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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)
A six-step mechanism is derived for the activation of
kinesin
K379 ATPase by microtubules. The data are fitted by the kinetic scheme [Formula see text] where T, D, and P refer to nucleotide triphosphate, nucleotide diphosphate, and inorganic phosphate, respectively; MtK refers to the complex of a K379 unit with the microtubule binding site. The initial binding and release steps, 1 and 6, are treated as rapid equilibria: k2 = 200 s-1, k3 = 100 s-1, k5 = 35-40 s-1, maximum steady-state rate = 25 s-1 (50 mM NaCl, 20 degrees C). k2 was obtained from the maximum rate of fluorescence enhancement with mant-ATP as substrate, k3 was obtained from the hydrolysis transient phase for ATP or mant-ATP, and k5 was obtained from the rate of decrease in fluorescence of mant-
ADP
in the reaction [Formula see text]. A large excess of ATP was present with the Mt to block rebinding of mant-
ADP
. The rate was measured as a function of microtubule concentration and extrapolated to give the maximum rate k5. The same method was used to obtain k5 for
ADP
by mixing K.
ADP
with microtubules plus excess mant-ATP. The enhancement of fluorescence for the binding of mant-ATP is followed by a decrease in fluorescence with a rate constant of 35-40 s-1. Since the decrease must occur after hydrolysis, it may be correlated with a step or steps leading to the low fluorescence MtK.D state. In the kinetic scheme, steps 4 and 5 both contribute to determining the maximum turnover rate. At higher ionic strengths or lower protein concentrations, the MtK complex is dissociated by ATP. The maximum rate is 12 +/- 2 s-1 in 50 mM NaCl; consequently, hydrolysis occurs before dissociation. The dissociation constant of MtK in the presence of
ADP
is twice as large as the dissociation constant in the presence of ATP and four times larger than the KM for microtubule activation. The proposed kinetic scheme, which treats the K379 units of a dimer as independent, provides a satisfactory description of the transient and steady-state properties of the system with the possible exception of results at very low substrate concentrations.
...
PMID:Mechanism of microtubule kinesin ATPase. 754 88
ncd is a kinesin-related motor protein from Drosophila that moves in the opposite direction along microtubules to
kinesin
. To learn more about the ncd mechanism, ncd motor domain (R335-K700) was expressed in Escherichia coli and its enzymatic characteristics were studied. The ncd motor domain was purified from the cell lysate by S-Sepharose chromatography, and trace amounts of contaminants were removed by passing through a MonoQ column. The yield was 20 mg from a 500 mL culture of E. coli. The purified ncd motor domain exhibited an unusual UV spectrum with a broad peak around 272-275 nm, which was at least partly due to the bound nucleotide. Upon incubation with radioactive ATP, 3H at adenine but not 32P at gamma-phosphate was retained by the protein on gel filtration, indicating it bound
ADP
but not ATP. Thus, like
kinesin
, nucleotide binding to the ncd motor domain is tight, although there is an equilibrium between the protein and free nucleotide. We also used a fluorescent ATP analogue, mantATP, for the kinetic study of ncd motor domain. MantATP was turned over by ncd motor domain slowly in the absence of microtubules, but microtubules activated the turnover to a similar extent to that of ATP. Upon incubation with ncd motor domain, the fluorescent intensity of mantATP increased at 0.005 s-1, which is likely to reflect the release of endogenous
ADP
and incorporation of mantATP into the protein. The fluorescence intensity of the ncd motor domain having bound mantADP, likewise, decreased upon mixing with ATP, representing the mantADP release.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Expression, purification, ATPase properties, and microtubule-binding properties of the ncd motor domain. 754 90
Studies of immobilized
kinesin
have shown that a single dimeric molecule can maintain contact with and drive sliding of a microtubule. In solution, however, native
kinesin
binds microtubules too weakly and hydrolyses ATP too slowly to produce the high sliding velocities seen in motility assay. This apparent inhibition in solution appears to be caused by the binding of
kinesin
's tail domains to its motor (head) domains in a folded conformation. DKH392, a construct containing two heads but no tails, has been shown to display both tight binding to microtubules and high ATPase rates. Furthermore, it retains one molecule of
ADP
per dimer when bound to microtubules, which could facilitate a 'hand-over-hand' mechanism for processive motion. Here we show that DKH392 hydrolyses more than 100 ATP molecules per diffusional encounter with a microtubule, even in the high-salt conditions encountered physiologically. This provides direct evidence that
kinesin
's activity is highly processive, with the motor remaining attached to a microtubule through many cycles of ATP hydrolysis.
...
