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)

The ability of kinesin to interact with microtubules in a nucleotide-dependent manner and mediate microtubule-based motility has received the greatest amount of attention to date. Several lines of experimentation are now beginning to examine the interaction with membrane-bounded organelles. Immunochemical, biochemical and morphological approaches have shown that kinesin is associated with some, but not all, classes of membrane-bounded organelles found in cells. Similarly, evidence suggests that the distal portion of the rod and the tail portions of the kinesin heavy chain as well as the kinesin light chains may be important for the interaction with membrane surfaces. As a substantial amount of information about the molecular structure and biochemistry of kinesin has become available, the functional implications of interactions with membrane structures in vivo are being addressed.
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PMID:Kinesin interactions with membrane bounded organelles in vivo and in vitro. 183 61

Mutations in the unc-104 gene of the nematode C. elegans result in uncoordinated and slow movement. Transposon insertions in three unc-104 alleles (e2184, rh1016, and rh1017) were used as physical markers to clone the unc-104 gene. DNA sequence analysis of unc-104 cDNAs revealed an open reading frame capable of encoding a 1584 amino acid protein with similarities to kinesin heavy chain. The similarities are greatest in the amino-terminal ATPase and microtubule-binding domains. Although the primary sequence relatedness to kinesin is weak in the remainder of the molecule, the predicted secondary structure and regional isoelectric points are similar to kinesin heavy chain.
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PMID:The C. elegans unc-104 gene encodes a putative kinesin heavy chain-like protein. 184 75

We report the cDNA sequence of the squid kinesin heavy chain and compared the predicted amino acid sequence with that of the Drosophila heavy chain as reported by Yang, J.T., Laymon, R.A., and Goldstein, L.S. B. (1989) Cell 56, 879-889). We compared the two kinesin sequences with regard to the predicted physicochemical parameters of hydrophobicity, charge, and propensities of the secondary conformations. A comparison of the sequences from the two species reveals the head, stalk, and tail domains because a reduced degree of conservation demarcates the stalk. The charge profile indicates that the head region is nearly neutral, the stalk region acidic, and the tail is basic. The Fourier transform analysis of the hydrophobic profile of the stalk shows predominant peaks at 1/3.5 and 1/2.3, which are indexed as the second and third orders of the period 7 residue. As in the Drosophila sequence, the rod domain is divided into an amino and a carboxyl subdomain by a predicted hinge region. We show that the disposition of hydrophobic residues is distinct in these two subdomains. In particular, the heptad repeat is more regular in the amino-terminal rod domain than in the carboxyl-terminal rod domain. The tail region is positively charged, a feature that is consistent with the known electrostatic interaction between the heavy chain and negatively charged surfaces such as glass coverslips and latex beads. Three monoclonal antibodies to the kinesin heavy chain have been mapped to a region within the carboxyl terminus of the stalk.
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PMID:The primary structure and analysis of the squid kinesin heavy chain. 213 56

The KAR3 gene is essential for yeast nuclear fusion during mating, and its expression is strongly induced by alpha factor. The predicted KAR3 protein sequence contains two globular domains separated by an alpha-helical coiled coil. The carboxy-terminal domain is homologous to the amino-terminal mechanochemical domain of Drosophila kinesin heavy chain. Mutation of the putative ATP binding site produces a dominant "poison" of nuclear fusion. The mutant protein shows enhanced microtubule association in vivo, as predicted for a kinesin-like protein in a state of rigor binding. Localization of hybrid proteins to cytoplasmic microtubules in shmoos indicates that the amino-terminal domain also contains determinants for microtubule association. Thus, KAR3 is a member of a larger family of kinesin-like proteins characterized by the presence of the mechanochemical domain tethered to different protein binding domains. The phenotypes of kar3 mutants suggest that the protein mediates microtubule sliding during nuclear fusion and possibly mitosis.
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PMID:KAR3, a kinesin-related gene required for yeast nuclear fusion. 213 12

We have isolated and compared the 116-kilodalton (kDa) kinesin heavy chain from DU 145 human prostatic tumor cells and bovine brain. Comparative sodium dodecyl sulfate - polyacrylamide gel electrophoreses (SDS-PAGE), Western blots, and proteolytic digestion analysis all showed that the 116-kDa polypeptides from both sources were indistinguishable. Polyclonal antibodies raised against sea urchin kinesin cross-reacted with both brain and DU 145 kinesin on Western blots. SDS-PAGE and A-5m chromatographic studies indicated that kinesin forms a quarternary heteropolymer of approximately 400 kDa. DU 145 cells had three proteins of 116, 72, and 64 kDa forming the heteropolymer, in a 2:1:1 ratio, whereas brain cells appeared to have equimolar amounts of the 116-kDa heavy chain and a 64-kDa light chain.
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PMID:Properties of kinesin isolated from human prostatic DU 145 tumor cells and bovine brain. 214 May 13

