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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)
Kinesin is an ubiquitous heterotetrameric microtubule-based motor which translocates membrane-bound organelles. Since organelle motility and motor protein function can be regulated by components of signaling pathways, the ability of purified bovine brain
kinesin
(
kinesin
) to be phosphorylated and to recognize calmodulin (CaM) was tested. Extensively purified "kinesin" was found to consist of several forms of both heavy (KHC) and light (KLC) chains. Phosphorylation of
kinesin
by a variety of protein kinases was examined; cAMP-dependent protein kinase (cAMP-PK) was the most active enzyme leading to the incorporation of up to 8 mol P/mol
kinesin
. Phosphorylation occurred predominantly on the KLCs and led to substantial acidic pI shifts. Peptide maps indicated that multiple phosphorylation sites exist on each KLC. Incubation of
kinesin
in vitro with protein kinase C (PKC) led to the phosphorylation of both KHCs and KLCs. In vivo phosphorylation of KHC and KLCs was demonstrated by immunoprecipitation of [32P]-labeled
kinesin
from cultured rat hippocampal pyramidal neurons;
kinesin
phosphorylation was stimulated by 8-chlorophenyl-thio-cAMP or 12-O-tetradecanoylphorbol-13-acetate. Native bovine brain
kinesin
was shown to bind 125I-CaM by nucleotide-dependent pelleting with stable microtubules. Specific calcium-dependent binding of 125I-CaM to KLCs but not KHC was found using a ligand blotting assay. cAMP-PK phosphorylated
kinesin
bound 125I-CaM less well than untreated protein in both ligand blotting and microtubule-pelleting paradigms. Calcium-dependent binding of CaM to
kinesin
inhibited the
ATPase
activity of native
kinesin
but not of cAMP-PK phosphorylated
kinesin
. These results suggest that the KLCs have a regulatory function and integrate information coming from diverse signaling pathways to modulate the activity and function of
kinesin
.
...
PMID:Calmodulin binding to and cAMP-dependent phosphorylation of kinesin light chains modulate kinesin ATPase activity. 838 85
We have expressed the recombinant squid
kinesin
head domain in Escherichia coli and studied its interaction with microtubules. The head is active as a microtubule-stimulated
ATPase
and binds to microtubules, but it does not support microtubule gliding by itself. The head binds to both microtubules and depolymerized tubulin. In each case the zero-length crosslinker 1-ethyl-3-[3-dimethylamino)propyl] carbodiimide induces a bond specifically to beta- but not alpha-tubulin. The head decorates brain microtubules with an 8-nm axial spacing. Thus the stoichiometry is one
kinesin
head per tubulin dimer. The lattice is that of flagellar B-tubules, implying that reassembled microtubules are not symmetric. Moreover, the A- and B-tubules of intact flagellar outer doublets are both decorated with a B lattice. This suggests that the B lattice is a general property of microtubules.
...
PMID:Recombinant kinesin motor domain binds to beta-tubulin and decorates microtubules with a B surface lattice. 844 80
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.
...
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)
...
PMID:Expression, purification, and characterization of the Drosophila kinesin motor domain produced in Escherichia coli. 848 45
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.
...
PMID:The Drosophila kinesin light chain. Primary structure and interaction with kinesin heavy chain. 851 98
The KLP61F gene product is essential for Drosophila development. Mutations in KLP61F display a mitotic arrest phenotype caused by a failure in the proper separation of duplicated centrosomes (Heck et al., 1993). Sequence analysis of KLP61F identified it as a member of the bimC family of
kinesin
-like microtubule motor proteins. Here we report that KLP61F is distinct from KRP130, a kinesin-like protein recently purified from Drosophila embryos and suggested to be the product of the KLP61F gene (Cole et al., 1994). We also characterized recombinant KLP61F and found that it possesses microtubule-stimulated
ATPase
and microtubule translocation activities in vitro. In addition, we have used an affinity-purified, KLP61F-specific antiserum to localize native KLP61F and an epitope-tagged KLP61F fusion protein during various stages of mitosis in Drosophila syncytial blastoderm embryos. From early prophase through anaphase, KLP61F is coincident with the distribution of tubulin. Together these results confirm the existence of multiple bimC-like kinesins in Drosophila and suggest that KLP61F function is intrinsic to the mitotic spindle.
...
