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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 neck region of
kinesin
constitutes a key component in the enzyme's walking mechanism. Here we applied cryoelectron microscopy and image reconstruction to investigate the location of the
kinesin
neck in dimeric and monomeric constructs complexed to microtubules. To this end we enhanced the visibility of this region by engineering an SH3 domain into the transition between neck linker and neck coiled coil. The resulting chimeric
kinesin
constructs remained functional as verified by physiology assays. In the presence of
AMP
-PNP the SH3 domains allowed us to identify the position of the neck in a well defined conformation and revealed its high flexibility in the absence of nucleotide. We show here the double-headed binding of dimeric
kinesin
along the same protofilament, which is characterized by the opposite directionality of neck linkers. In this configuration the neck coiled coil appears fully zipped. The position of the neck region in dimeric constructs is not affected by the presence of the tubulin C-termini as confirmed by subtilisin treatment of microtubules prior to motor decoration.
...
PMID:Nucleotide-induced conformations in the neck region of dimeric kinesin. 1266 Jan 59
Switch I and II are key active site structural elements of kinesins, myosins, and G-proteins. Our analysis of a switch I mutant (R210A) in Drosophila melanogaster
kinesin
showed a reduction in microtubule affinity, a loss in cooperativity between the motor domains, and an ATP hydrolysis defect leading to aberrant detachment from the microtubule. To investigate the conserved arginine in switch I further, a lysine substitution mutant was generated. The R210K dimeric motor has lost the ability to hydrolyze ATP; however, it has rescued microtubule function. Our results show that R210K has restored microtubule association kinetics, microtubule affinity, ADP release kinetics, and motor domain cooperativity. Moreover, the active site at head 1 is able to distinguish ATP, ADP, and
AMP
-PNP to signal head 2 to bind the microtubule and release mantADP with kinetics comparable with wild-type. Therefore, the structural pathway of communication from head 1 to head 2 is restored, and head 2 can respond to this signal by binding the microtubule and releasing mantADP. Structural modeling revealed that lysine could retain some of the hydrogen bonds made by arginine but not all, suggesting a structural hypothesis for the ability of lysine to rescue microtubule function in the Arg210 mutant.
...
PMID:A kinesin switch I arginine to lysine mutation rescues microtubule function. 1286 Sep 92
In order to investigate the microtubule-associated intracellular trafficking of the NH2-terminal cellular prion protein (PrPC) fragment [Biochem. Biophys. Res. Commun. 313 (2004) 818], we performed a real-time imaging of fluorescent PrPC (GFP-PrPC) in living cells. Such GFP-PrPC exhibited an anterograde movement towards the direction of plasma membranes at a speed of 140-180 nm/s, and a retrograde movement inwardly at a speed of 1.0-1.2 microm/s. The anterograde and retrograde movements of GFP-PrPC were blocked by a
kinesin
family inhibitor (
AMP
-PNP) and a dynein family inhibitor (vanadate), respectively. Furthermore, anti-
kinesin
antibody (alpha-
kinesin
) blocked its anterograde motility, whereas anti-dynein antibody (alpha-dynein) blocked its retrograde motility. These data suggested the
kinesin
family-driven anterograde and the dynein-driven retrograde movements of GFP-PrPC. Mapping of the interacting domains of PrPC identified amino acid residues indispensable for interactions with
kinesin
family: NH2-terminal mouse (Mo) residues 53-91 and dynein: NH2-terminal Mo residues 23-33, respectively. Our findings argue that the discrete N-terminal amino acid residues are indispensable for the anterograde and retrograde intracellular movements of PrPC.
...
