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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)

Axoplasm from the squid giant axon contains a soluble protein translocator that induces movement of microtubules on glass, latex beads on microtubules, and axoplasmic organelles on microtubules. We now report the partial purification of a protein from squid giant axons and optic lobes that induces these microtubule-based movements and show that there is a homologous protein in bovine brain. The purification of the translocator protein depended primarily on its unusual property of forming a high affinity complex with microtubules in the presence of a nonhydrolyzable ATP analog, adenylyl imidodiphosphate. The protein, once released from microtubules with ATP, migrates on gel filtration columns with an apparent molecular weight of 600 kilodaltons and contains 110-120 and 60-70 kilodalton polypeptides. This protein is distinct in molecular weight and enzymatic behavior from myosin or dynein, which suggests that it belongs to a novel class of force-generating molecules, for which we propose the name kinesin.
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PMID:Identification of a novel force-generating protein, kinesin, involved in microtubule-based motility. 392 25

In the study of motor proteins, the molecular mechanism of mechanochemical coupling, as well as the cellular role of these proteins, is an important issue. To assess these questions we introduced cDNA of wild-type and site-directed mutant kinesin heavy chains into fibroblasts, and analyzed the behavior of the recombinant proteins and the mechanisms involved in organelle transports. Overexpression of wild-type kinesin significantly promoted elongation of cellular processes. Wild-type kinesin accumulated at the tips of the long processes, whereas the kinesin mutants, which contained either a T93N- or T93I mutation in the ATP-binding motif, tightly bound to microtubules in the center of the cells. These mutant kinesins could bind to microtubules in vitro, but could not dissociate from them even in the presence of ATP, and did not support microtubule motility in vitro, thereby indicating rigor-type mutations. Retrograde transport from the Golgi apparatus to the endoplasmic reticulum, as well as lysosome dispersion, was shown to be a microtubule-dependent, plus-end-directed movement. The latter was selectively blocked in the rigor-mutant cells, although the microtubule minus-end-directed motion of lysosomes was not affected. We found the point mutations that make kinesin motor in strong binding state with microtubules in vitro and showed that this mutant causes a dominant effect that selectively blocks anterograde lysosome membrane transports in vivo.
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PMID:Point mutation of adenosine triphosphate-binding motif generated rigor kinesin that selectively blocks anterograde lysosome membrane transport. 749 Feb 81

We report here the complete sequence of the gamma dynein heavy chain of the outer arm of the Chlamydomonas flagellum, and partial sequences for six other dynein heavy chains. The gamma dynein heavy chain sequence contains four P-loop motifs, one of which is the likely hydrolytic site based on its position relative to a previously mapped epitope. Comparison with available cytoplasmic and flagellar dynein heavy chain sequences reveals regions that are highly conserved in all dynein heavy chains sequenced to date, regions that are conserved only among axonemal dynein heavy chains, and regions that are unique to individual dynein heavy chains. The presumed hydrolytic site is absolutely conserved among dyneins, two other P loops are highly conserved among cytoplasmic dynein heavy chains but not in axonemal dynein heavy chains, and the fourth P loop is invariant in axonemal dynein heavy chains but not in cytoplasmic dynein. One region that is very highly conserved in all dynein heavy chains is similar to a portion of the ATP-sensitive microtubule-binding domain of kinesin. Two other regions present in all dynein heavy chains are predicted to have high alpha-helical content and have a high probability of forming coiled-coil structures. Overall, the central one-third of the gamma dynein heavy chain is most conserved whereas the N-terminal one-third is least conserved; the fact that the latter region is divergent between the cytoplasmic dynein heavy chain and two different axonemal dynein heavy chains suggests that it is involved in chain-specific functions.
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PMID:Molecular analysis of the gamma heavy chain of Chlamydomonas flagellar outer-arm dynein. 751 41

To shed light on how axonal transport is regulated, we examined the possible roles of protein kinase A (PKA) in vivo suggested by our previous work (Sato-Yoshitake et al., 1992). Pharmacological probes or the purified catalytic subunit of PKA were applied to the permeabilized-reactivated model of crayfish walking leg giant axon, and the effect was monitored by the quantitative video-enhanced light microscopy and the quantitative electron microscopy. Dibutyryl cyclic AMP caused concentration-dependent transient reduction in the number of anterogradely transported small vesicles, while the retrogradely transported organelles and anterogradely transported mitochondria showed no decrease. This transient selective inhibition of anterograde vesicle transport was reversed by the application of a specific inhibitor of PKA (KT5720) in a concentration-dependent manner, and was reproduced by the application of the purified catalytic subunit of PKA and augmented by the application of adenosine 5'-O-(3-thiotriphosphate) (ATP gamma S). Corresponding biochemical study showed that several axoplasmic proteins including kinesin were specifically phosphorylated by the activation of the PKA pathway. These findings suggest the possible roles of PKA in the regulation of the direction of the axonal transport in vivo. The finding that only vesicle transport but not mitochondria transport was inhibited also suggests that the transport of vesicles and that of mitochondria are differently regulated and might be supported by different motors.
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PMID:The activation of protein kinase A pathway selectively inhibits anterograde axonal transport of vesicles but not mitochondria transport or retrograde transport in vivo. 753 26

