Abstract
Transient kinetic analysis of microtubule-stimulated ATP hydrolysis by the monomeric kinesin motor domain DKH357 was performed to investigate the kinetic pattern of a monomer. Both ATP and ADP produced dissociation of the complex, microtubule (MT).E, of microtubules with DKH357 at a maximum rate of approximately 45 s-1 as determined by decrease in turbidity. The maximum dissociation rate was independent of the KCl concentration between 25 and 200 mM. At subsaturating levels of nucleotide, ATP was more effective than ADP in dissociating DKH357 from MT.E (1.6 and 0.4 microM-1 s-1 for ATP and ADP, respectively, at 50 mM KCl). Addition of ATP to MT.E results in a burst of product formation with a maximum initial rate of approximately 100 s-1 at saturating levels of ATP. This maximum hydrolysis rate of 100 s-1 is similar to the maximum steady state ATPase rate at saturating microtubules of approximately 70 s-1, and thus hydrolysis is at least partially rate-limiting. When the MT lattice was highly occupied with bound DKH357, the amplitude of the burst was approximately 2 per DKH357 active site (superstoichiometric). The rate constant for the burst transient was approximately 45 s-1, which is the same as the rate for dissociation of DKH357 from the microtubule and this suggests that dissociation and termination of the burst phase are coupled. The size of the burst increased with decreasing initial occupancy of the MT lattice with bound DKH357 and approached the value of approximately 4 ATP molecules predicted by previous steady state measurements (Jiang, W., Stock, M., Li, X., and Hackney, D. D., submitted for publication).
Highlights
The size of the burst increased with decreasing initial occupancy of the MT lattice with bound DKH357 and approached the value of ϳ4 ATP molecules predicted by previous steady state measurements
We report transient kinetic results that directly demonstrate that hydrolysis of ATP by the MT1⁄7DKH357 complex is faster than dissociation of DKH357 from the MT, and that dissociation does not even occur during most ATPase cycles
With monomeric DKH346, DKH357, and DKH365, MTs stimulate steady state ATP hydrolysis with a bimolecular rate constant that is ϳ4-fold greater than that for stimulation of the rate of ADP release from E1⁄7ADP.2
Summary
Analysis of the bimolecular rates for stimulation by MTs of steady state ATPase and ADP release, indicates that monomers DKH346, DKH357, and DKH365 hydrolyze ϳ4 ATP molecules during each cycle of net binding and release of kinesin from a MT.2 This is equivalent to saying that the head domain has only a 1 in 4 probability of dissociating from the MT during hydrolysis of each ATP molecule. We report transient kinetic results that directly demonstrate that hydrolysis of ATP by the MT1⁄7DKH357 complex is faster than dissociation of DKH357 from the MT, and that dissociation does not even occur during most ATPase cycles This results in a burst of product formation on addition of ATP to the rigor complex of kinesin with MTs that is larger than the concentration of kinesin active sites (superstoichiometric). A preliminary report of these results has been made [17]
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