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)

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 mechanochemical ATPase kinesin is thought to move membrane-bounded organelles along microtubules in fast axonal transport. However, fast transport includes several classes of organelles moving at rates that differ by an order of magnitude. Further, the fact that cytoplasmic forms of kinesin exist suggests that kinesins might move cytoplasmic structures such as the cytoskeleton. To define cellular roles for kinesin, the axonal transport of kinesin was characterized. Retinal proteins were pulse-labeled, and movement of radiolabeled kinesin through optic nerve and tract into the terminals was monitored by immunoprecipitation. Heavy and light chains of kinesin appeared in nerve and tract at times consistent with fast transport. Little or no kinesin moved with slow axonal transport indicating that effectively all axonal kinesin is associated with membranous organelles. Both kinesin heavy chain molecular weight variants of 130,000 and 124,000 M(r) (KHC-A and KHC-B) moved in fast anterograde transport, but KHC-A moved at 5-6 times the rate of KHC-B. KHC-A cotransported with the synaptic vesicle marker synaptophysin, while a portion of KHC-B cotransported with the mitochondrial marker hexokinase. These results suggest that KHC-A is enriched on small tubulovesicular structures like synaptic vesicles and that at least one form of KHC-B is predominantly on mitochondria. Biochemical specialization may target kinesins to appropriate organelles and facilitate differential regulation of transport.
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PMID:Fast axonal transport of kinesin in the rat visual system: functionality of kinesin heavy chain isoforms. 753 59

Dynein and kinesin have been implicated as the molecular motors that are responsible for the fast transport of axonal membranous organelles and vesicles. Experiments performed in vitro with partially reconstituted preparations have led to the hypothesis that kinesin moves organelles in the anterograde direction and dynein moves them in the retrograde direction. However, the molecular basis of transport directionality remains unclear. In the experiments described here, carboxylated fluorescent beads were injected into living Mauthner axons of lamprey and the beads were observed to move in both the anterograde and retrograde directions. The bead movement in both directions required intact microtubules, occurred at velocities approaching organelle fast transport in vivo, and was inhibited by vanadate at concentrations that inhibit organelle fast transport. When living axons were injected with micromolar concentrations of vanadate and irradiated at 365 nm prior to bead injections, a treatment that results in the V1 photolysis of dynein, the retrograde movement of the beads was specifically abolished. Neither the ultraviolet irradiation alone nor the vanadate alone produced the retrograde-specific inhibition. These results support the hypothesis that dynein is required for retrograde, but not anterograde, transport in vivo.
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PMID:Retrograde but not anterograde bead movement in intact axons requires dynein. 754 25

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

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

Synthetic antisense oligonucleotides have been used to inhibit specific protein synthesis in vivo. Antisense oligonucleotides directed to kinesin heavy chain were injected into the vitreous of anesthetized rabbits in order to assess the effects on transport in the retinal ganglion cells whose axons form the optic nerve. The antisense oligonucleotide specifically inhibited retinal kinesin synthesis by 82 +/- 7% (n = 4). The rapid axonal transport of the membrane proteins into the optic nerve was concomitantly inhibited by 70 +/- 10% (n = 4). These results provide direct evidence for the specific role of kinesin in rapid anterograde transport in vivo and indicate the utility of antisense oligonucleotides to explore neuronal dynamics in a specific neuronal cell type in a living animal.
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PMID:Inhibition of kinesin synthesis and rapid anterograde axonal transport in vivo by an antisense oligonucleotide. 768 25

In the nematode Caenorhabditis elegans, mutants in osm-3 gene are known to be defective in osmotic avoidance, chemotaxis and dauer formation behaviours. To study the molecular basis of these pleiotropic defects we have cloned the osm-3 gene by germline transformation of osm-3 (p802) mutants through microinjection of the wild type genomic DNA. Northern analysis reveals a 3.0 kb transcript corresponding to osm-3. DNA sequencing of the transforming 4.3 kb fragment revealed a kinesin heavy chain-like protein, which contains conserved ATPase and microtubule binding domains. Our results are consistent with the previous EM data on osm-3 (p802) mutants that show an accumulation of dense matrix material in the amphid sheath cytoplasm and a shortened distal segment of the amphid channel cilium. These data suggest a kinesin-like role of the osm-3 product in axonal transport.
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PMID:C. elegans osm-3 gene mediating osmotic avoidance behaviour encodes a kinesin-like protein. 769 Feb 65

