Molecular origin of the weak susceptibility of kinesin velocity to loads and its relation to the collective behavior of kinesins

Motor proteins are active enzymatic molecules that support important cellular processes by transforming chemical energy into mechanical work. Although the structures and chemomechanical cycles of motor proteins have been extensively investigated, the sensitivity of a motor’s velocity in response to...

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Published inProceedings of the National Academy of Sciences - PNAS Vol. 114; no. 41; pp. E8611 - E8617
Main Authors Wang, Qian, Diehl, Michael R., Jana, Biman, Cheung, Margaret S., Kolomeisky, Anatoly B., Onuchic, José N.
Format Journal Article
LanguageEnglish
Published United States National Academy of Sciences 10.10.2017
SeriesPNAS Plus
Subjects
Adenosine Triphosphate - metabolism
ATP
Binding Sites
Biological Sciences
Cellular structure
Chemical energy
Enzymes
Humans
Kinesin
Kinesin - chemistry
Kinesin - metabolism
Kinetics
Microtubules - metabolism
Molecular biology
Molecular Dynamics Simulation
Molecular motors
Molecular structure
Molecules
Neck
PNAS Plus
Protein Binding
Proteins
Simulation
Velocity
molecular mechanism
susceptibility
kinesin
collective behavior
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Summary:Motor proteins are active enzymatic molecules that support important cellular processes by transforming chemical energy into mechanical work. Although the structures and chemomechanical cycles of motor proteins have been extensively investigated, the sensitivity of a motor’s velocity in response to a force is not well-understood. For kinesin, velocity is weakly influenced by a small to midrange external force (weak susceptibility) but is steeply reduced by a large force. Here, we utilize a structure-based molecular dynamic simulation to study the molecular origin of the weak susceptibility for a single kinesin. We show that the key step in controlling the velocity of a single kinesin under an external force is the ATP release from the microtubule-bound head. Only under large loading forces can the motor head release ATP at a fast rate, which significantly reduces the velocity of kinesin. It underpins the weak susceptibility that the velocity will not change at small to midrange forces. The molecular origin of this velocity reduction is that the neck linker of a kinesin only detaches from the motor head when pulled by a large force. This prompts the ATP binding site to adopt an open state, favoring ATP release and reducing the velocity. Furthermore, we show that two load-bearing kinesins are incapable of equally sharing the load unless they are very close to each other. As a consequence of the weak susceptibility, the trailing kinesin faces the challenge of catching up to the leading one, which accounts for experimentally observed weak cooperativity of kinesins motors.
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Contributed by José N. Onuchic, September 2, 2017 (sent for review June 7, 2017; reviewed by Ioan Andricioaei and Garegin A. Papoian)
Author contributions: Q.W., M.S.C., A.B.K., and J.N.O. designed research; Q.W. performed research; Q.W., M.R.D., B.J., M.S.C., A.B.K., and J.N.O. analyzed data; and Q.W., M.R.D., B.J., M.S.C., A.B.K., and J.N.O. wrote the paper.
Reviewers: I.A., University of California, Irvine; and G.A.P., University of Maryland.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1710328114