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)

Serum autoantibodies from a patient with autoantibodies directed against the Golgi complex were used to screen clones from a HepG2 lambda Zap cDNA library. Three related clones, designated SY2, SY10, and SY11, encoding two distinct polypeptides were purified for further analysis. Antibodies affinity purified by adsorption to the lambda Zap-cloned recombinant proteins and antibodies from NZW rabbits immunized with purified recombinant proteins reproduced Golgi staining and bound two different proteins, 95 and 160 kD, from whole cell extracts. The SY11 protein was provisionally named golgin-95 and the SY2/SY10 protein was named golgin-160. The deduced amino acid sequence of the cDNA clone of SY2 and SY11 represented 58.7- and 70-kD proteins of 568 and 620 amino acids. The in vitro translation products of SY2 and SY11 cDNAs migrated in SDS-PAGE at 65 and 95 kD, respectively. The in vitro translated proteins were immunoprecipitated by human anti-Golgi serum or immune rabbit serum, but not by normal human serum or preimmune rabbit serum. Features of the cDNA suggested that SY11 was a full-length clone encoding golgin-95 but SY2 and SY10 together encoded a partial sequence of golgin-160. Analysis of the SY11 recombinant protein identified a leucine zipper spanning positions 419-455, a glutamic acid-rich tract spanning positions 322-333, and a proline-rich tract spanning positions 67-73. A search of the SwissProt data bank indicated sequence similarity of SY11 to human restin, the heavy chain of kinesin, and the heavy chain of myosin. SY2 shared sequence similarity with the heavy chain of myosin, the USO1 transport protein from yeast, and the 150-kD cytoplasmic dynein-associated polypeptide. Sequence analysis demonstrated that golgin-95 and golgin-160 share 43% sequence similarity and, therefore, may be functionally related proteins.
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PMID:Molecular characterization of two human autoantigens: unique cDNAs encoding 95- and 160-kD proteins of a putative family in the Golgi complex. 831 94

Kinesin is a cytoplasmic motor protein that moves along microtubules and can induce microtubule bundling and sliding in vitro. To determine how kinesin mediates microtubule interactions, we determined the shapes and mass distributions of squid brain kinesin, taxol-stabilized microtubules (squid and bovine), and adenosine 5'-[beta, gamma-imido]triphosphate-stabilized kinesin-microtubule complexes by high-resolution metal replication and by low-temperature, low-dose dark-field scanning transmission electron microscopy of unfixed, directly frozen preparations. Mass mapping by electron microscopy revealed kinesins loosely attached to the carbon support as asymmetrical dumbbell-shaped molecules, 40-52 nm long, with a mass of 379 +/- 15 kDa. The mass distribution and shape of these molecules suggest that these images represent kinesin in a shortened conformation. Kinesin-microtubule complexes were organized as bundles of linearly arrayed microtubules, stitched together at irregular intervals by cross-bridges typically < or = 25 nm long. The crossbridges had a mass of 360 +/- 15 kDa, consistent with one kinesin per crossbridge. These results suggest that kinesin has a second microtubule binding site in addition to the known site on the motor domain of the heavy chain; this second site may be located near the C terminus of the heavy chains or on the associated light chains. Thus, kinesin could play a role in either crosslinking or sliding microtubules.
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PMID:Single kinesin molecules crossbridge microtubules in vitro. 834 62

Studies of granule-microtubule interactions in human neutrophils have suggested that mechanochemical ATPases such as kinesin or dynein may play a role in granule mobilization during neutrophil activation by inflammatory signals. In this study we show that proteins extracted from the surface of neutrophil granules, found previously to contain microtubule-dependent ATPase activity, caused microtubules polymerized from phosphocellulose-purified rat brain tubulin to move across glass slides. Antibodies were generated against peptides based on two regions of the amino acid sequence of Drosophila kinesin: the ATPase active site (amino acids 86-99) in the head of the kinesin heavy chain and the tail of the heavy chain (residues 913-933). These antibodies were found to recognize kinesin in rat brain extracts as well as kinesin-like polypeptides in extracts of human neutrophils. Furthermore, when used in immunoaffinity chromatography, these antibodies permitted the isolation of a protein from neutrophil granule extracts that was recognized by Drosophila kinesin antibodies. Subcellular localization by immunofluorescence microscopy showed this protein to be associated principally with the cytoplasmic granules of neutrophils.
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PMID:Affinity purification and subcellular localization of kinesin in human neutrophils. 848 17