The effect of neuropathic and non-neuropathic organophosphates (OPs) and acrylamide on an in vitro kinesin-driven microtubule (MT) motility assay was compared. The goal of the study was to determine whether this in vitro assay could confirm that a mechanism of action of neuropathic OPs was to impair kinesin activity and, therefore, possibly fast axonal anterograde transport (FAAT) in vivo. For our study, kinesin from chicken brain (CK) and sea urchin egg (SUK) was initially purified. Western immunoblotting confirmed the close antigenic homology between CK and SUK, using a mouse monoclonal sea urchin kinesin heavy chain-specific antibody (SUK 4). In the presence of microtubules (MTs) and MgATP, both CK- and SUK-driven MT movement was measured using a video-enhanced differential interference contrast microscope system with computer-assisted analysis. Using this assay system, we then tested separately the effect of two neuropathic OPs (diisopropylfluorophosphate (DFP) and phenyl saligenin phosphate (PSP)) and a non-neuropathic OP (paraoxon (PO)) each at a concentration of 10(-2) M at 27 degrees C. Additionally, we tested acrylamide (10(-2) M), since it is one of the best-characterized neurotoxins impairing FAAT in vivo. Our results demonstrated that none of these compounds significantly affected kinesin-driven MT motility in vitro compared to the standard controls. Further, this assay system was thus not able to discriminate between the neuropathic and non-neuropathic effect of these OPs.
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PMID:The effect of organophosphates on a chicken brain or sea urchin egg kinesin-driven microtubule motility assay. 769 24

Cytoplasmic microtubules are fibrous intracellular organelles found in almost all eukaryotic cells and play an important role in maintenance of cell shape, cell division, axonal transport, secretion and receptor activity. Besides tubulin dimers, microtubule proteins consist of several other components called MAPs which promote microtubule assembly and form long filamentous projection on the surface of the polymer. In mammalian brain, two classes of MAPs have been characterized; one is structural MAPs including MAP1 (1A and 1B), MAP2 (2A, 2B and 2C) and tau which function in the morphogenesis and maintenance of neural tissues and cells, and the other contains motor MAPs (kinesin and MAP1C) which are related to translocation of vesicles along microtubules in axon and to mitosis. The primary sequences of MAPs have been determined from their cDNAs. The functions of structural MAPs are modulated by their binding to other intracellular components, different expressions of isoforms during brain development and phosphorylation-dephosphorylation by various protein kinases and phosphatases. Biochemical characterization of MAP2 and tau have been well investigated. However, little is known about the function of MAP1 under the biochemical level, because MAP1 is unstable and high sensitive to proteases. We have developed a simple and rapid purification procedure for MAP1 using poly (L-aspartic acid) and taxol, and observed MAP1-F-actin interaction as well as MAP1-microtubules interaction. Recently, we have found that three specific kinases which can phosphorylate MAP1A and 1B are associated with MAP1 preparation and called it MAP1 kinase. Some evidence suggest that one of them is an unknown kinase and others are casein kinase I- and II-like kinases. Further studies to examine MAP1 kinase and phosphorylation of MAP1 provide a valuable insight for understanding thoroughly the microtubule-mediated functions.
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PMID:[Structure and function of mammalian brain microtubule-associated proteins]. 793 91

Kinesin, a microtubule-dependent ATPase, is believed to be involved in anterograde axonal transport. The kinesin head, which contains both microtubule and ATP binding sites, has the necessary components for the generation of force and motility. We have used saturation binding and electron microscopy to examine the interaction of the kinesin motor domain with the microtubule surface and found that binding saturated at one kinesin head per tubulin heterodimer. Both negative staining and cryo-electron microscopy revealed a regular pattern of kinesin bound to the microtubule surface, with an axial repeat of 8 nm. Optical diffraction analysis of decorated microtubules showed a strong layer-line at this spacing, confirming that one kinesin head binds per tubulin heterodimer. The addition of Mg-ATP to the microtubule-kinesin complex resulted in the complete dissociation of kinesin from the microtubule surface.
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PMID:Decoration of the microtubule surface by one kinesin head per tubulin heterodimer. 809 24


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