EC:3.6.4.4 - FACTA Search

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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)

The nonclaret disjunctional (ncd) protein is a kinesin-related microtubule motor protein that is encoded at the claret locus in Drosophila and is required for proper chromosome distribution in meiosis and early mitosis. The protein contains a region with 41% amino acid sequence identity to kinesin heavy chain, but translocates on microtubules with the opposite polarity to kinesin, toward microtubule minus ends. The overall structure of ncd also differs from kinesin heavy chain, in that the proposed motor domain is present at the C terminus of the molecule instead of the N terminus, as in kinesin heavy chain. In studies to define the molecular determinants of ncd function, we constructed and expressed a protein with a deletion of the N-terminal 208 amino acids of the non-motor region. Analysis of the truncated protein shows that the protein exhibits microtubule-stimulated Mg(2+)-ATPase activity and binds microtubules in pelleting assays. In contrast to near full-length ncd, the truncated protein does not support directional movement of microtubules in in vitro motility assays. Instead, microtubules show nucleotide-sensitive binding to the truncated protein on glass surfaces and bound microtubules exhibit one-dimensional diffusional movement that is constrained to their longitudinal axis. The diffusional movement reveals a weak binding state of the ncd motor that may represent a mechanochemical intermediate in its ATP hydrolysis cycle. If diffusional movement is a characteristic intrinsic to the claret motor, it is likely to be important in the in vivo function of the protein.
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PMID:An N-terminal truncation of the ncd motor protein supports diffusional movement of microtubules in motility assays. 831 80

We have demonstrated the presence of kinesin in the secretory pancreatic tissue using SDS-PAGE, immunoblot and immunoelectron microscopy techniques. Polyclonal antibodies were raised against the rat brain kinesin heavy chain and affinity-purified. Immunoblot studies showed that these antibodies were bound to a 116 kDa protein found in rat pancreas crude extracts and in partially purified kinesin fractions. Kinesin identification was also performed by a cosedimentation procedure based on its strong binding to microtubules in the presence of sodium fluoride. The microtubule-kinesin complex was observed by immunoelectron microscopy gold staining. The reversible association of kinesin with microtubules was generated by MgATP.
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PMID:Rat pancreas kinesin: identification and potential binding to microtubules. 833 81

Nonclaret disjunctional (ncd) is a kinesin-related microtubule motor protein that is required for proper chromosome distribution in Drosophila. Despite its sequence similarity to kinesin heavy chain, ncd translocates with the opposite polarity as kinesin, toward microtubule minus ends. We have expressed different regions of the protein in bacteria and analyzed the proteins for function. Results indicate that ncd consists of three domains: a basic, proline-rich N-terminal "tail," a central alpha-helical coiled-coil stalk, and a C-terminal motor domain. The ncd N terminus proteins bundle microtubules in motility assays and show ATP-independent binding to microtubules in solution. Truncated proteins, lacking the tail but containing the predicted motor domain and differing lengths of the stalk, did not support microtubule gliding in in vitro assays but showed microtubule-stimulated MgATPase activity in solution. Addition of a nonspecific N terminus to two of the truncated proteins restored directional gliding and rotation of microtubules in motility assays, demonstrating that these properties map to the predicted mechanochemical domain of ncd. Physical properties of the C terminus proteins indicate that the stalk region is important for dimerization and that the ncd protein probably exists and functions as a dimer.
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PMID:Structural and functional domains of the Drosophila ncd microtubule motor protein. 847 43

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

The Drosophila kinesin heavy-chain gene was truncated to obtain the N-terminal 401 amino acid motor domain (designated K401) containing both the microtubule and ATP binding sites. The plasmid construct with the truncated kinesin gene was used to transform Escherichia coli. After induction, K401 was expressed as soluble kinesin protein at high levels and purified to homogeneity in milligram quantities. The purified protein was active and behaved as native kinesin with respect to its steady-state kinetic properties: K401 demonstrated a very low ATPase activity (kcat = 0.01 s-1) which was stimulated approximately 1000-fold by the addition of microtubules (kcat = 10 s-1; K0.5,MT = 0.9 microM tubulin; Km,ATP = 31 microM). Like native kinesin, K401 when purified contained ADP tightly bound at its active site, and the release of ADP from the active site occurred at a rate equal to the steady-state ATPase kcat. Active-site measurements using [alpha-32P]ATP demonstrated a stoichiometry of one ATPase site per K401 molecule. Like native kinesin, K401 can also hydrolyze MgGTP, and in the presence of microtubules, the rate of hydrolysis was increased dramatically from 0.03 to 16 s-1 (K0.5,MT = 2 microM tubulin; Km,GTP = 3.5 mM). These results establish that an active kinesin motor domain can be bacterially expressed and that this domain, the N-terminal 401 amino acids of the Drosophila kinesin heavy chain without light chains or additional eukaryotic factors, has full catalytic activity with microtubules.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Expression, purification, and characterization of the Drosophila kinesin motor domain produced in Escherichia coli. 848 45

