EC:3.6.4.4 - FACTA Search

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Query: EC:3.6.4.4 (kinesin)
5,033 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We have analyzed the effects of various substrates and inhibitors on the rates of microtubule (MT) motility induced by sea urchin egg kinesin using real-time computer analysis and video-enhanced light microscopy. In the presence of magnesium, 10 mM concentrations of all the nucleotides tested supported MT translocation, with velocities in MgATP greater than MgGTP greater than MgTTP approximately equal to MgUTP greater than MgCTP greater than MgITP. The velocity of kinesin-driven MT motility is fairly uniform over approximately 3 pH units, from pH 6 to 9, with almost no motility outside this range. In the presence of ATP, no motility is observed in the absence of divalent cations; addition of Mg2+ but not addition of Ca2+ restores motility. MgATP-dependent MT motility is reversibly inhibited by Mg-free ATP, EDTA, or tripolyphosphate, suggesting that Mg-free ATP is an inactive substrate analogue. MgATP and MgGTP both obey saturable, Michaelis-Menten kinetics, with apparent Km values of approximately 60 microM and 2 mM, and Vmax values of approximately 0.6 and 0.4 microns/s, respectively. MgATP gamma S and MgADP are classic competitive inhibitors of kinesin-driven motility in MgATP, with Ki values of approximately 15 and 150 microM, respectively. Adenosine 5'-(beta, gamma-methylene)-triphosphate and N-ethylmaleimide only inhibit MT motility weakly, while adenyl-5'-yl imidodiphosphate and vanadate strongly inhibit MT motility, but not in a simple competitive manner. Moreover, in contrast to other inhibitors which cause a unimodal decrease in MT mean velocity, vanadate concentrations greater than approximately 10% that of MgATP cause some MTs to become immotile, resulting in a bimodal distribution of MT velocities.
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PMID:Quantitative analysis of sea urchin egg kinesin-driven microtubule motility. 252 43

Bovine brain kinesin binds ADP tightly and contains a stoichiometric amount of ADP at its active site when isolated in the presence of free Mg2+ (Hackney, D. D. (1988) Proc. Natl. Acad. Sci. U.S.A. 85, 6314-6318). EDTA in excess of Mg2+ weakens ADP binding and nucleotide-free kinesin can be prepared by gel filtration with excess EDTA. On addition of ATP, this nucleotide-free enzyme catalyzes the rapid hydrolysis of a stoichiometric amount of ATP in a burst phase followed by much slower continued ATP hydrolysis limited by the release of ADP from the active site. This burst reaction is evident both by formation of [32P]Pi from [gamma-32P]ATP and by formation of [alpha-32P]ADP from [alpha-32P]ATP. At 1.1 nM kinesin active sites, the observed rate of the burst phase increases linearly with ATP over the 1-20 nM range yielding a bimolecular rate of net ATP binding and hydrolysis of 2.5 microM-1 s-1. The intercept at zero ATP is 0.008 s-1 which equals the ADP release rate at 0.008-0.009 s-1. This predicts a Km for ATP of approximately 3.5 nM and measurements of the dependence on ATP concentration of the steady state rate and amount of bound ADP are consistent with a Km of this magnitude.
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PMID:Nucleotide-free kinesin hydrolyzes ATP with burst kinetics. 252 42

Recently, a protein called kinesin was described, which is capable of inducing movement of inert particles along microtubules. To purify this protein from bovine brain, we used the ability of kinesin to bind to taxol-stabilized microtubules in the presence of inorganic tripolyphosphate. The brain kinesin preparation contained one major polypeptide of 135 kDa and four minor polypeptides of 45-70 kDa. The minor polypeptides were eluted from a gel-permeation chromatography column at the same position as the major component. All the polypeptides of the preparation were capable of binding to the microtubules under identical conditions. The kinesin molecule is most probably a complex of these polypeptides. Brain kinesin had a very low ATPase activity (0.06-0.08 mumol X min-1 X mg-1 in 3 mM Mg2+ at pH 6.7). ATPase activity was strongly stimulated by microtubules (Vmax = 4.6 mumol per min per mg of kinesin). Microtubule-activated kinesin ATPase had a Km for ATP between 10 and 12 X 10(-6) M and a Kapp for microtubules (i.e., polymerized tubulin concentration required for a half-maximal activation) of 12-14 X 10(-6) M. Kinesin had a significant ATPase activity even without microtubules if 2 mM Ca2+ was substituted for Mg2+ (Vmax = 1.6 mumol X min-1 X mg-1; Km = 800 X 10(-6) M). Kinesin is therefore a mechanochemical ATPase that is activated by microtubules.
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PMID:Bovine brain kinesin is a microtubule-activated ATPase. 294 42