The kinetic mechanism of the human kinesin ATPase motor domain K379, expressed in Escherichia coli, was determined by transient and steady-state kinetic studies. The steps in nucleotide binding were measured using the fluorescent substrate analogues, methylanthraniloyl ATP (mant-ATP) and mant-ADP. Both nucleotides gave a two-step fluorescence signal, an increase followed by a decrease, which indicates that two isomerizations are induced by nucleotide binding. The ATPase mechanism is fitted by a six-step reaction: [formula: see text] where, T, D, and P refer to nucleotide triphosphate, nucleotide diphosphate, and inorganic phosphate, respectively; K(T) and K(D) are states in rapid equilibrium with the free nucleotide. A set of kinetic constants for 20 degrees C 50 mM NaCl is K1 = 2 x 10(4) M-1, k2 = 200 s-1, k3 = 9 s-1, k5 = 0.01 s-1, and K6 = 2 x 10(-5) M. Values of K1 and K6 are estimates for mant-ATP and mant-ADP, respectively. ADP dissociation is the rate-limiting step. The rate constant for a decrease in fluorescence for the transitions from the high fluorescence K.T state to the low fluorescence K.D state is equal to k3, the rate constant of the hydrolysis step measured by quench flow experiments. The decrease could occur in step 3 or step 4 if k4 > k3.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Kinetic mechanism of kinesin motor domain. 754 87

A six-step mechanism is derived for the activation of kinesin K379 ATPase by microtubules. The data are fitted by the kinetic scheme [Formula see text] where T, D, and P refer to nucleotide triphosphate, nucleotide diphosphate, and inorganic phosphate, respectively; MtK refers to the complex of a K379 unit with the microtubule binding site. The initial binding and release steps, 1 and 6, are treated as rapid equilibria: k2 = 200 s-1, k3 = 100 s-1, k5 = 35-40 s-1, maximum steady-state rate = 25 s-1 (50 mM NaCl, 20 degrees C). k2 was obtained from the maximum rate of fluorescence enhancement with mant-ATP as substrate, k3 was obtained from the hydrolysis transient phase for ATP or mant-ATP, and k5 was obtained from the rate of decrease in fluorescence of mant-ADP in the reaction [Formula see text]. A large excess of ATP was present with the Mt to block rebinding of mant-ADP. The rate was measured as a function of microtubule concentration and extrapolated to give the maximum rate k5. The same method was used to obtain k5 for ADP by mixing K.ADP with microtubules plus excess mant-ATP. The enhancement of fluorescence for the binding of mant-ATP is followed by a decrease in fluorescence with a rate constant of 35-40 s-1. Since the decrease must occur after hydrolysis, it may be correlated with a step or steps leading to the low fluorescence MtK.D state. In the kinetic scheme, steps 4 and 5 both contribute to determining the maximum turnover rate. At higher ionic strengths or lower protein concentrations, the MtK complex is dissociated by ATP. The maximum rate is 12 +/- 2 s-1 in 50 mM NaCl; consequently, hydrolysis occurs before dissociation. The dissociation constant of MtK in the presence of ADP is twice as large as the dissociation constant in the presence of ATP and four times larger than the KM for microtubule activation. The proposed kinetic scheme, which treats the K379 units of a dimer as independent, provides a satisfactory description of the transient and steady-state properties of the system with the possible exception of results at very low substrate concentrations.
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PMID:Mechanism of microtubule kinesin ATPase. 754 88

ncd is a kinesin-related motor protein from Drosophila that moves in the opposite direction along microtubules to kinesin. To learn more about the ncd mechanism, ncd motor domain (R335-K700) was expressed in Escherichia coli and its enzymatic characteristics were studied. The ncd motor domain was purified from the cell lysate by S-Sepharose chromatography, and trace amounts of contaminants were removed by passing through a MonoQ column. The yield was 20 mg from a 500 mL culture of E. coli. The purified ncd motor domain exhibited an unusual UV spectrum with a broad peak around 272-275 nm, which was at least partly due to the bound nucleotide. Upon incubation with radioactive ATP, 3H at adenine but not 32P at gamma-phosphate was retained by the protein on gel filtration, indicating it bound ADP but not ATP. Thus, like kinesin, nucleotide binding to the ncd motor domain is tight, although there is an equilibrium between the protein and free nucleotide. We also used a fluorescent ATP analogue, mantATP, for the kinetic study of ncd motor domain. MantATP was turned over by ncd motor domain slowly in the absence of microtubules, but microtubules activated the turnover to a similar extent to that of ATP. Upon incubation with ncd motor domain, the fluorescent intensity of mantATP increased at 0.005 s-1, which is likely to reflect the release of endogenous ADP and incorporation of mantATP into the protein. The fluorescence intensity of the ncd motor domain having bound mantADP, likewise, decreased upon mixing with ATP, representing the mantADP release.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Expression, purification, ATPase properties, and microtubule-binding properties of the ncd motor domain. 754 90

