase activity is not as tightly coupled to interaction with microtubules as myosin ATPase activity is coupled to interaction with actin. The method by which axonemal movement is inhibited will critically affect the interpretation of difference in ATPase activity. If the homogenization or similar methods uncouple dynein, the difference in ATPase activity is not a useful measurement. Greater understanding of the relationship between dynein kinetics and axonemal movement may be obtained by use of conditions and substrates with known effects at specific steps in the dynein mechanochemical cycle and quantitating their effects on movement.
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PMID:Mechanochemical coupling in eukaryotic flagella. 253 74

The substrate specificity of the 22S dynein ATPase from Tetrahymena cilia was investigated. The 22S dynein exhibited a high specificity for ATP in terms of both apparent Km and Vmax: naturally occurring nucleoside triphosphates other than ATP were hydrolyzed slowly with an apparent Km of 0.25-1 mM, a sharp contrast to that of ATP hydrolysis (1-4 microM). Pyrophosphate was a poor inhibitor for the dynein ATPase, indicating weak affinity. Since dynein binds ATP tightly and hydrolyzes it at a high rate, a method to determine a trace amount of ATP in the presence of other nucleoside triphosphates has been developed by taking advantage of this enzymatic characteristic of dynein. The effect of P1,P5-di(adenosine-5'-)-pentaphosphate (Ap5A) on the 22S dynein ATPase was also investigated. Ap5A acted as a weak competitive inhibitor of the ciliary 22S dynein ATPase and the nonlinearity of the double-reciprocal plot of the ATPase was confirmed in the presence of Ap5A.
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PMID:The substrate specificity of dynein from Tetrahymena cilia. 283 Feb 51

Ciliary axonemes from Tetrahymena contain a second salt-extractable ATPase distinguishable from outer arm 21 S dynein by sedimentation velocity (congruent to 13 S), electrophoretic mobility and substrate specificity. As characterized by turbidimetric assay, gel electrophoresis in the presence of sodium dodecyl sulphate, ATPase activity and electron microscopy, the 13 S dynein ATPase rebinds to extracted doublet microtubules. Compared to structural-side (ATP-insensitive) 21 S dynein binding, which is moderately specific for the 24 nm outer row arm position, rebinding of 13 S dynein is highly specific but for the inner row arm position. However, 13 S dynein rebinds to the A subfibre with a spacing that coincides with the triplet spacing of the radial spokes (24-32-40 nm periods; 96 nm repeat). All of the major protein components present in the 13 S or 21 S fractions rebind to extracted doublets under conditions that both restore and activate dynein ATPase activity. Unlike active-side (ATP-sensitive) rebound 21 S dynein, rebound 13 S dynein is completely insensitive to dissociation by ATP-vanadate and does not independently decorate the B subfibre. The saturation profile for rebinding of 13 S dynein exhibits a lack of cooperativity between binding events (h = 1.0) similar to structural-side rebinding of 21 S dynein. At low 21 S/doublet stoichiometry there is no measureable competition between the 13 S and 21 S dyneins for binding sites on the A subfibre lattice, although at saturating concentrations of 21 S dynein, rebinding of 13 S dynein is blocked completely.
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PMID:Rebinding of Tetrahymena 13 S and 21 S dynein ATPases to extracted doublet microtubules. The inner row and outer row dynein arms. 293 46

The ATPase activity of native dynein 1 from sea urchin sperm flagella is activated reversibly by inorganic monovalent chlorides with the magnitude of activation being nearly independent of the cation below 0.3 M. At higher concentrations, activation increases in the order LiCl greater than NH4Cl greater than NaCl greater than KCl, with the maximum occurring at about 0.8 M in all cases. The sodium halides activate reversibly in the order NaI greater than NaBr greater than NaCl, but NaF is strongly inhibitory. The presence of the organic anions formate, acetate, or propionate favors the native low ATPase activity state, with lithium acetate giving little activation at up to 1 M and sodium acetate partially reversing the activation due to simultaneous presence of 0.6 M NaCl. The sedimentation rate of the dynein does not change between 0.2 and 0.8 M NaCl or sodium acetate, suggesting that the effects of the anions on ATPase activity are due to local changes near the catalytic site, rather than to large-scale changes in the molecular structure. All the agents that activate the dynein ATPase, either reversibly (halides) or irreversibly (Triton X-100), decrease its sensitivity to inhibition by vanadate, consistent with ATPase activation being the result of a decreased stability of the dynein. ADP.Pi kinetic intermediate that is thought to bind vanadate at the gamma-Pi site and act as a dead-end kinetic block. Although many divalent cations, including Mg2+, Mn2+, Fe2+, Co2+, Ni2+, Zn2+, Ca2+, and Sr2+, can support dynein ATPase activity, the magnitude of ATPase increase observed upon treatment with Triton X-100 is greatest with Mg2+ and Mn2+, which are also the only cations capable of supporting the motility of demembranated flagella at rates similar to those observed in vivo.
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PMID:Activation of dynein 1 adenosine triphosphatase by monovalent salts and inhibition by vanadate. 294 15

Energy coupling in flagellar motility was investigated using demembranated, reactivated sea urchin spermatozoa (Arbacia punctulata). The ATP-dependence of ATPase activity was investigated for ATP concentrations ranging from 4 microM to 600 microM ATP. Using Eadie-Scatchard plot analysis, we identified two axonemal dynein ATPase activities. Their apparent Michaelis constants were calculated to be equal to 4 microM and 161 microM ATP, and they were referred to, respectively, as the high-affinity dynein ATPase (HADA) and the low-affinity dynein ATPase (LADA). Investigation of movement-coupled ATPase activity (difference between the ATPase activities of reactivated and broken, immotile spermatozoa) indicated that HADA and LADA were both 65% movement-coupled. The apparent Michaelis constants of movement-coupled HADA and LADA, 12 microM and 271 microM ATP, respectively, were two- to four-fold greater than the apparent Michaelis constants of movement-uncoupled HADA and LADA. The apparent Michaelis constants for force generation and beat frequency of reactivated spermatozoa were determined to be 24 microM and 290 microM ATP, respectively. These results raise the possibility that flagellar force generation is controlled primarily by movement-coupled HADA, and that flagellar beat frequency is controlled primarily by movement-coupled LADA. Thus, mechanochemical activity in flagellar motility may be divided between two enzymatically and functionally distinct classes of flagellar dyneins.
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PMID:Evidence for functional differences between two flagellar dynein ATPases. 294 77


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