PMID:Anterograde and retrograde intracellular trafficking of fluorescent cellular prion protein. 1498 83
We have studied the structure of microtubules decorated with
kinesin
motor domains in different nucleotide states by 3D electron microscopy. Having docked the atomic coordinates of both dimeric ADP.
kinesin
and tubulin heterodimer into a map of
kinesin
dimers bound to microtubules in the presence of ADP, we try to predict which regions of the proteins interact in the weakly binding state. When either the presence of 5'-adenylyimidodiphosphate (
AMP
-PNP) or an absence of nucleotides puts motor domains into a strongly-bound state, the 3D maps show changes in the motor domains which modify their interaction with beta-tubulin. The maps also show differences in beta-tubulin conformation compared with undecorated microtubules or those decorated with weakly-bound motors. Strongly-bound ncd appears to produce an identical change.
...
PMID:3D electron microscopy of the interaction of kinesin with tubulin. 1521 83
The motor protein
kinesin
moves along microtubules, driven by adenosine triphosphate (ATP) hydrolysis. However, it remains unclear how
kinesin
converts the chemical energy into mechanical movement. We report crystal structures of monomeric
kinesin
KIF1A with three transition-state analogs: adenylyl imidodiphosphate (
AMP
-PNP), adenosine diphosphate (ADP)-vanadate, and ADP-AlFx (aluminofluoride complexes). These structures, together with known structures of the ADP-bound state and the adenylyl-(beta,gamma-methylene) diphosphate (
AMP
-PCP)-bound state, show that
kinesin
uses two microtubule-binding loops in an alternating manner to change its interaction with microtubules during the ATP hydrolysis cycle; loop L11 is extended in the
AMP
-PNP structure, whereas loop L12 is extended in the ADP structure. ADP-vanadate displays an intermediate structure in which a conformational change in two switch regions causes both loops to be raised from the microtubule, thus actively detaching
kinesin
.
...
PMID:KIF1A alternately uses two loops to bind microtubules. 1528 75
Interaction of
kinesin
-coated latex beads with a single microtubule (MT) was directly observed by fluorescence microscopy. In the presence of ATP, binding of a
kinesin
bead to the MT facilitated the subsequent binding of other
kinesin
beads to an adjacent region on the MT that extended for micrometers in length. This cooperative binding was not observed in the presence of ADP or 5'-adenylylimidodiphosphate (
AMP
-PNP), where binding along the MT was random. Cooperative binding also was induced by an engineered, heterodimeric
kinesin
, WT/E236A, that could hydrolyze ATP, yet remained fixed on the MT in the presence of ATP. Relative to the stationary WT/E236A
kinesin
on a MT, wild-type
kinesin
bound preferentially in close proximity, but was biased to the plus-end direction. These results suggest that
kinesin
binding and ATP hydrolysis may cause a long-range state transition in the MT, increasing its affinity for
kinesin
toward its plus end. Thus, our study highlights the active involvement of MTs in
kinesin
motility.
...
PMID:Long-range cooperative binding of kinesin to a microtubule in the presence of ATP. 1573 63
KIF1A, a kinesin-related motor protein that transports pre-synaptic vesicles in neurons, was originally presumed to translocate along microtubules (MT) as a monomer. Protein structure predictions from its amino acid sequence failed to identify the long coiled-coil domains typical of kinesins, which led researchers to believe it does not oligomerize into the canonical
kinesin
dimer. However, mounting evidence using recombinant chimeric protein indicates that KIF1A, like conventional
kinesin
, requires dimerization for fast, unidirectional processive movement along MTs. Because these studies are somewhat indirect, we wished to test the oligomerization state of native KIF1A, and to compare that to full-length recombinant protein. We have performed hydrodynamic analyses to determine the molecular weights of the respective complexes. Our results indicate that most native KIF1A is soluble and indeed monomeric, but recombinant KIF1A is a dimer. MT-binding studies also showed that native KIF1A did not bind to MTs in either the presence of
AMP
-PNP, apyrase, or adenosine triphosphate (ATP), but recombinant KIF1A bound to MTs most stably in the presence of ATP, indicating very different motor functional states. To further characterize KIF1A's dimerization potential, we prepared peptides corresponding to the neck domains of MmKIF1A and CeUnc104, and by circular dichroism spectroscopy compared these peptides for their ability to form coiled-coils. Interestingly, both MmKIF1A and CeUnc104 neck peptides formed homodimeric coiled-coils, with the MmKIF1A neck coiled-coil exhibiting the greater stability. Collectively, from our data and from previous studies, we predict that native KIF1A can exist as both an inactive monomer and an active homodimer formed in part through its neck coiled-coil domain.