Studies of immobilized kinesin have shown that a single dimeric molecule can maintain contact with and drive sliding of a microtubule. In solution, however, native kinesin binds microtubules too weakly and hydrolyses ATP too slowly to produce the high sliding velocities seen in motility assay. This apparent inhibition in solution appears to be caused by the binding of kinesin's tail domains to its motor (head) domains in a folded conformation. DKH392, a construct containing two heads but no tails, has been shown to display both tight binding to microtubules and high ATPase rates. Furthermore, it retains one molecule of ADP per dimer when bound to microtubules, which could facilitate a 'hand-over-hand' mechanism for processive motion. Here we show that DKH392 hydrolyses more than 100 ATP molecules per diffusional encounter with a microtubule, even in the high-salt conditions encountered physiologically. This provides direct evidence that kinesin's activity is highly processive, with the motor remaining attached to a microtubule through many cycles of ATP hydrolysis.
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PMID:Highly processive microtubule-stimulated ATP hydrolysis by dimeric kinesin head domains. 756 25

Chronic exposure to acrylamide leads to a dying-back axonopathy afflicting the longest axons of all tested mammalian and avian species. Prior to the onset of acrylamide-induced axonal degeneration, alterations in axonal fast transport have been consistently reported to be more severe for the retrograde than the anterograde direction. The putative retrograde motor protein, dynein, is compromised by exposure to the sulfhydryl-alkylating agent N-ethylmaleimide (NEM) at concentrations far below those required to inactivate kinesin, the putative anterograde motor protein. Since acrylamide is capable of alkylating protein sulfhydryl moieties, we tested whether a direct exposure of purified kinesin or dynein to acrylamide would result in an impairment of either enzyme's ability to translocate microtubules. Motor activity was assayed by sequentially adsorbing either kinesin or dynein to acid-washed coverslips, treating with an alkylating agent or control solution, adding microtubules and ATP, and finally imaging and quantifying the binding and gliding of microtubules using video-enhanced differential interference contrast (VE-DIC) microscopy. In comparison to controls, incubation of dynein with NEM, ethacrynic acid, or iodoacetic acid resulted in dose-dependent decreases in the amount and rate of microtubule gliding, but increases in irreversible high-affinity microtubule binding. In contrast, exposure of dynein to 1-100 mM solutions of acrylamide did not significantly alter either the binding or gliding of microtubules (a molar/hour exposure to acrylamide equivalent to 50 times that which causes retrograde transport deficits in vivo). Likewise, kinesin motility parameters were not significantly affected by acrylamide concentrations up to 100 mM while NEM solutions > 100 microM led to significant losses in the ability of kinesin to bind MT. These data indicate that acrylamide does not significantly interact with bound (adsorbed) kinesin or dynein, implying that the mechanism by which acrylamide interferes with fast axonal transport in vivo is by interaction with other factor(s) that govern the movement of vesicles.
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PMID:The effect of acrylamide and other sulfhydryl alkylators on the ability of dynein and kinesin to translocate microtubules in vitro. 759 12

Kinesin and non claret disjunctional are closely related molecular motors that move in opposite directions along microtubules. We have used recombinant single-headed and double-headed constructs of both rat kinesin heavy chain and non claret disjunctional to investigate the interactions of these motor proteins with microtubules. At saturation the stoichiometry of binding for non claret disjunctional and kinesin to microtubules is one molecule (single or double-headed) per tubulin heterodimer. In the absence of added nucleotide, addition of increasing amounts of one motor results in the competitive displacement of the other motor from the microtubules. This effect is apparent also in the presence of the nucleotide analogue 5'-adenylimidodiphosphate, which tightens the binding of both kinesin and non claret disjunctional. Competition for binding sites occurs also under conditions of steady-state ATP turnover. We conclude that despite their opposite directionality, kinesin and non claret disjunctional compete for overlapping binding sites on the MT surface. Since the binding of the second head of a double-headed motor is sterically blocked, the data imply also that both kinesin and non claret disjunctional may translocate via a processive (alternating heads) mechanism with a minimum step size of approximately 8 nm.
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PMID:Kinesin and ncd bind through a single head to microtubules and compete for a shared MT binding site. 760 88


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