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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)

Microtubules and their associated proteins form the basis of axonal transport; they are degraded during the neuronal degeneration in Alzheimer's disease. This article surveys recent results on the structure of microtubules, tau protein, and PHFs. Microtubules have been investigated by electron microscopy and image processing after labeling them with the head domain of the motor protein kinesin. This reveals the arrangement of tubulin subunits in microtubules and the shape of the tubulin-motor complex. Tau protein was studied by electron microscopy, solution X-ray scattering, and spectroscopic methods. It appears as an elongated molecule (about 35 nm) without recognizable secondary structure. Alzheimer PHFs were examined by FTIR and X-ray diffraction; they, too, show evidence for secondary structure such as beta sheets.
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PMID:On the structure of microtubules, tau, and paired helical filaments. 756 44

Previously described extended proteins from the cytoskeleton of Giardia lamblia (beta-giardin, median body protein) have been found to be segmented coiled coils with regular structural repeat patterns in their amino acid sequences. Screening a lambda ZAPII library derived from Giardia genomic DNA with an antibody directed against a 34 x 10(3) M(r) giardin isoform selected a gene encoding a much larger polypeptide chain (HPSR2), the sequence of which was determined by chromosome walking the open reading frame. The complete gene has been cloned and expressed as a recombinant protein of 183 x 10(3) M(r). The predicted amino acid sequence of the protein has identifiable features suggesting that it might be a motor protein with an amino-terminal hydrolytic domain attached to a long coiled coil stalk. The presumed head domain is 211 residues and contains a P-loop sequence conserved in purine nucleotide-binding proteins. The remaining 1409 amino acids mainly make up a region of heptad repeats such as in myosin or the kinesin stalk, ending in a small (67 amino acids) carboxy-terminal domain. Fourier analysis of the predicted stalk shows the presence of a strong physical repeat created by regular heptad phase changes dividing the coil into segments of 25 residues. This structure most closely resembles the smaller microtubule-associated median body protein which has segments of 24 residues.
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PMID:Giardia gene predicts a 183 kDa nucleotide-binding head-stalk protein. 759 9

Motor domains of the Drosophila minus-end-directed microtubule (MT) motor protein ncd, were found to saturate microtubule binding sites at a stoichiometry of approximately one motor domain per tubulin dimer. To determine the tubulin subunit(s) involved in binding to ncd, mixtures of ncd motor domain and MTs were treated with the zero-length cross-linker 1-ethyl-3-(3-dimethylaminopropyl-carbodiimide) (EDC). EDC treatment generated covalently cross-linked products of ncd and alpha-tubulin and of ncd and beta-tubulin, indicating that the ncd motor domain interacts with both alpha- and beta-tubulin. When the Drosophila kinesin motor domain protein was substituted for the ncd motor domain, cross-linked products of kinesin and alpha-tubulin and of kinesin and beta-tubulin were produced. EDC treatment of mixtures of ncd motor domain and unassembled tubulin dimers or of kinesin motor domain and unassembled tubulin dimers produced the same motor-tubulin products generated in the presence of MTs. These results indicate that kinesin family motors of opposite polarity interact with both tubulin monomers and support a model in which some portion of each protein's motor domain overlaps adjacent alpha- and beta-tubulin subunits.
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PMID:ncd and kinesin motor domains interact with both alpha- and beta-tubulin. 759 61