PMID:Highly processive microtubule-stimulated ATP hydrolysis by dimeric kinesin head domains. 756 25
The motor protein non-claret disjunctional (ncd) moves towards the minus ends of microtubules (MTs), whereas its close relative
kinesin
moves in the opposite direction towards the plus ends of MTs. The mechanisms of movement and directional reversal for these motor proteins are unknown. Here we report the rate constants for MT activated
ADP
release from a recombinant double-headed ncd protein, GST-MC5, and a recombinant double-headed kinesin protein, K delta 401, measured using the fluorescent nucleotide analogues methylanthranilyol ATP (mantATP) and mantADP. Comparison of the maximal MT activated mantADP release rates for these proteins with their maximal MT activated mantATP turnover rates indicates that
ADP
release is the rate-limiting step for ATP turnover for both ncd and
kinesin
. This data supports the view that directional reversal may result from structural rather than chemical kinetic differences in the way the motors interact with MTs.
...
PMID:ADP release is the rate-limiting step of the MT activated ATPase of non-claret disjunctional and kinesin. 763 15
Bacterial expressed
kinesin
motor domains hydrolyze ATP and promote microtubule-dependent motility. It has routinely been assumed that motor domain preparations are monomeric on the basis of the presumption that dimerization is mediated by the stalk region. However, experimental verification of the oligomeric state of the
kinesin
construct is required to interpret the results from single-molecule motility assays as well as presteady-state kinetic experiments. We have measured directly the state of assembly of three conventional
kinesin
motor domain constructs-K401, K366, and K341, comprising the N-terminal 401, 366, and 341 amino acids, respectively, of the Drosophila kinesin heavy chain-by sedimentation velocity and sedimentation equilibrium methods in an analytical ultracentrifuge. K401 (MW of
ADP
complex, 45,532) is a predominantly a dimer with a sedimentation coefficient, s020,w, of 5.06 S, but it is able to self-associate by means of a 1-2-4 mechanism into higher oligomers. Molecular weight measurements establish the dissociation constant for dimerization at 37 +/- 17 nM in the presence of ATP. The dissociation constant in the presence of
ADP
is 35 +/- 26 nM and in the presence of AMPPNP is 42 +/- 28 nM. The construct K366 (MW of
ADP
complex, 41,404) is a monomer (measured MW, 41,768 +/- 1219) at concentrations below 4 microM K366, with a sedimentation coefficient, s020,w, of 3.25 S. At higher concentrations, there is evidence for a weak association of K366 to a 1-2-4-8 model with a slight preference for octamer formation. The smallest construct, K341 (MW of
ADP
complex, 38,274), is a monomer (measured MW, 38,191 +/- 734) up to at least 10 microM total K341 concentration with a sedimentation coefficient, s020,w, of 2.9 S. Thus, the dimerization domain either is between amino acid residues 367 and 401 or is strongly affected by the removal of this region. Higher oligomers of K401 form by a mechanism involving dimers of dimers, and suggest that native
kinesin
may also undergo self-association. These results have important implications for the interpretation of ATP-dependent motility assays.
...
PMID:Sedimentation studies on the kinesin motor domain constructs K401, K366, and K341. 771 94
We have established pathway of the
kinesin
ATPase by direct measurement of each step in the pathway. Kinesin binds to microtubules with an 8-nm repeat and a stoichiometry of one
kinesin
monomer unit per tubulin dimer. Thus, the dimeric
kinesin
binds with both heads attached to the microtubule and on adjacent tubulin subunits. In the steady state,
kinesin
has a low ATPase activity that is limited by the rate of
ADP
release (< 0.01 s-1) in the absence of microtubules and is activated 2000-fold by the addition of microtubules to achieve a maximum rate of approximately 20 s-1. Transient-state kinetic analysis has provided direct measurement of individual steps of the reaction to define the pathway of the microtubule-
kinesin
ATPase. These studies establish that the rate-limiting step in the ATPase pathway is the release of the
kinesin
-product complex (K.
ADP
.P) from the microtubule following ATP hydrolysis. After phosphate release, the rebinding of
kinesin
-
ADP
to the microtubule is fast, accounting for the high activation of the ATPase at low microtubule concentration. This ATPase cycle explains the phenomenological differences between myosin and
kinesin
observed in motility assays. Kinesin remains associated with a microtubule through multiple rounds of hydrolysis, because it spends only a small fraction of its duty cycle in the dissociated state. The discussion of this paper will focus on the new data, their interpretation, and significance for mechanisms of force production. The ATPase coupling mechanism will be compared with dynein and myosin.
...
PMID:Pathway of the microtubule-kinesin ATPase. 778 62
The diffusion-limited rate for association of the
ADP
complex of dimeric DKH392
kinesin
head domains with a microtubule was estimated to be 2-3 x 10(7) M-1 s-1 based on approximation of a microtubule as a highly elongated prolate ellipsoidal adsorber of 100% efficiency. This theoretical bimolecular rate is approximately 100-fold smaller than the experimental rate, kcat/KMT0.5, for DKH392 that was determined from the stimulation of the steady-state ATPase rate by microtubules. The large difference between these two estimates of the bimolecular rate indicates that it is likely that dimeric DKH392 hydrolyzes multiple ATP molecules during each diffusional encounter with a microtubule.