Coupling between ATP hydrolysis and microtubule movement was demonstrated several years ago in flagellar axonemes and subsequent studies suggest that the relevant microtubule motor, dynein, uses ATP to drive microtubule sliding by a cross-bridge mechanism analogous to that of myosin in muscles. Kinesin, a microtubule-based motility protein which may participate in organelle transport and mitosis, binds microtubules in a nucleotide-sensitive manner, and requires hydrolysable nucleotides to translocate microtubules over a glass surface. Recently, neuronal kinesin was shown to possess microtubule-activated ATPase activity although coupling between ATP hydrolysis and motility was not demonstrated. Here we report that sea urchin egg kinesin, prepared either with or without a 5'-adenylyl imidodiphosphate(AMPPNP)-induced microtubule binding step, also possesses significant microtubule-activated ATPase activity when Mg-ATP is used as a substrate. This ATPase activity is inhibited in a dose-dependent manner by addition of Mg-free ATP, by chelation of Mg2+ with EDTA, by addition of Na3VO4, or by addition of AMPPNP with or without Mg2+. Addition of these same reagents also inhibits the microtubule-translocating activities of sea urchin egg kinesin in a dose-dependent manner, supporting the hypothesis that kinesin-driven motility is coupled to the microtubule-activated Mg2+-ATPase activity.
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PMID:Correlation between the ATPase and microtubule translocating activities of sea urchin egg kinesin. 295 28

A truncated motor domain of the alpha subunit of Drosophila kinesin was obtained by expression in Escherichia coli and purified to homogeneity in the presence of MgATP. This domain (designated DKH340) extends from the N terminus to amino acid 340. The isolated protein contains a stoichiometric level of tightly bound ADP and has a low basal rate of ATP hydrolysis of 0.029 +/- 0.002 s-1 in the absence of microtubules. The rate of release of bound ADP is 0.026 +/- 0.003 s-1. The approximate equality of the ADP release rate and the steady state ATPase rate indicates that ADP release is the rate-limiting step in ATP hydrolysis in the absence of microtubules. The rate of ATP hydrolysis is stimulated 3000 fold-by addition of microtubules (MT) (kcat = 80 s-1; KMT0.5,ATPase = 160 nM for half-saturation of the ATPase rate by microtubules at saturating ATP levels; KMT0.5ATPase = 43 microns for half-saturation of the ATPase rate by ATP at saturating microtubule levels). Binding of DKH340 to MTs is biphasic in the presence of adenosine 5-(beta-gamma-imido)t-riphosphate. One DKH340 binds tightly per tubulin heterodimer, but greater than one DKH340/tubulin heterodimer can be bound at higher ratios of DKH340/microtubules. In the presence of MgATP, KMT0.5,Binding for physical binding of DKH340 to microtubules is weaker than KMT0.5,ATPase for stimulation of hydrolysis. These results are consistent with a model in which DKH340 cycles on and off the microtubule during hydrolysis of each ATP molecule. For this model, the kcat/KMT0.5,ATPase ratio of 5 x 10(8) M-1 s-1 is at least as large as the bimolecular rate constant for association with microtubules, and this value approaches the diffusion controlled limit. Nucleotide-free DKH340 can be produced by gel filtration in the absence of Mg2+, but it reforms tightly bound ADP slowly in the presence of MgATP (t1/2 > or = 10 min), and thus it is likely to be in a conformational state which is not produced during steady state ATP hydrolysis.
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PMID:Drosophila kinesin minimal motor domain expressed in Escherichia coli. Purification and kinetic characterization. 820 59

We studied the effect of alkaline-earth metal ions on the kinesin-driven gliding of microtubules, using a narrow glass chamber enabling the exchange of buffer components without interrupting microscopic observation. Under standard conditions (0.5 mM Mg2+), microtubules were found to glide at a mean velocity of about 0.6 micron/s. Motility was widely ceased after removing Mg2+. Subsequent addition of Ca2+ restored motility (maximal mean gliding velocity measured: 0.26 micron/s at 2.5 mM Ca2+). Also in the presence of Sr2+ or Ba2+ a slow gliding could be observed (0.025 micron/s and 0.014 micron/s, respectively, at 0.5 mM). After removal of Ca2+, Sr2+, or Ba2+ and re-addition of Mg2+, the gliding velocities reached approximately the values determined under standard conditions. Motility was not changed when 0.5 mM Ca2+, Sr2+, or Ba2+ were applied together with Mg2+. Microtubule gliding stopped after substitution of 0.5 mM BeCl2 for Mg2+. When both BeCl2 and Mg2+ were present, the mean gliding velocity was reduced to 0.29 micron/s. In addition, many microtubules were released from the kinesin coated glass surface, indicating that the beryllium salt disorders the binding between kinesin and microtubules. Our results confirm that Mg2+ is the most suitable cofactor for kinesin driven microtubule motility. However, they also demonstrate that brain kinesin can generate motility when Ca2+ was substituted for Mg2+.
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PMID:Kinesin-driven microtubule motility in the presence of alkaline-earth metal ions: indication for a calcium ion-dependent motility. 922 52