We describe two dynein heavy chain (DHC)-like polypeptides (DHCs 2 and 3) that are distinct from the heavy chain of conventional cytoplasmic dynein (DHC1) but are expressed in a variety of mammalian cells that lack axonemes. DHC2 is a distant member of the "cytoplasmic" branch of the dynein phylogenetic tree, while DHC3 shares more sequence similarity with dynein-like polypeptides that have been thought to be axonemal. Each cytoplasmic dynein is associated with distinct cellular organelles. DHC2 is localized predominantly to the Golgi apparatus. Moreover, the Golgi disperses upon microinjection of antibodies to DHC2, suggesting that this motor is involved in establishing proper Golgi organization. DCH3 is associated with as yet unidentified structures that may represent transport intermediates between two or more cytoplasmic compartments. Apparently, specific cytoplasmic dyneins, like individual members of the kinesin superfamily, play unique roles in the traffic of cytomembranes.
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PMID:Mammalian cells express three distinct dynein heavy chains that are localized to different cytoplasmic organelles. 866 68

Invasion of mammalian cells by the protozoan parasite Trypanosoma cruzi occurs by an actin-independent mechanism distinct from phagocytosis. Clusters of host lysosomes are observed at the site of parasite attachment, and lysosomal markers are detected in the vacuolar membrane at early stages of the entry process. These observations led to the hypothesis that the trypanosomes recruit host lysosomes to their attachment site, and that lysosomal fusion serves as a source of membrane to form the parasitophorous vacuole. Here we directly demonstrate directional migration of lysosomes to the parasite entry site, using time-lapse video-enhanced microscopy of L6E9 myoblasts exposed to T. cruzi trypomastigotes. BSA-gold-loaded lysosomes moved towards the cell periphery, in the direction of the parasite attachment site, but only when their original position was less than 11-12 microns from the invasion site. Lysosomes more distant from the invasion area exhibited only the short multi-directional saltatory movements previously described for lysosomes, regardless of their proximity to the cell margins. Specific depletion of peripheral lysosomes was obtained by microinjection of NRK cells with antibodies against the cytoplasmic domain of lgp 120, a treatment that aggregated lysosomes in the perinuclear area and inhibited T. cruzi entry. The microtubule-binding drugs nocodazole, colchicine, vinblastine, and taxol also inhibited invasion, in both NRK and L6E9 cells. Furthermore, microinjection of antibodies to the heavy chain of kinesin blocked the acidification-induced, microtubule-dependent redistribution of lysosomes to the host cell periphery, and reduced trypomastigote entry. Our results therefore demonstrate that during T. cruzi invasion of host cells lysosomes are mobilized from the immediately surrounding area, and that availability of lysosomes at the cell periphery and microtubule/kinesin-mediated transport are requirements for parasite entry.
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PMID:Host cell invasion by trypanosomes requires lysosomes and microtubule/kinesin-mediated transport. 870 21

AtKCBP is a calcium-dependent calmodulin-binding protein from Arabidopsis that contains a conserved kinesin microtubule motor domain. Calmodulin has been shown previously to bind to heavy chains of the unconventional myosins, where it is required for in vitro motility of brush border myosin I, but AtKCBP is the first kinesin-related heavy chain reported to be capable of binding specifically to calmodulin. Other kinesin proteins have been identified in Arabidopsis, but none of these binds to calmodulin, and none has been demonstrated to be a microtubule motor. We have tested bacterially expressed AtKCBP for the ability to bind microtubules to a glass surface and induce gliding of microtubules across the glass surface. We find that AtKCBP is a microtubule motor protein that moves on microtubules toward the minus ends, with the opposite polarity as kinesin. In the presence of calcium and calmodulin, AtKCBP no longer binds microtubules to the coverslip surface. This contrasts strikingly with the requirement of calmodulin for in vitro motility of brush border myosin I. Calmodulin could regulate AtKCBP binding to microtubules in the cell by inhibiting the binding of the motor to microtubules. The ability to bind to calmodulin provides an evolutionary link between the kinesin and myosin motor proteins, but our results indicate that the mechanisms of interaction and regulation of kinesin and myosin heavy chains by calmodulin are likely to differ significantly.
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PMID:In vitro motility of AtKCBP, a calmodulin-binding kinesin protein of Arabidopsis. 899 Feb 7

Microtubule-associated tau proteins are likely candidates to interfere with axonal transport of membranous organelles. We studied that tau proteins influenced the enzyme activity of kinesin, known to drive anterograd transport along microtubules. An in vitro reconstituted system was applied; microtubules were assembled from purified tubulin with or without tau proteins. Both types of reconstituted microtubules stimulated MgATPase activity of purified kinesin in a concentration dependent, saturable manner. The extent of maximal stimulation by tau-coated microtubules was lower than that of microtubules without tau proteins. Analysis of kinetic data, on the other hand, suggests that tau-coated microtubules apparently bind kinesin with higher affinity then microtubules not associated with tau proteins. Tau proteins, similarly to tubulin dimers, seem to bind to the heavy chain of kinesin. These data support the notion that tau proteins could act as regulators of kinesin-driven processes.
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PMID:Tau proteins bind to kinesin and modulate its activation by microtubules. 920 Jan 33