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

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

Isolation of microtubule motor proteins is needed both for the discovery of new motors and for characterization of the products of motor-related genes. The sequences of motor-related genes cannot yet be used to predict the mechanochemical properties of the gene products. This was illustrated by the first kinesin-related gene product to be characterized. Protein expressed from the ncd gene moved toward the minus ends of microtubules (Walker et al., 1990; McDonald et al., 1990), while kinesin itself moves toward the plus ends. Until the relationship between mechanochemical function and amino acid sequence is more thoroughly understood, biochemical isolation and characterization of microtubule motor proteins will remain essential. Two approaches for getting useful quantities of microtubule motor proteins have been used: isolation from cytosol as described under Section II above and isolation from bacteria carrying cloned motor protein genes in expression vectors. Bacterial expression of functional microtubule motors has been successful to date in only a few cases (Yang et al., 1990; Walker et al., 1990, McDonald et al., 1990). Additional progress is expected with the expression of cloned genes from viral vectors in cultured eukaryotic cells, but broad success has not yet been reported. Biochemical isolation of motors from their natural cytosol has some distinct advantages. One can have confidence that a given motor will be folded properly and have normal post-translational modifications. In addition, if it exists in vivo as a heteromultimer, a microtubule motor isolated from its native cytosol will carry with it a normal complement of associated proteins. Studies of such associated proteins will be important in learning how motors accomplish their tasks in vivo. Drosophila cytosol should be a rich source of microtubule motors. Drosophila carry at least 11 and perhaps as many as 30 genes that are related to kinesin (Stewart et al., 1991; Endow and Hatsumi, 1991). The work of Tom Hays' lab indicates that Drosophila carry more than nine dynein related genes (Rasmussen et al., 1994). Relatively little effort to isolate the products of these genes from cytosol has been made. The only work that I am aware of has produced a kinesin-like microtubule motor (D.G. Cole, K.B. Sheehan, W.M. Saxton, and J.M. Scholey, in progress) that may be the Drosophila homolog of Xenopus eg5 (Sawin et al., 1992). This isolation was straightforward, and efforts to identify additional motors are almost assured of success.
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PMID:Isolation and analysis of microtubule motor proteins. 770 57

Changes of immunoreactivities for microtubule based motor proteins, kinesin and cytoplasmic dynein, and non-motor protein, microtubule associated protein (MAP) 2 were investigated in gerbil hippocampus after transient ischemia. The immunoreactivities for kinesin showed a progressive decrease in hippocampal CA1 cells from 8 h after transient 5 or 15 min of ischemia that is lethal to the CA1 cells, while it showed no change after 2 min of ischemia that is non-lethal to the cells. The immunoreactivities for cytoplasmic dynein showed a decrease from 3 or 1 h of reperfusion in the CA1 cells after 5 or 15 min of ischemia, respectively. In contrast, the immunoreactivity for MAP2 remained normal until 2 days in the CA1 cells after 5 min of ischemia. These results showed an early changes of microtubule based motor proteins, such as kinesin and cytoplasmic dynein in vulnerable CA1 neurons. These changes may affect the mitochondrial shuttle system between neuronal cell body and the peripheries such as axon terminal and dendrites. This early disturbance may cause a failure to obtain newly synthesized nuclear encoded mitochondrial protein, and result in mitochondrial dysfunctions and the subsequent cell death.
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PMID:Early immunohistochemical changes of microtubule based motor proteins in gerbil hippocampus after transient ischemia. 771 74

We describe here a new member of the kinesin superfamily in Drosophila, KLP3A (Kinesin-Like-Protein-at-3A). The KLP3A protein localizes to the equator of the central spindle during late anaphase and telophase of male meiosis. Mutations in the KLP3A gene disrupt the interdigitation of microtubules in spermatocyte central spindles. Despite this defect, anaphase B spindle elongation is not obviously aberrant. However, cytokinesis frequently fails after both meiotic divisions in mutant testes. Together, these findings strongly suggest that the KLP3A presumptive motor protein is a critical component in the establishment or stabilization of the central spindle. Furthermore, these results imply that the central spindle is the source of signals that initiate the cleavage furrow in higher cells.
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PMID:The Drosophila kinesin-like protein KLP3A is a midbody component required for central spindle assembly and initiation of cytokinesis. 773 Apr 6

The two-headed motor protein kinesin hydrolyzes nucleotide to move unidirectionally along its microtubule track at speeds up to 1000 nm/s (Saxton et al., 1988) and develops forces in excess of 5 pN (Hunt et al., 1994; Svoboda et al., 1994a). Individual kinesin molecules have been studied recently in vitro, and their behavior has been characterized in terms of force-velocity curves and variance measurements (Svoboda and Block, 1994a; Svoboda et al., 1994b). We present a model for force generation in kinesin in which the ATP hydrolysis reactions are coordinated with the relative positions of the two heads. The model explains the experimental data and permits us to study the relative roles of Brownian motion and elastic deformation in the motor mechanism of kinesin.
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PMID:Coordinated hydrolysis explains the mechanical behavior of kinesin. 778 69


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