Displacement of the fluorescent substrate analogue methylanthraniloyl ADP (mant-ADP) from kinesin by excess ATP results in a biphasic fluorescent transient. The pH and microtubule dependence of the rates and amplitudes indicates that the two phases are produced by release of bound mant-ADP, with an excess of the 3'-isomer, followed by the subsequent relaxation of the free 2'- and 3'-isomers to their equilibrium distribution. The first phase for release of mant-ADP is accelerated by microtubules and occurs at the same rate as ADP release measured using [32P]ADP. The second phase is subject to base catalysis and occurs at the same rate as the isomerization of isolated 2'- or 3'-mant-ATP over a 100-fold range of rates. The bound mant-ADP isomers undergo isomerization rapidly when bound to kinesin at pH 8.2, whereas mant-ADP isomers interconvert only slowly when bound to myosin. No fluorescence resonance energy transfer occurs between the single tryptophan in the kinesin neck domain and bound mant-ADP, but efficient energy transfer does occur from protein tyrosine groups. The rate of mant-ADP release in the absence of microtubules is minimal (0.005 s-1) at pH 7-8, 2 mM Mg2+, and 25 mM KCl but is accelerated at lower pH (0.04 s-1 at pH 5.5) and either lower or higher [KCl] (0.01 and 0. 06 s-1 at 0 and 800 mM KCl, respectively). The microtubule-stimulated rate of ADP release is accelerated at low pH and inhibited by high concentrations of monovalent salts. Reduction of the free Mg2+ by addition of excess EDTA increases the release of mant-ADP from E.MgADP to 0.03 s-1. This acceleration at low Mg2+ likely represents sequential release of Mg2+ at 0.03 s-1 followed by rapid release of ADP, as the rate of ADP release from Mg-free E.ADP is fast (>0.5 s-1). At high Mg2+, rebinding of Mg2+ to E.ADP forces release of ADP from the E.MgADP complex at 0.005 s-1.
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PMID:Interaction of mant-adenosine nucleotides and magnesium with kinesin. 954 60

Molecular motors move along actin or microtubules by rapidly hydrolyzing ATP and undergoing changes in filament-binding affinity with steps of the nucleotide hydrolysis cycle. It is generally accepted that motor binding to its filament greatly increases the rate of ATP hydrolysis, but the structural changes in the motor associated with ATPase activation are not known. To identify the conformational changes underlying motor movement on its filament, we solved the crystal structures of three kinesin mutants that decouple nucleotide and microtubule binding by the motor, and block microtubule-activated, but not basal, ATPase activity. Conformational changes in the structures include a disordered loop and helices in the switch I region and a visible switch II loop, which is disordered in wild-type structures. Switch I moved closer to the bound nucleotide in two mutant structures, perturbing water-mediated interactions with the Mg2+. This could weaken Mg2+ binding and accelerate ADP release to activate the motor ATPASE: The structural changes we observe define a signaling pathway within the motor for ATPase activation that is likely to be essential for motor movement on microtubules.
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PMID:A structural pathway for activation of the kinesin motor ATPase. 1138 96

New crystal structures of the kinesin motors differ from previously described motor-ADP atomic models, showing striking changes both in the switch I region near the nucleotide-binding cleft and in the switch II or 'relay' helix at the filament-binding face of the motor. The switch I region, present as a short helix flanked by two loops in previous motor-ADP structures, rearranges into a pseudo-beta-hairpin or is completely disordered with melted helices to either side of the disordered switch I loop. The relay helix undergoes a rotational movement coupled to a translation that differs from the piston-like movement of the relay helix observed in myosin. The changes observed in the crystal structures are interpreted to represent structural transitions that occur in the kinesin motors during the ATP hydrolysis cycle. The movements of switch I residues disrupt the water-mediated coordination of the bound Mg2+, which could result in loss of Mg2+ and ADP, raising the intriguing possibility that disruption of the switch I region leads to release of nucleotide by the kinesins. None of the new structures is a true motor-ATP state, however, probably because conformational changes at the active site of the kinesins require interactions with microtubules to stabilize the movements.
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PMID:Kinesin: switch I & II and the motor mechanism. 1180 20

The TRP (transient receptor potential) superfamily of cation channels is present in all eukaryotes, from yeast to mammals. Many TRP channels have been studied in the nematode Caenorhabditis elegans, revealing novel biological functions, regulatory modes, and mechanisms of localization. C. elegans TRPV channels function in olfaction, mechanosensation, osmosensation, and activity-dependent gene regulation. Their activity is regulated by G protein signaling and polyunsaturated fatty acids. C. elegans TRPPs related to human polycystic kidney disease genes are expressed in male-specific neurons. The KLP-6 kinesin directs TRPP channels to cilia, where they may interact with F0/F1 ATPases. A sperm-specific TRPC channel, TRP-3, is required for fertilization. Upon sperm activation, TRP-3 translocates from an intracellular compartment to the plasma membrane to allow store-operated Ca2+ entry. The TRPM channels GON-2 and GTL-2 regulate Mg2+ homeostasis and Mg2+ uptake by intestinal cells; GON-2 is also required for gonad development. The TRPML CUP-5 promotes normal lysosome biogenesis and prevents apoptosis. Dynamic, precise expression of TRP proteins generates a remarkable range of cellular functions.
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PMID:TRP channels in C. elegans. 1646 Feb 89

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