Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: 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 examine the possible role of kinesin in pigment granule migration in the retinal pigment epithelium (RPE) of teleosts, we investigated the expression and distribution of kinesin heavy chain (KHC) in RPE. Blots of fish RPE lysates probed with two well-characterized antibodies to KHC (H2 and HD) displayed a prominent band at 120 kD. A third KHC antibody (SUK4) recognized a band at 118 kD. The 118 kD band was also occasionally present in blots probed with H2, suggesting the presence of two KHC isoforms in teleost RPE. Reverse transcriptase-polymerase chain reaction (RT-PCR) of mRNA from RPE using primers homologous to conserved regions of the KHC motor domain resulted in the identification of two putative KHC genes (FKIF1 and FKIF5) based on partial amino acid sequences. Previous studies had demonstrated a requirement for microtubules in pigment granule aggregation in RPE. In addition, the reported microtubule polarity orientation in RPE apical projections is consistent with a role for kinesin in pigment granule aggregation. Immunofluorescent localization of KHC in isolated RPE cells using H2 revealed a mottled distribution over the entire cell body, with no detectable selective association with pigment granules, even in cells fixed while aggregating pigment granules. Microinjected KHC antibodies had no effect on pigment granule aggregation or dispersion, although each of the three antibodies has been shown to block kinesin function in other systems. Thus we found no evidence for KHC function in RPE pigment granule aggregation. However, the two KHC isoforms may participate in other microtubule-dependent processes in RPE.
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PMID:Expression of kinesin heavy chain isoforms in retinal pigment epithelial cells. 755 3

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

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

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

In Caenorhabditis elegans three genetic loci osm-3, unc-104 and unc-116 have been identified, which encode anterograde motor kinesin. Here we show that osm-3 encodes a 672 amino acid long kinesin-like protein (KLP) that contains all three functional domains similar to the kinesin heavy chain, including a globular motor region, an alpha-helical coiled-coil rod, and a globular tail region. OSM-3 shows homology in both the motor and rod domains with kinesins from divergent species such as mouse KIF3, and sea urchin KRP95, and also with the rod domains of several non-kinesin proteins, such as myosin, ezrin, outer membrane proteins alpha precursor OMPA, yeast intracellular protein transport USO1, and the rat neurofilament NF-H. Temporal and spatial expression of the osm-3::lacZ fusion gene during development is limited to an exclusive set of 26 chemosensory neurons whose dendritic endings are exposed to the external environment, including six IL2 neurons of the inner labial sensilla, eight pairs of amphid neurons (ADF, ADL, ASE, ASG, ASH, ASI, ASJ, ASK) in the head, and two pairs of phasmid neurons (PHA and PHB) in the tail. Our data are consistent with the known structural defects in the amphid and phasmid sensilla in osm-3 mutants and also show the expression of the gene in IL2 neurons. Temporally, the gene is differentially expressed in all three types of chemosensory sensilla. Further work on osm-3, unc-104 and unc-116 mutants should give insight into the in vivo functions of the kinesin family during C. elegans neurogenesis.
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PMID:Exclusive expression of C. elegans osm-3 kinesin gene in chemosensory neurons open to the external environment. 771 94

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

A 100-kDa polypeptide with microtubule-interacting properties was identified in a Golgi vesicle-enriched fraction from Corylus avellana pollen. The k71s23 antibody (directed to the kinesin heavy chain from bovine brain) [Tiezzi et al., 1992: Cell Motil. Cytoskeleton 21:132-137] localized the polypeptide on the external surface of membrane-bounded organelles. Some 100-kDa-containing vesicles copelleted with microtubules (polymerized from purified bovine brain tubulin) either in presence or absence of 5 mM AMPPNP, but they could be released by 10 mM ATP or 0.5 M KCl. The pollen microtubule-interacting protein, salt-extracted from membranes and partially purified by gel filtration, exhibited an ATPase activity (16.2 nmolPi/mg/min) which could be stimulated about 2-fold (32.5 nmolPi/mg/min) by addition of bovine brain microtubules. We suppose that the 100-kDa polypeptide is part of a molecular complex showing properties of the kinesin class.
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PMID:Kinesin-related polypeptide is associated with vesicles from Corylus avellana pollen. 782 Aug 65

