Kinesin motility is driven by subdomain dynamics. Academic Article

abstract

• The microtubule (MT)-associated motor protein kinesin utilizes its conserved ATPase head to achieve diverse motility characteristics. Despite considerable knowledge about how its ATPase activity and MT binding are coupled to the motility cycle, the atomic mechanism of the core events remain to be found. To obtain insights into the mechanism, we performed 38.5 microseconds of all-atom molecular dynamics simulations of kinesin-MT complexes in different nucleotide states. Local subdomain dynamics were found to be essential for nucleotide processing. Catalytic water molecules are dynamically organized by the switch domains of the nucleotide binding pocket while ATP is torsionally strained. Hydrolysis products are 'pulled' by switch-I, and a new ATP is 'captured' by a concerted motion of the 0/L5/switch-I trio. The dynamic and wet kinesin-MT interface is tuned for rapid interactions while maintaining specificity. The proposed mechanism provides the flexibility necessary for walking in the crowded cellular environment.

authors

• Hwang, Wonmuk

published proceedings

• Elife

altmetric score

• 1.75

author list (cited authors)

• Hwang, W., Lang, M. J., & Karplus, M.

citation count

• 34

publication date

• November 2017

publisher

• eLife  Publisher

published in

• eLife  Journal

keywords

• Adenosine Triphosphatases
• Adenosine Triphosphate
• Atp Hydrolysis
• Biophysics
• Computational Biology
• Humans
• Kinesin-microtubule System
• Kinesins
• Mechanochemistry
• Microtubules
• Models, Molecular
• Molecular Dynamics Simulation
• Motility Cycle
• Motor Protein
• None
• Protein Binding
• Structural Biology
• Systems Biology

PubMed Central ID

• 29111975

Digital Object Identifier (DOI)

• 10.7554/eLife.28948

start page

• e28948

volume

• 6

URL

• http://dx.doi.org/10.7554/elife.28948