Gene/Protein Disease Symptom Drug Enzyme Compound
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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)

Moving along a microtubule, kinesin follows a course parallel to the protofilaments; but it is not known whether kinesin binds exclusively on a single protofilament. The presence of zinc during tubulin polymerization induces sheets where neighboring protofilaments are antiparallel. If kinesin could support the motility of these zinc-sheets, then the binding site for a kinesin molecule would be limited to a single protofilament. Kamimura and Mandelkow [1992: J. Cell Biol. 118:865-75] reported that kinesin moves along zinc-sheets. We found that zinc-sheets grown under their conditions often had a microtubule-like structure along one edge. We confirmed the possibility that the motility observed by Kamimura and Mandelkow [1992: J. Cell Biol. 118:865-75] is attributed to the microtubule-like structure rather than the zinc-sheet. To resolve the question of whether kinesin can recognize an antiparallel protofilament lattice, we investigated the kinesin-mediated motility of zinc-macrotubes. At higher free zinc concentrations, zinc-sheets roll up as macrotubes, free of edges. In the presence of 10 microM taxol and 100 nM free Zn2+ at pH 6.8, the samples were shown by electron microscopy to contain only macrotubes. Under these buffer conditions, kinesin could bind strongly to axonemal doublets in the presence of AMP-PNP, and generate motility in the presence of ATP, but kinesin did not bind to nor move the macrotubes. This shows that kinesin cannot bind efficiently to nor move on the anti-parallel lattice; it is possible (though not necessary) that the groove between two parallel protofilaments is required for kinesin's motility.
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PMID:Kinesin does not support the motility of zinc-macrotubes. 760 7

The kinesin superfamily is a class of microtubule-based mechano-enzymes involved in intracellular transport and chromosome movements. Molecules that move towards either the plus end or the minus end of microtubules are represented within the family. The motor domains of these molecules exhibit considerable sequence homology and contain both the ATP- and microtubule-binding sites (reviewed in refs 1, 2). Here we focus on non-claret disjunctional (ncd), a minus-end-directed motor involved in chromosome segregation in meiosis and early mitosis in Drosophila. We have calculated a three-dimensional map of tubulin sheets decorated with monomeric recombinant ncd motor domains by negative-stain electron microscopy and image analysis. Comparisons with a control structure of tubulin alone reveal that each motor domain binds to the crest of a single protofilament, making extensive contacts with both the alpha and beta tubulin monomers. Binding of the motor domain results in significant conformational changes in both of the tubulin monomers.
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PMID:Three-dimensional structure of a tubulin-motor-protein complex. 761 26

Kinesin is a microtubule (MT)-associated 'motor' molecule fundamental to organelle transport. Recently, various kinesin superfamily members (KIFs) have also been identified and suggested as being responsible for the transport of specific organelles. Kinesin is a heterotetramer composed of two heavy chains and two light chains. The heavy chains form two globular heads, a rod and a fan-like tail completed by the light chains. The globular head, which is composed of approximately 340 amino-terminal residues of the heavy chain, includes both ATP-binding and MT-binding domains, and its recombinant protein also has these properties. To improve the understanding of the mechanism of force generation by an MT-based molecular motor, kinesin, we report here the three-dimensional structure of the complex of a recombinant kinesin head and MTs, as revealed by helical reconstruction from cryo-electron micrographs. A kinesin head is a globular teardrop-like structure binding to the ridge of one protofilament of MTs. We have determined the polarity of the structure of the complex of MTs and the kinesin head in relation to MT polarity.
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PMID:Three-dimensional structure of the kinesin head-microtubule complex. 761 26

