How the Interplay between Mechanical and Nonmechanical Interactions Affects Multiple Kinesin Dynamics

Intracellular transport is supported by enzymes called motor proteins that are often coupled to the same cargo and function collectively. Recent experiments and theoretical advances have been able to explain certain behaviors of multiple motor systems by elucidating how unequal load sharing between...

Full description

Saved in:
Bibliographic Details
Published in:The journal of physical chemistry. B 2012-08, Vol.116 (30), p.8846-8855
Main Authors: Uppulury, Karthik, Efremov, Artem K, Driver, Jonathan W, Jamison, D. Kenneth, Diehl, Michael R, Kolomeisky, Anatoly B
Format: Article
Language:English
Subjects:
Cargo
Dynamical systems
Dynamics
Enzymes
Joining
kinesin
Kinesins - chemistry
Kinesins - metabolism
Loads (forces)
Mathematical models
microtubules
Models, Molecular
molecular motor proteins
Motors
physical chemistry
Protein Binding
stochastic processes
Thermodynamics
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Intracellular transport is supported by enzymes called motor proteins that are often coupled to the same cargo and function collectively. Recent experiments and theoretical advances have been able to explain certain behaviors of multiple motor systems by elucidating how unequal load sharing between coupled motors changes how they bind, step, and detach. However, nonmechanical interactions are typically overlooked despite several studies suggesting that microtubule-bound kinesins interact locally via short-range nonmechanical potentials. This work develops a new stochastic model to explore how these types of interactions influence multiple kinesin functions in addition to mechanical coupling. Nonmechanical interactions are assumed to affect kinesin mechanochemistry only when the motors are separated by less than three microtubule lattice sites, and it is shown that relatively weak interaction energies (∼2 k B T) can have an appreciable influence over collective motor velocities and detachment rates. In agreement with optical trapping experiments on structurally defined kinesin complexes, the model predicts that these effects primarily occur when cargos are transported against loads exceeding single-kinesin stalling forces. Overall, these results highlight the interdependent nature of factors influencing collective motor functions, namely, that the way the bound configuration of a multiple motor system evolves under load determines how local nonmechanical interactions influence motor cooperation.
ISSN:1520-6106
1520-5207
1520-5207
DOI:10.1021/jp304018b