Force-dependent stepping kinetics of myosin-V

Anabel E.M. Clemen, Mojca Vilfan, Johann Jaud, Junshan Zhang, Michael Bärmann, Matthias Rief

Research output: Contribution to journalArticlepeer-review

123 Scopus citations

Abstract

Myosin-V is a processive two-headed actin-based motor protein involved in many intracellular transport processes. A key question for understanding myosin-V function and the communication between its two heads is its behavior under load. Since in vivo myosin-V colocalizes with other much stronger motors like kinesins, its behavior under superstall forces is especially relevant. We used optical tweezers with a long-range force feedback to study myosin-V motion under controlled external forward and backward loads over its full run length. We find the mean step size remains constant at ∼36 nm over a wide range of forces from 5 pN forward to 1.5 pN backward load. We also find two force-dependent transitions in the chemomechanical cycle. The slower ADP-release is rate limiting at low loads and depends only weakly on force. The faster rate depends more strongly on force. The stronger force dependence suggests this rate represents the diffusive search of the leading head for its binding site. In contrast to kinesin motors, myosin-V's run length is essentially independent of force between 5 pN of forward to 1.5 pN of backward load. At superstall forces of 5 pN, we observe continuous backward stepping of myosin-V, indicating that a force-driven reversal of the power stroke is possible.

Original languageEnglish
Pages (from-to)4402-4410
Number of pages9
JournalBiophysical Journal
Volume88
Issue number6
DOIs
StatePublished - Jun 2005

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