Kinesin is a 'motor' molecule, consisting of two head domains, an alpha-helical coiled coil rod, and a tail part that binds to its cargo. When expressed in a bacterial system, the head domain is functional, and can bind to microtubules with the stoichiometry of one head per tubulin dimer. Kinesin moves along microtubules by means of a cyclic process of nucleotide binding, hydrolysis and product release. We have used negative-stain electron microscopy and image analysis to study the structures of microtubules and tubulin sheets decorated with the motor domain (head) of kinesin in three states: in the presence of an unhydrolysable ATP analogue, 5'-adenylylimidodiphosphate (AMP-PNP); without nucleotides; and with adenosine 5'-diphosphate (ADP). A single kinesin head bound to a microtubule has a pear-shaped structure, with the broader end towards the 'plus' end of the microtubule under all conditions; the reverse motor, ncd, is similarly oriented. Three-dimensional maps reveal that kinesin heads have a spike that is assumed to form the attachment to the tail of a complete kinesin molecule. This spike is perpendicular to the microtubule axis in the presence of ADP, but points towards the plus end (approximately 45 degrees) in the presence of AMP-PNP or absence of nucleotides. Our results provide direct evidence for a conformational change of the kinesin motor domain during the ATPase cycle.
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PMID:Nucleotide-dependent angular change in kinesin motor domain bound to tubulin. 761 26

The motor protein non-claret disjunctional (ncd) moves towards the minus ends of microtubules (MTs), whereas its close relative kinesin moves in the opposite direction towards the plus ends of MTs. The mechanisms of movement and directional reversal for these motor proteins are unknown. Here we report the rate constants for MT activated ADP release from a recombinant double-headed ncd protein, GST-MC5, and a recombinant double-headed kinesin protein, K delta 401, measured using the fluorescent nucleotide analogues methylanthranilyol ATP (mantATP) and mantADP. Comparison of the maximal MT activated mantADP release rates for these proteins with their maximal MT activated mantATP turnover rates indicates that ADP release is the rate-limiting step for ATP turnover for both ncd and kinesin. This data supports the view that directional reversal may result from structural rather than chemical kinetic differences in the way the motors interact with MTs.
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PMID:ADP release is the rate-limiting step of the MT activated ATPase of non-claret disjunctional and kinesin. 763 15

Kinesin is a motor protein that converts chemical energy derived from ATP hydrolysis into mechanical work to transport cellular components along microtubules. We studied the properties of ATP-dependent microtubule-kinesin sliding with two different in vitro assay systems. In one assay system, a kinesin-coated glass microneedle (elastic coefficient, 1-2.5 pN microns -1) was made to slide along an axoneme. Using this system, we obtained the relationship between the force (= load) on the microneedle and the velocity of microneedle-kinesin sliding in the auxotonic condition, in which the load on the microtubule-kinesin contacts increased as sliding progressed. The force-velocity curve was upwardly convex (maximum velocity Vmax, 0.58 +/- 0.15 microns s-1; maximum isometric force P0, 5.0 +/- 1.6 pN) and was similar to that of in vitro actin-myosin sliding in the auxotonic condition, suggesting that the two motor protein systems have fundamental kinetic properties in common. In the other assay system, an axoneme attached to a glass microneedle (elastic coefficient, 4-5 pN microns -1) was made to slide on a kinesin-coated glass surface (Vmax, 0.68 +/- 0.17 microns s-1; P0, 46.1 +/- 18.6 pN). The change in shape of the axoneme indicated an enormous flexibility of randomly oriented kinesin molecules.
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PMID:The mode of ATP-dependent microtubule-kinesin sliding in the auxotonic condition. 763 48

We have isolated a 1224 bp cDNA clone from a Bombyx mori embryonic cDNA library which contains sequences homologous to the kinesin-like protein gene, ncd, which is required for distribution of chromosomes at meiosis in Drosophila melanogaster females. This clone includes both a microtubule motor and the ATP-binding domains found in kinesin-like proteins. The motor domain is classified in the group of the BimC and cut7, which have a role in spindle formation during mitosis of Aspergillus nidulans and Schizosaccharomyces pombe, respectively. However, the location of the domain at the carboxy terminus is not common in this family, except for ncd and KAR3.
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PMID:cDNA structure and characterization of a kinesin-like protein from the silkworm Bombyx mori. 770 3

