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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)
Cytoplasmic dynein and ncd, a kinesin-related protein from Drosophila, are motor proteins that move toward the minus ends of microtubules, while
kinesin
moves to the microtubule plus end. In previous work, we examined the nucleotide dependence of motility and enzymatic activity by
kinesin
[Shimizu, T., Furusawa, K., Ohashi, S., Toyoshima, Y. Y., Okuno, M., Malik, F., & Vale, R. D., (1991) J. Cell Biol. 112, 1189-1197]. In this study, we examined these activities of the cytoplasmic dynein from bovine brain and ncd in order to explore what enzymatic features might be shared by these two minus-end-directed motors. Both ncd and cytoplasmic dynein demonstrated an activation of ATPase activity upon the addition of microtubules (30-fold and 6-fold, respectively). A significant difference between ncd and cytoplasmic dynein was their relative sensitivity to vanadate and to aluminum fluoride. In contrast to cytoplasmic dynein, ncd polypeptide was not cleaved by UV-vanadate treatment, and its ATPase and motility were unaffected by vanadate (up to 0.1 mM). When the nucleotide requirement for movement as examined using a battery of 20 nucleotides and nucleotide analogues, cytoplasmic dynein was found to exhibit a specificity very similar to that of axonemal dyneins from Tetrahymena. Surprisingly, however, the nucleotide specificities of in vitro motility produced by ncd or its construct, GST/
MC1
(a fusion protein of glutathione S-transferase and 210-700 of the predicted ncd amino acid sequence), were quite distinct from that of
kinesin
. Thus, the nucleotide specificity profiles of members of the
kinesin
motor superfamily do not appear to be identical.
...
PMID:Comparison of the motile and enzymatic properties of two microtubule minus-end-directed motors, ncd and cytoplasmic dynein. 784 16
The kinetic mechanism of the nonclaret disjunctional protein (Ncd) motor was investigated using the dimer termed
MC1
(residues 209-700), which has been shown to exhibit negative-end directed motility (Chandra et al., 1993). The kinetic properties are similar to those of the monomeric Ncd motor domain (Pechatnikova and Taylor, 1997). The maximum steady-state ATPase activity of 1.5 s(-1) is half as large as for the monomeric motor. Dissociation constants in the presence of nucleotides showed the same trend but with approximately a two-fold decrease in the values: K(d) values are 1.0 microM for ADP-AlF(4), 1.1 microM for ATPgammaS, 1.5 microM for ATP, 3 microM for ADP, and 10 microM for ADP-vanadate (in 25 mM NaCl, 22 degrees C). The apparent second-order rate constants for the binding of ATP and ADP to the microtubule-motor complex (MtMC1) are 2 microM(-1) s(-1). Based on measurements at high microtubule concentrations the kinetic steps were fitted to the scheme,[see text] where N refers to one head of the dimer and T, D, and P stand for ATP, ADP, and inorganic phosphate. k(1) and k(-4) are the first-order rate constants of the transition induced by the binding of mant ATP and mant ADP respectively. ADP release is the main rate-limiting step in the MtMC1 mechanism. The binding of the
MC1
-mant ADP complex to microtubules released less than half of the mant ADP (alternating site reactivity). The second mant ADP is only released by the binding of nucleotides that dissociate the MtMC1 complex (ATP and ADP but not AMPPNP). The apparent rate constant for dissociation of the second mant ADP is four times smaller than the first and much smaller than the rate of dissociation of MtMC1 by ATP or ADP. These results are explained by a model in which
MC1
.ADP is first dissociated from the microtubule by ATP, followed by rebinding to the microtubule by the ADP-containing head. Ncd may follow a different reaction pathway than does
kinesin
, but the differences in rate constants do not explain the opposite direction of motion. The kinetic evidence and the high ratio of motile velocity to ATPase support a nonprocessive, low duty cycle mechanism for the Ncd motor.
...