...
PMID:Monomeric and dimeric states exhibited by the kinesin-related motor protein KIF1A. 1588 13
Kinesins are motor proteins that transport their cargos along microtubules in an ATP-dependent manner. The testis-specific
kinesin
KIF17b was shown to directly regulate cAMP-response element modulator (CREM)-dependent transcription by determining the subcellular localization of the activator of CREM in testis (ACT), the testis-specific coactivator of CREM in postmeiotic male germ cells. CREM is a crucial transcriptional regulator of many important genes required for spermatid maturation, as demonstrated by the complete block of sperm development at the first steps of spermiogenesis in crem-null mice. To better understand the complex regulation of postmeiotic germ cell differentiation, we further characterized the ACT-KIF17b interaction, the function of KIF17b, and the signaling pathways governing its action. In this study, we demonstrated that the abilities of KIF17b to shuttle between the nuclear and the cytoplasmic compartments and to transport ACT are neither dependent on its motor domain nor on microtubules, thus revealing a novel microtubule-independent function for kinesins. We also showed that the cyclic AMP-dependent protein kinase A mediates the phosphorylation of KIF17b, and this modification is important for its subcellular localization. These results indicate that cyclic
AMP
signaling controls CREM-mediated transcription in male germ cells through modification of KIF17b function.
...
PMID:Microtubule-independent and protein kinase A-mediated function of kinesin KIF17b controls the intracellular transport of activator of CREM in testis (ACT). 1600 95
The
kinesin
-binding site on the microtubule has not been identified because of the technical difficulties involved in the mutant analyses of tubulin. Exploiting the budding yeast expression system, we succeeded in replacing the negatively charged residues in the alpha-helix 12 of beta-tubulin with alanine and analyzed their effect on
kinesin
-microtubule interaction in vitro. The microtubule gliding assay showed that the affinity of the microtubules for
kinesin
was significantly reduced in E410A, D417A, and E421A, but not in E412A mutant. The unbinding force measurement revealed that in the former three mutants, the
kinesin
-microtubule interaction in the adenosine 5'-[beta,gamma-imido]triphosphate state (
AMP
-PNP state) became less stable when a load was imposed towards the microtubule minus end. In parallel with this decreased stability, the stall force of
kinesin
was reduced. Our results implicate residues E410, D417, and E421 as crucial for the
kinesin
-microtubule interaction in the strong binding state, thereby governing the size of
kinesin
stall force.
...
PMID:Identification of a strong binding site for kinesin on the microtubule using mutant analysis of tubulin. 1712 95
Kinesin-1 is a two-headed molecular motor that walks along microtubules, with each step gated by adenosine triphosphate (ATP) binding. Existing models for the gating mechanism propose a role for the microtubule lattice. We show that unpolymerized tubulin binds to
kinesin
-1, causing tubulin-activated release of adenosine diphosphate (ADP). With no added nucleotide, each
kinesin
-1 dimer binds one tubulin heterodimer. In adenylyl-imidodiphosphate (
AMP
-PNP), a nonhydrolyzable ATP analog, each
kinesin
-1 dimer binds two tubulin heterodimers. The data reveal an ATP gate that operates independently of the microtubule lattice, by ATP-dependent release of a steric or allosteric block on the tubulin binding site of the tethered
kinesin
-ADP head.
...
PMID:An ATP gate controls tubulin binding by the tethered head of kinesin-1. 1741 43
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