A gene encoding the heavy chain of conventional kinesin (kin2) has recently been identified in the dimorphic fungus Ustilago maydis (Lehmler et al., 1997). From the phenotype of kin2 null-mutants it was concluded that Kin2 might be involved in vesicle traffic towards the tip. However, this model did not explain why kin2-null mutant hyphae were unable to create empty cell compartments that are normally left behind the growing tip cell. Here we present a re-investigation of the function of Kin2 in hyphae and sporidia. We provide evidence that suggests a different and unexpected role of this kinesin motor in hyphal growth of Ustilago maydis. In addition, Kin2 was partially purified from U. maydis and in vitro properties were investigated. Isolated kinesin supported in vitro microtubule gliding at speeds of up to 1.8 micron/second, and showed motility properties and hydrodynamic behavior similar to those described for kinesin from N. crassa. It appears to be the product of the kin2 gene. Compared with wild-type sporidia, the kin2-null mutant sporidia grew normally but were defective in accumulation of Lucifer Yellow in their vacuoles, which were smaller than normal and often misplaced. The dikaryotic hyphae, produced by the fusion of two kin2-null sporidia, showed tip growth, but unlike wild-type hyphae, these structures lacked the large, basal vacuole and contain significantly more 200-400 nm vesicles scattered over the hole hypha. This defect was accompanied by a failure to generate regular empty cell compartments that are left behind in wild-type tip cells as the hyphae grow longer. These results suggest that Kin2 is a microtubule-dependent motor enzyme which is involved in the formation of vacuoles. The accumulation of these vacuoles at the basal end of the tip cell might be crucial for the formation of the empty sections and supports cytoplasmic migration during the growth of dikaryotic hyphae.
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PMID:Kinesin from the plant pathogenic fungus Ustilago maydis is involved in vacuole formation and cytoplasmic migration. 966 45

We have investigated the mechanism by which conventional kinesin is prevented from binding to microtubules (MTs) when not transporting cargo. Kinesin heavy chain (HC) was expressed in COS cells either alone or with kinesin light chain (LC). Immunofluorescence microscopy and MT cosedimentation experiments demonstrate that the binding of HC to MTs is inhibited by coexpression of LC. Association between the chains involves the LC NH2-terminal domain, including the heptad repeats, and requires a region of HC that includes the conserved region of the stalk domain and the NH2 terminus of the tail domain. Inhibition of MT binding requires in addition the COOH-terminal 64 amino acids of HC. Interaction between the tail and the motor domains of HC is supported by sedimentation experiments that indicate that kinesin is in a folded conformation. A pH shift from 7.2 to 6.8 releases inhibition of kinesin without changing its sedimentation behavior. Endogenous kinesin in COS cells also shows pH-sensitive inhibition of MT binding. Taken together, our results provide evidence that a function of LC is to keep kinesin in an inactive ground state by inducing an interaction between the tail and motor domains of HC; activation for cargo transport may be triggered by a small conformational change that releases the inhibition of the motor domain for MT binding.
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PMID:Light chain-dependent regulation of Kinesin's interaction with microtubules. 981 61

The membranous outer segments of vertebrate photoreceptors are supported by cytoskeletons consisting of microtubules and associated proteins, which occur as the ciliary axoneme in rods and cones, and as a separate cytoskeletal system at the incisures of rod outer segments. We performed an immunocytochemical study of the cytoskeleton in photoreceptors isolated from amphibian retinas and found that immunoreactivity to the heavy chain of the motor protein kinesin was closely associated with the microtubules in each of these outer segment cytoskeletal systems. In the outer segments of cones, kinesin heavy chain immunoreactivity was confined to a streak at the axoneme that extended to the outer segment tip. In the outer segments of rods, kinesin heavy chain immunoreactivity was found as both a short streak at the axoneme and a series of long parallel lines that coincided with the microtubules at rod outer segment incisures. Our findings constitute the first report of kinesin in the axoneme of cones and at the incisures of rods. Closely associated with microtubules, kinesin in photoreceptor outer segment axonemes and at rod outer segment incisures can transport materials longitudinally along the microtubules and/or connect these with each other and/or with other components. Because these cytoskeletal systems differ in fundamental ways, kinesin can play different roles in each case, e.g., kinesin at rod outer segment incisures can have structural and functional roles that are unique to rods. These findings may have clinical relevance because similar cytoskeletal systems are expected to occur in the outer segments of human photoreceptors; thus, a disturbance involving kinesin in the cytoskeletal systems at photoreceptor axonemes and/or at rod outer segment incisures could interfere with the normal structure and function of photoreceptors and contribute to human photoreceptor degenerations.
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PMID:Association of kinesin with microtubules in diverse cytoskeletal systems in the outer segments of rods and cones. 983 60


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