PMID:Kinetics processivity and the direction of motion of Ncd. 1042 45
N-Ethylmaleimide (NEM), which reacts readily with exposed sulfhydryl groups, has been shown to inhibit the activity of the microtubule (MT) motors
kinesin
, Ncd, and dynein. Currently, the mechanism of inhibition is not known for any of these proteins. To investigate the mechanism by which NEM inhibits Ncd, the recombinant Ncd motor-stalk protein
MC1
(modified claret 1) was treated with varying concentrations of NEM (0-10 mM) and cosedimentation and ATPase assays were used to assess the effects of modification on
MC1
interactions with MTs. In the cosedimentation assay, treatment with </=0.1 mM NEM enhanced
MC1
binding to MTs in the presence of MgATP but had no effect on
MC1
binding to MTs in the presence of MgAMP-PNP. In comparison, treatment with >/=0.5 mM NEM induced aggregation of
MC1
and resulted in sedimentation of the motor in the absence of MTs. NEM modification had no effect on the basal ATPase rate but produced a decrease in the MT-stimulated ATPase rate. Labeling of
MC1
with [3H]NEM indicated that enhanced MT binding was associated with an average labeling of 1 Cys residue per
MC1
polypeptide, while aggregation was associated with an average labeling of 2 Cys residues per
MC1
polypeptide. Protein digestion, structural analysis, and mass spectrometry indicate that modification of Cys313 or Cys324 in the stalk domain is correlated with enhanced binding of
MC1
to MTs. These results suggest that NEM enhances Ncd binding to MTs by disruption of neck and/or stalk function and demonstrate the importance of this region in motor function.
...
PMID:N-ethylmaleimide inhibits Ncd motor function by modification of a cysteine in the stalk domain. 1045 70
Ncd is a kinesin-related motor protein which drives movement to the minus-end of microtubules. The kinetics of Ncd were investigated using the dimeric construct
MC1
(Leu(209)-Lys(700)) expressed in Escherichia coli strain BL21(DE) as a nonfusion protein [Chandra, R., Salmon, E. D., Erickson, H. P., Lockhart, A., and Endow, S. A. (1993) J. Biol. Chem. 268, 9005-9013]. Acid chemical quench flow methods were used to measure directly the rate of ATP hydrolysis, and stopped-flow kinetic methods were used to determine the kinetics of mantATP binding, mantADP release, dissociation of
MC1
from the microtubule, and binding of
MC1
to the microtubule. The results define a minimal kinetic mechanism, M.N + ATP M.N.ATP M.N.ADP.P N. ADP.P N.ADP + P M.N.ADP M.N + ADP, where N, M, and P represent Ncd, microtubules, and inorganic phosphate respectively, with k(+1) = 2.3 microM(-1) s(-1), k(+2) =23 s(-1), k(+3) =13 s(-1), k(+5)= 0.7 microM(-)(1) s(-)(1), and k(+6) = 3.7 s(-)(1). Phosphate release (k(+4)) was not measured directly although it is assumed to be fast relative to ADP release because Ncd is purified with ADP tightly bound at the active site. ATP hydrolysis occurs at 23 s(-)(1) prior to Ncd dissociation at 13 s(-)(1). The pathway for ATP-promoted detachment (steps 1-3) of Ncd from the microtubule is comparable to
kinesin
's. However, there are two major differences between the mechanisms of Ncd and
kinesin
. In contrast to
kinesin
, mantADP release for Ncd at 3.7 s(-)(1) is the slowest step in the pathway and is believed to limit steady-state turnover. Additionally, the burst amplitude observed in the pre-steady-state acid quench experiments is stoichiometric, indicating that Ncd, in contrast to
kinesin
, is not processive for ATP hydrolysis.
...
PMID:Kinetic studies of dimeric Ncd: evidence that Ncd is not processive. 1067 28
Ncd is a minus-end-directed microtubule motor and a member of the
kinesin
superfamily. The Ncd dimer contains two motor domains, and cooperative interactions between the heads influence the interactions of each respective motor domain with the microtubule. The approach we have taken to understand the cooperativity between the two motor domains is to analyze the ATPase cycle of dimeric
MC1
and monomeric MC6. The steps in the ATPase cycle where cooperativity occurs can be identified by comparing the two mechanisms. The rate-limiting step in the MC6 mechanism is ADP release at 3.4 s(-)(1). The observed rate constant for ATP-induced dissociation from the microtubule is 14 s(-)(1). However, the relative amplitude associated with MC6 dissociation is extremely small in comparison to the amplitude associated with dimeric
MC1
dissociation kinetics. The amplitude data indicate that monomeric MC6 does not detach from the microtubule during the initial turnovers of ATP, and ATP hydrolysis is uncoupled from movement. The results show that cooperative interactions between the motor domains of the dimer are required for ATP-dependent dissociation; therefore, one function of the partner motor domain may be to weaken the interaction of the adjacent head with the microtubule.
...
PMID:Moving a microtubule may require two heads: a kinetic investigation of monomeric Ncd. 1068 15