We identified and sequenced a cDNA clone encoding a kinesin-like protein from Drosophila. The predicted product of this cDNA has a carboxy-terminal domain that is substantially similar to the motor domain of kinesin heavy chain. The amino-terminal domain is unlike that found in previously identified kinesins or kinesin-like proteins. Analyses of this new sequence suggest that the maximal motor unit in the kinesin superfamily may be as little as 350 amino acids, and that the existence of both kinesin and kinesin-like molecules must be an evolutionarily ancient feature of eukaryotes. We also tested some of the biochemical properties of the protein encoded by this cDNA and found them to be similar to those of kinesin. Finally, the clone we isolated appears to correspond to the non-claret disjunctional (ncd) gene, which when mutant causes defects in meiotic and early embryonic mitotic chromosome segregation, and whose recently determined sequence predicts a kinesin-like domain.
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PMID:Identification and characterization of a gene encoding a kinesin-like protein in Drosophila. 214 Sep 58

Kinesin is a mechanochemical protein that converts the chemical energy in adenosine triphosphate into mechanical force for movement of cellular components along microtubules. The regions of the kinesin molecule responsible for generating movement were determined by studying the heavy chain of Drosophila kinesin, and its truncated forms, expressed in Escherichia coli. The results demonstrate that (i) kinesin heavy chain alone, without the light chains and other eukaryotic factors, is able to induce microtubule movement in vitro, and (ii) a fragment likely to contain only the kinesin head is also capable of inducing microtubule motility. Thus, the amino-terminal 450 amino acids of kinesin contain all the basic elements needed to convert chemical energy into mechanical force.
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PMID:Evidence that the head of kinesin is sufficient for force generation and motility in vitro. 214 32

The nod gene is required for the distributive segregation of nonexchange chromosomes during meiosis in D. melanogaster. Loss-of-function nod mutations cause nondisjunction and loss of nonrecombinant chromosomes both at meiosis I and during subsequent mitotic divisions. We have cloned the nod locus, examined its expression patterns, and determined its coding sequence. In adults the nod transcript is only present in females, consistent with the observation that males do not use the distributive segregation system. However, the nod locus is also transcribed in the embryonic, larval, and pupal stages of development, and possibly in all dividing cells. Finally, the N-terminal domain of the predicted nod protein has amino acid similarity to the mechanochemical domain of kinesin heavy chain; however, the C-terminal domain is unlike that of kinesin heavy chain or of any previously reported protein. Thus, the nod protein is a member of the kinesin superfamily and may be a microtubule motor.
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PMID:A kinesin-like protein required for distributive chromosome segregation in Drosophila. 214 92

The structure equivalent to higher eukaryotic centrosomes in fission yeast, the nuclear membrane-bound spindle pole body, is inactive during interphase. On transition from G2 to M phase of the cell cycle, the spindle pole body duplicates; the daughter pole bodies seed microtubules which interdigitate to form a short spindle that elongates to span the nucleus at metaphase. We have identified two loci which, when mutated, block spindle formation. The predicted product of one of these genes, cut7+, contains an amino-terminal domain similar to the kinesin heavy chain head domain, indicating that the cut7+ product could be a spindle motor. The cut7+ gene resembles the Aspergillus nidulans putative spindle motor gene bimC, both in terms of its organization with a homologous amino-terminal head and no obvious heptad repeats and in the morphology of the mutant phenotype. But we find no similarity between the carboxy termini of these genes, suggested that either the cut7+ gene represents a new class of kinesin genes and that fission yeast may in addition contain a bimC homologue, or that the carboxy termini of these mitotic kinesins are not evolutionarily conserved and that the cut7+ gene belongs to a subgroup of bimC-related kinesins.
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PMID:Novel potential mitotic motor protein encoded by the fission yeast cut7+ gene. 214 14

Kinesin was isolated from bovine intradural nerve roots and conjugated with 5-(iodoacetamido)fluorescein. The modified kinesin (AF-kinesin) supports the movement of organelles along microtubules at rates comparable with those obtained using unmodified kinesin. AF-kinesin was purified by high-performance liquid chromatography. SDS/PAGE analysis of the purified fraction showed the presence of a fluorescent band at the position of the 125-kDa kinesin heavy chain. This protein promoted microtubule gliding with MgATP and with MgGTP at rates comparable to those of unlabelled kinesin. AF-kinesin had a fluorescein/protein ratio of one. Video microscopy at low light levels was used to monitor the interactions between the analogue and microtubules. AF-kinesin binds to microtubules in the presence of adenosine 5'-[beta, gamma-imino]triphosphate or ADP. Brief incubation of the microtubule. AF-kinesin complex with 10 mM ATP or GTP completely removes the labelled molecule. AF-kinesin can be inactivated in its ability to cause microtubule gliding by irradiating it with light that bleaches the bound fluorophore. When the protein is damaged in this way it still binds to microtubules and does so in the presence of ATP.
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PMID:Characterization of an active, fluorescein-labelled kinesin. 214 15


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