(taken from the application): One major goal will be to investigate the dynamic flexibility of the motor proteins in solution. We will determine whether skeletal muscle myosin level arm motion is coupled to ATP hydrolysis, and if an energized level arm conformation is sufficient for force generation. In collaboration with Don Eden and Roger Cooke, we will correlate the production of force by muscle fibers with the substrate hydrolysis-driven conversion of the isolated motor domain a more compact structure for the same substrate. If the hypothesis is correct, only substrates that support contract should rotate the lever arm to convert S1 to a more compact structure, and substrates that form compact intermediates should support contraction. Kinesin and NCD motor domain segmental flexibility in solution will also be characterized. The dynamic flexibility in solution of their motor domain attachments to the stalk region, and the effects of nucleotides on that flexibility will be determined using monomeric and dimeric constructs of NCD and kinesin. A second major goal will be characterize properties of the complexes of the motor proteins with their polymers. We are currently studying the ternary complex between a tublin dimer and a motor monomer (NCD) with the goal of crystallizing it. The equilibrium association constants, Ka, for these complexes in the presence of different nucleotides, and the kinetic constants, complexes in the presence of different nucleotides, and the kinetic constants, Km and Vmax, for tubulin-activated MgATPase activity, will be measured. The crystallization trials will be done in collaboration with Elena Sablin and Robert Fletterick. Electrostatic and energetic interactions for both systems will be characterized. For NCD binding to tubulin, the ionic strength dependence will be used to quantify nucleotide- induced charge changes t the binding interface. For NCD binding to tubulin, the ionic strength dependence will be used top quantify nucleotide-induced charge changes at the binding interface. For myosin binding to actin, using loop 2 mutants in collaboration with Jim Spudich and Joel Cohen, nucleotide-induced electric charge changes at the actin binding site will be measured and compared to net electric charge changes of the motor domain.

Project Start
2002-07-01
Project End
2003-06-30
Budget Start
Budget End
Support Year
9
Fiscal Year
2002
Total Cost
Indirect Cost
Name
University of California San Francisco
Department
Type
DUNS #
073133571
City
San Francisco
State
CA
Country
United States
Zip Code
94143
Lal, Sean; Li, Amy; Allen, David et al. (2015) Best Practice BioBanking of Human Heart Tissue. Biophys Rev 7:399-406
Eldred, Catherine C; Naber, Nariman; Pate, Edward et al. (2013) Conformational changes at the nucleotide site in the presence of bound ADP do not set the velocity of fast Drosophila myosins. J Muscle Res Cell Motil 34:35-42
Harrington, Timothy D; Naber, Nariman; Larson, Adam G et al. (2011) Analysis of the interaction of the Eg5 Loop5 with the nucleotide site. J Theor Biol 289:107-15
Purcell, Thomas J; Naber, Nariman; Franks-Skiba, Kathy et al. (2011) Nucleotide pocket thermodynamics measured by EPR reveal how energy partitioning relates myosin speed to efficiency. J Mol Biol 407:79-91
Waitzman, Joshua S; Larson, Adam G; Cochran, Jared C et al. (2011) The loop 5 element structurally and kinetically coordinates dimers of the human kinesin-5, Eg5. Biophys J 101:2760-9
Purcell, Thomas J; Naber, Nariman; Sutton, Shirley et al. (2011) EPR spectra and molecular dynamics agree that the nucleotide pocket of myosin V is closed and that it opens on binding actin. J Mol Biol 411:16-26
Naber, Nariman; Larson, Adam; Rice, Sarah et al. (2011) Multiple conformations of the nucleotide site of Kinesin family motors in the triphosphate state. J Mol Biol 408:628-42
Stewart, Melanie A; Franks-Skiba, Kathleen; Chen, Susan et al. (2010) Myosin ATP turnover rate is a mechanism involved in thermogenesis in resting skeletal muscle fibers. Proc Natl Acad Sci U S A 107:430-5
Hjelm, Rex P; Stone, Deborah Bennett; Fletterick, Robert J et al. (2010) Decoration of microtubules in solution by the kinesin-14, Ncd. Acta Crystallogr D Biol Crystallogr 66:1218-23
Carter, Andrew P; Vale, Ronald D (2010) Communication between the AAA+ ring and microtubule-binding domain of dynein. Biochem Cell Biol 88:15-21

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