The microtubule-based motor protein kinesin is thought to drive anterograde organelle transport in axons, but nothing is known about how its force-generating activity or organelle-binding properties are regulated. Studies in other motility systems suggest that protein phosphorylation is a reasonable candidate for this function. I report here that the kinesin heavy chain (HC) and light chain (LC), as well as the 160-kDa kinesin-associated protein kinectin, are phosphorylated in vivo in cultures of chick sympathetic neurons and PC12 cells labeled metabolically with 32P. In neurons, both kinesin chains are phosphorylated exclusively on serine residues, and limiting tryptic digestion demonstrated that the phosphorylation sites are clustered in a region of < or = 5 kDa for the HC and < or = 14 kDa for the LC. Partial tryptic digestion of 32P-labeled HC followed by immunoblotting with SUK4 monoclonal anti-HC and fluorography showed that the sites of HC phosphorylation are outside the globular N-terminal head region where kinesin's microtubule-binding and mechanochemical activities reside. Treatment of metabolically labeled neurons with forskolin, phorbol esters, or calcium ionophore did not alter the extent of phosphorylation, the phosphoamino acid composition, or the V8 protease phosphopeptide maps of the HC, LC, and 160-kDa protein, with one exception: treatment with calcium ionophore reduced the specific activity of the LC. In addition, when kinesin from PC12 cells was compared with that from PC12-derived cell lines lacking protein kinase A activity, neither the extent of phosphorylation nor the phosphopeptide maps were altered for either chain. Phosphopeptide mapping experiments also showed that postlysis kinase activity can phosphorylate both the neuronal HC and LC at sites not phosphorylated in vivo.
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PMID:Phosphorylation of neuronal kinesin heavy and light chains in vivo. 849 30

A gene family, designated kat, has been characterized in Arabidopsis thaliana by genomic Southern hybridization and nucleotide sequencing analysis. The kat gene family includes at least five members, named katA, katB, katC, katD and katE, whose products share appreciable sequence similarities in their presumptive ATP-binding and microtubule-binding motifs with known kinesin-like proteins. The carboxyl-terminal region of the KatA protein deduced from the nucleotide sequence of the cDNA clone has considerable homology with the mechanochemical motor domain of the kinesin heavy chain. The predicted secondary structure of the KatA protein indicates two globular domains separated by a long alpha helical coiled coil with heptad repeat structures, such as are commonly found in kinesin-like proteins.
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PMID:Identification of a gene family (kat) encoding kinesin-like proteins in Arabidopsis thaliana and the characterization of secondary structure of KatA. 849 4

Kinesin light chain (KLC) complexes with the kinesin heavy chain (KHC) to form native kinesin. Proposed functions of KLC include coupling of cargo to KHC or modulation of KHC ATPase activity. In this paper we use the KHC tail, which binds specifically to KLC in blot overlays, as a probe to clone a cDNA encoding KLC from a Drosophila expression library. The identified clone encodes a protein with 70% amino acid identity to rat KLC. Drosophila KLC is predicted to form an alpha-helical coiled-coil between residues 34 and 129, followed by five imperfect tandem repeats of unknown function and a sixth shorter motif. These repeats are highly conserved across species. The Drosophila KLC gene is located at 69D on the third chromosome and is widely expressed, with 1.8-kb transcripts in most tissues, and slightly smaller transcripts in gonads. Finally, we present evidence that the heptad repeats of KLC are required for interaction with the KHC tail. Since the KHC tail used in our assay includes about 20 heptad repeats, this result suggests that KHC and KLC interact via coiled-coils. Such an interaction could provide stability to the KHC-KLC complex in vivo.
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PMID:The Drosophila kinesin light chain. Primary structure and interaction with kinesin heavy chain. 851 98

Progress regarding the kinesins is now being made at a rapid and accelerating rate. The in vivo-functions, and biophysical and enzymatic properties of kinesin itself are being explored at ever increasing levels of detail. The kinesin-related proteins now number several dozen, and although more is known about primary structure than function for most of the proteins, this trend is already reversing. For example, knowledge about the kinesin-related protein, ncd, is expanding rapidly, and more is already known about its three-dimensional structure than is known for kinesin heavy chain. This volume presents a comprehensive review of the major published works on kinesin and kinesin-related proteins. Hopefully, this manuscript will complement other recent review articles [17, 20, 25, 37, 60-62, 67, 69, 75, 85-88, 231, 233, 238, 244, 269-271, 281, 282, 292] or books [49, 227, 293] that have focused on more selective aspects of the kinesin family, or have been aimed more generally at MT motor proteins. In line with the stated purpose of the Protein Profile series, annual updates of the review on the kinesins are planned for at least the next few years.
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PMID:Motor proteins 1: kinesins. 854 43

Neurospora kinesin (Nkin) is a distant relative of the family of conventional kinesins, members of which have been identified in various animal species. As in its animal counterparts, Nkin most likely is an organelle motor. Because it is a functional homologue of the kinesin heavy chain of higher eukaryotes, its biophysical and motility properties were compared with those of other conventional kinesins. Purified Nkin behaves as a homodimeric complex composed of two subunits of a 105-kDa polypeptide. Based on its hydrodynamic properties (Stokes radius and sedimentation coefficient), Nkin is an elongated molecule, although it is more compact than its animal counterparts. A detailed comparison of the motility properties of Nkin with those of animal conventional kinesins reveals similarities and some intriguing differences. Nkin is less effective than other kinesins in the use of natural nucleoside triphosphates but responds to a selection of ATP analogues in a similar fashion as mammalian kinesin. Even in the presence of saturating concentrations of ATP, Nkin is significantly more sensitive to ADP or tripolyphosphate than other kinesins. Both the ATP-driven microtubule gliding activity and the microtubule-stimulated ATPase activity of Nkin obey Michaelis-Menten kinetics. Surprisingly, however, the Km values for both these activities are approximately an order of magnitude higher than those of other kinesins. Whether the low affinity for ATP suggested by these high Km values is related to the high rate of motility remains to be determined.
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PMID:Characterization of the biophysical and motility properties of kinesin from the fungus Neurospora crassa. 863 82

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