PMID:Motor activity and mitotic spindle localization of the Drosophila kinesin-like protein KLP61F. 858 56
Acanthamoeba myosin-IA and myosin-IB are single-headed molecular motors that may play an important role in membrane-based motility. To better define the types of motility that myosin-IA and myosin IB can support, we determined the rate constants for key steps on the myosin-I
ATPase
pathway using fluorescence stopped-flow, cold-chase, and rapid-quench techniques. We determined the rate constants for ATP binding, ATP hydrolysis, actomyosin-I dissociation, phosphate release, and ADP release. We also determined equilibrium constants for myosin-I binding to actin filaments, ADP binding to actomyosin-I, and ATP hydrolysis. These rate constants define an
ATPase
mechanism in which (a) ATP rapidly dissociates actomyosin-I, (b) the predominant steady-state intermediates are in a rapid equilibrium between actin-bound and free states, (c) phosphate release is rate limiting and regulated by heavy-chain phosphorylation, and (d) ADP release is fast. Thus, during steady-state ATP hydrolysis, myosin-I is weakly bound to the actin filament like skeletal muscle myosin-II and unlike the microtubule-based motor
kinesin
. Therefore, for myosin-I to support processive motility or cortical contraction, multiple myosin-I molecules must be specifically localized to a small region on a membrane or in the actin-rich cell cortex. This conclusion has important implications for the regulation of myosin-I via localization through the unique myosin-I tails. This is the first complete transient kinetic characterization of a member of the myosin superfamily, other than myosin-II, providing the opportunity to obtain insights about the evolution of all myosin isoforms.
...
PMID:Biochemical kinetic characterization of the Acanthamoeba myosin-I ATPase. 860 84
We have examined the energetics of the interactions of two
kinesin
constructs with nucleotide and microtubules to develop a structural model of
kinesin
-dependent motility. Dimerization of the constructs was found to reduce the maximum rate of the microtubule-activated
kinesin
ATPase
5-fold. Beryllium fluoride and aluminum fluoride also reduce this rate, and they increase the affinity of
kinesin
for microtubules. By contrast, inorganic phosphate reduces the affinity of a dimeric
kinesin
construct for microtubules. These findings are consistent with a model in which the
kinesin
head can assume one of two conformations, "strong" or "weak" binding, determined by the nature of the nucleotide that occupies the active site. Data for dimeric
kinesin
are consistent with a model in which
kinesin
.ATP binds to the microtubule in a strong state with positive cooperativity; hydrolysis of ATP to ADP+P(i) leads to dissociation of one of the attached heads and converts the second, attached head to a weak state; and dissociation of phosphate allows the second head to reattach. These results also argue that a large free energy change is associated with formation of
kinesin
.ADP.P(i) and that this step is the major pathway for dissociation of
kinesin
from the microtubule.
...
PMID:Equilibrium studies of kinesin-nucleotide intermediates. 862 18
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.
...
PMID:Characterization of the biophysical and motility properties of kinesin from the fungus Neurospora crassa. 863 82
Steady-state and pre-steady-state kinetic methods were used to analyze two shorter Drosophila
kinesin
constructs (K341 and K366) in comparison to K401. K341, K366, and K401 represent the
kinesin
motor domains containing the N-terminal 341, 366, or 401 amino acids, respectively. K401 is dimeric (Kd = 37 +/- 17 nM) whereas both K366 and K341 are monomeric [Correia et al. (1995) Biochemistry 34, 4898-4907]. Like native
kinesin
and K401, K341 and K366 demonstrate low
ATPase
activity in the absence of microtubules (0.03 and 0.01 s-1, respectively), and ADP release is rate-limiting during steady-state turnover. Microtubules activate the steady-state
ATPase
to 84 s-1 for K341 (K(m),ATP = 100 microM; K0.5,MT = 3.2 microM tubulin) and 64 s-1 for K366 (K(m),ATP = 65 microM; K0.5,MT = 2.5 microM tubulin) in comparison to K401 at 20 s-1 (K(m)ATP = 60 microM; K0.5,MT = 1 microM tubulin). The rapid quench experiments for all three constructs show a burst of product formation during the first turnover, indicating the rate-limiting step for the microtubule-activated
ATPase
occurs after ATP hydrolysis. The interaction of K341 and K366 with the microtubule was analyzed by electron microscopy. The results show that K341 and K366, like K401, bind to the microtubule with an 8 nm axial periodicity. However, the addition of K366 to microtubules resulted in significant aggregation of microtubules. The pre-steady-state kinetic results show that K341 retains the kinetic and structural properties necessary to compare directly the kinetic properties of monomeric and dimeric kinesins, although the microtubule-activated
ATPase
is significantly faster for the monomeric constructs, suggesting possible interactions in the dimer which inhibit ATP turnover as part of the coupling to force production.
...
PMID:Purification and characterization of two monomeric kinesin constructs. 863 76
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