Bacterial expressed kinesin motor domains hydrolyze ATP and promote microtubule-dependent motility. It has routinely been assumed that motor domain preparations are monomeric on the basis of the presumption that dimerization is mediated by the stalk region. However, experimental verification of the oligomeric state of the kinesin construct is required to interpret the results from single-molecule motility assays as well as presteady-state kinetic experiments. We have measured directly the state of assembly of three conventional kinesin motor domain constructs-K401, K366, and K341, comprising the N-terminal 401, 366, and 341 amino acids, respectively, of the Drosophila kinesin heavy chain-by sedimentation velocity and sedimentation equilibrium methods in an analytical ultracentrifuge. K401 (MW of ADP complex, 45,532) is a predominantly a dimer with a sedimentation coefficient, s020,w, of 5.06 S, but it is able to self-associate by means of a 1-2-4 mechanism into higher oligomers. Molecular weight measurements establish the dissociation constant for dimerization at 37 +/- 17 nM in the presence of ATP. The dissociation constant in the presence of ADP is 35 +/- 26 nM and in the presence of AMPPNP is 42 +/- 28 nM. The construct K366 (MW of ADP complex, 41,404) is a monomer (measured MW, 41,768 +/- 1219) at concentrations below 4 microM K366, with a sedimentation coefficient, s020,w, of 3.25 S. At higher concentrations, there is evidence for a weak association of K366 to a 1-2-4-8 model with a slight preference for octamer formation. The smallest construct, K341 (MW of ADP complex, 38,274), is a monomer (measured MW, 38,191 +/- 734) up to at least 10 microM total K341 concentration with a sedimentation coefficient, s020,w, of 2.9 S. Thus, the dimerization domain either is between amino acid residues 367 and 401 or is strongly affected by the removal of this region. Higher oligomers of K401 form by a mechanism involving dimers of dimers, and suggest that native kinesin may also undergo self-association. These results have important implications for the interpretation of ATP-dependent motility assays.
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PMID:Sedimentation studies on the kinesin motor domain constructs K401, K366, and K341. 771 94

Many cell phenomena involve major morphological changes, particularly in mitosis and the process of cell migration. For cells or neuronal growth cones to migrate, they must extend the leading edge of the plasma membrane as a lamellipodium or filopodium. During extension of filopodia, membrane must move across the surface creating shear and flow. Intracellular biochemical processes driving extension must work against the membrane mechanical properties, but the forces required to extend growth cones have not been measured. In this paper, laser optical tweezers and a nanometer-level analysis system were used to measure the neuronal growth cone membrane mechanical properties through the extension of filopodia-like tethers with IgG-coated beads. Although the probability of a bead attaching to the membrane was constant irrespective of treatment; the probability of forming a tether with a constant force increased dramatically with cytochalasin B or D and dimethylsulfoxide (DMSO). These are treatments that alter the organization of the actin cytoskeleton. The force required to hold a tether at zero velocity (F0) was greater than forces generated by single molecular motors, kinesin and myosin; and F0 decreased with cytochalasin B or D and DMSO in correlation with the changes in the probability of tether formation. The force of the tether on the bead increased linearly with the velocity of tether elongation. From the dependency of tether force on velocity of tether formation, we calculated a parameter related to membrane viscosity, which decreased with cytochalasin B or D, ATP depletion, nocodazole, and DMSO. These results indicate that the actin cytoskeleton affects the membrane mechanical properties, including the force required for membrane extension and the viscoelastic behavior.
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PMID:Mechanical properties of neuronal growth cone membranes studied by tether formation with laser optical tweezers. 775 61

We have developed a biochemical screen for the identification of kinesin-related proteins (KRPs) in their natural host cells and the subsequent purification of these KRPs as native, functional multimeric complexes. The screen involves immunoblotting with pan-kinesin peptide antibodies that recognize several presumptive KRPs in cytosolic extracts; the antibodies have been used so far to monitor the purification of two bona fide kinesin-related motor protein complexes. These two KRPs were purified via AMPPNP-induced microtubule affinity binding, ATP-induced elution from AMPPNP microtubules, gel filtration fractionation, and sucrose density gradient centrifugation. KRP(85/95) from sea urchin (Strongylocentrotus purpuratus) eggs behaves as a heterotrimeric complex of 85-, 95-, and 115-kDa subunits that moves toward the plus ends of microtubule tracks at approximately 0.4 micron/s. KRP(130) from fruitfly (Drosophila melanogaster) embryos behaves as a homotetrameric complex of four 130-kDa subunits that moves toward the plus ends of microtubule tracks at approximately 0.04 micron/s. To our knowledge, KRP(85/95) and KRP(130) are the only KRPs to have been purified from native tissue as functional multimeric motor complexes.
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PMID:Purification of kinesin-related protein complexes from eggs and embryos. 778 59


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