...
PMID:Implications of diffusion-controlled limit for processivity of dimeric kinesin head domains. 778 88
Direct measurement of the kinetics of
kinesin
dissociation from microtubules, the release of phosphate and
ADP
from
kinesin
, and rebinding of
kinesin
to the microtubule have defined the mechanism for the
kinesin
ATPase cycle. The processivity of ATP hydrolysis is ten molecules per site at low salt concentration but is reduced to one ATP per site at higher salt concentration. Kinesin dissociates from the microtubule after ATP hydrolysis. This step is rate-limiting. The subsequent rebinding of
kinesin
-
ADP
to the microtubule is fast, so
kinesin
spends only a small fraction of its duty cycle in the dissociated state. These results provide an explanation for the motility differences between skeletal myosin and
kinesin
.
...
PMID:Pathway of processive ATP hydrolysis by kinesin. 785 36
The N-terminal 392 amino acids of the Drosophila
kinesin
alpha subunit (designated DKH392) form a dimer in solution that releases only one of its two tightly bound
ADP
molecules on association with a microtubule, whereas a shorter monomeric construct (designated DKH340) releases > or = 95% of its one bound
ADP
on association with a microtubule. This half-site reactivity of dimeric DKH392 is observed over a wide range of ratios of DKH392 to microtubules and steady-state ATPase rates, indicating that it is characteristic of the mechanism of microtubule-stimulated ATP hydrolysis and not the result of a fortuitous balance of rate constants. When [alpha-32P]ATP is included in the medium, incorporation of 32P label into the pool of
ADP
that is bound to the complex of DKH392 and microtubules occurs rapidly enough for the bound
ADP
to be an intermediate on the main pathway of ATP hydrolysis. These and other results are consistent with the half-site reactivity being a consequence of the tethering of dimeric DKH392 to the microtubule through one head domain, which is attached in a rigor-like manner without bound nucleotide, whereas the other head is not attached to the microtubule and still contains a tightly bound
ADP
. An intermediate of this nature and the tight binding of DKH392 to microtubules in the presence of ATP suggest a mechanism for directed motility in which the head domains of dimeric DKH392 alternate in a sequential manner.
...
PMID:Evidence for alternating head catalysis by kinesin during microtubule-stimulated ATP hydrolysis. 804 10
The pre-steady-state kinetics of the microtubule-
kinesin
ATPase were investigated by chemical-quench flow methods using the Drosophila
kinesin
motor domain (K401) expressed in Escherichia coli [Gilbert, S. P., & Johnson, K. A. (1993) Biochemistry 32, 4677-4684]. The results define a minimal mechanism: M.K + ATP in equilibrium with (M).K.ATP in equilibrium with (M).K.
ADP
.Pi in equilibrium with M.K.
ADP
+ Pi in equilibrium with M.K +
ADP
, where M, K, and Pi represent microtubules,
kinesin
, and inorganic phosphate, respectively, with k+1 = 0.8-3 microM-1 s-1, k-1 = 100-300 s-1, k+2 = 70-120 s-1, k+4 = 10-20 s-1, and k+3 >> k-2 and k+3 >> k+4. Conditions were as follows: 25 degrees C, 20 mM HEPES, pH 7.2 with KOH, 5 mM magnesium acetate, 0.1 mM EDTA, 0.1 mM EGTA, 50 mM potassium acetate, 1 mM DTT. The experiments presented do not determine the step in the cycle where
kinesin
dissociates from the microtubule or the step at which
kinesin
reassociates with the microtubule; therefore, the steps that may represent
kinesin
as the free enzyme are indicated by (M). A burst of
ADP
product formation was observed during the first turnover of the enzyme in the acid-quench experiments that define the ATP hydrolysis transient. The observation of the burst demonstrates that product release is rate limiting even in the presence of saturating microtubule concentrations. The pulse-chase experiments define the time course of ATP binding to the microtubule-K401 complex. At low ATP concentrations, ATP binding limits the rate of the burst. However, at high concentrations of ATP, ATP binding is faster than the rate of ATP hydrolysis with k+2 = 70-120 s-1. The amplitude of the burst of the ATP binding transient reached a maximum of 0.7 per site at saturating concentrations of ATP and microtubules. The amplitude of less than 1 is attributed to the fast k(off) for ATP (k-1 = 100-300 s-1) that leads to a partitioning of the M.K.ATP complex between ATP hydrolysis (k+2) and ATP release (k-1). These results indicate that ATP binds weakly to the M.K complex (Kd,ATP app approximately 100 microM).
ADP
release (k+4 = 10-20 s-1) is rate limiting during steady-state turnover, indicating that microtubules activate the
kinesin
ATPase by increasing k(off),
ADP
from 0.01 s-1 in the absence of microtubules to 10-20 s-1 at saturating microtubule concentrations.
...
PMID:Pre-steady-state kinetics of the microtubule-kinesin ATPase. 811 Aug
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