The distribution and dynamics of both the ER and Golgi complex in animal cells are known to be dependent on microtubules; in many cell types the ER extends toward the plus ends of microtubules at the cell periphery and the Golgi clusters at the minus ends of microtubules near the centrosome. In this study we provide evidence that the microtubule motor, kinesin, is present on membranes cycling between the ER and Golgi and powers peripherally directed movements of membrane within this system. Immunolocalization of kinesin at both the light and electron microscopy levels in NRK cells using the H1 monoclonal antibody to kinesin heavy chain, revealed kinesin to be associated with all membranes of the ER/Golgi system. At steady-state at 37 degrees C, however, kinesin was most concentrated on peripherally distributed, pre-Golgi structures containing beta COP and vesicular stomatitis virus glycoprotein newly released from the ER. Upon temperature reduction or nocodazole treatment, kinesin's distribution shifted onto the Golgi, while with brefeldin A (BFA)-treatment, kinesin could be found in both Golgi-derived tubules and in the ER. This suggested that kinesin associates with membranes that constitutively cycle between the ER and Golgi. Kinesin's role on these membranes was examined by microinjecting kinesin antibody. Golgi-to-ER but not ER-to-Golgi membrane transport was found to be inhibited by the microinjected anti-kinesin, suggesting kinesin powers the microtubule plus end-directed recycling of membrane to the ER, and remains inactive on pre-Golgi intermediates that move toward the Golgi complex.
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PMID:Kinesin is the motor for microtubule-mediated Golgi-to-ER membrane traffic. 784 44

The N-terminal residues of the two heavy chains of the motor enzyme kinesin form two globular "heads"; the heads are attached to a "rod" domain which is a two-stranded alpha-helical coiled-coil. Interaction between the heads is thought to be important to kinesin function. The rod may not be necessary for head-head interactions because a heavy chain N-terminal fragment containing only residues from the head and adjacent region forms dimers (Huang, T.-G., Suhan, J., and Hackney, D. D. (1994) J. Biol. Chem. 269, 16502-16507). However, the nature and stability of the subunit-subunit interactions in such derivatives are unclear. To examine the physical properties of heavy chain interaction in and near the head domains, we characterized the self-association behavior of two dimeric kinesin derivatives predicted (Lupas, A., van Dyke, M., and Stock, J. (1991) Science 252, 1162-1164) to lack the rod. Derivative K448-BIO contains the 448 N-terminal residues of Drosophila kinesin heavy chain fused at the C terminus to a 2-residue linker and a C-terminal fragment from Escherichia coli biotin carboxyl carrier protein; derivative K448-L is the same except that it lacks the biotin carboxyl carrier protein fragment. Both derivatives expressed in insect cells display microtubule-stimulated ATPase activity; K448-BIO also displays microtubule motility. Equilibrium sedimentation and gel filtration indicate that purified K448-BIO and K448-L at 0.02-0.4 mg/ml form homogeneous solutions of homodimers with no detectable formation of monomers or higher order oligomers. Derivative self-association is non-covalent but extremely stable with an association constant > or = 2 x 10(8) M-1. Stable subunit-subunit association induced by structures in and near the kinesin heads may be necessary for full mechanochemical function.
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PMID:Subunit interactions in dimeric kinesin heavy chain derivatives that lack the kinesin rod. 787 39

The motor protein kinesin is implicated in organelle movement toward the plus ends of microtubules, but little is known about its interaction with organelle membranes or about the physiological role of the phosphorylation of kinesin and its associated protein kinectin seen in neurons in vivo (Hollenbeck, P. J. (1993) J. Neurochem. 60, 2265-2275). Here we have demonstrated that the kinesin heavy chain (KHC), light chain, and kinectin isolated from chick brain or sympathetic neurons exist in several isoelectric forms. Metabolic labeling followed by phosphatase treatment showed that these are phosphoisoforms, and that phosphorylation is reversible in vitro. To assess the capability of phosphorylation to regulate kinesin's state and/or activity, we performed 32P and 35S pulse-chase experiments with neuronal cultures and determined that kinesin-associated phosphate turns over 3-4 times faster than the proteins themselves. When the phosphoisoform distributions for different kinesin pools were analyzed, it was found that membrane-associated KHC contained predominantly the most highly phosphorylated isoform, while soluble kinesin consisted of less phosphorylated KHC isoforms. Nerve growth factor-induced neurite outgrowth in PC12 cells was found to increase significantly kinesin's 32P specific activity while doubling the relative abundance of the most highly phosphorylated KHC isoform. These results demonstrate that the phosphorylation state of kinesin is closely coupled to its organelle binding and to the magnitude of organelle transport in the cell. We propose that the phosphorylation state of kinesin and associated proteins may regulate motility via association with organelle membranes and, specifically, that KHC phosphorylation induces membrane association.
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PMID:Phosphorylation of kinesin in vivo correlates with organelle association and neurite outgrowth. 789 Jun 79


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