Cryo-EM Structures Reveal Specialization at the Myosin VI-actin Interface and a Mechanism of Force Sensitivity

Overview

Journal Elife

Specialty Biology

Date 2017 Dec 5

PMID 29199952

Citations 30

Authors

Pinar S Gurel

Laura Y Kim

Paul V Ruijgrok

Tosan Omabegho

Zev Bryant

Gregory M Alushin

Affiliations

Soon will be listed here.

Abstract

Despite extensive scrutiny of the myosin superfamily, the lack of high-resolution structures of actin-bound states has prevented a complete description of its mechanochemical cycle and limited insight into how sequence and structural diversification of the motor domain gives rise to specialized functional properties. Here we present cryo-EM structures of the unique minus-end directed myosin VI motor domain in rigor (4.6 Å) and Mg-ADP (5.5 Å) states bound to F-actin. Comparison to the myosin IIC-F-actin rigor complex reveals an almost complete lack of conservation of residues at the actin-myosin interface despite preservation of the primary sequence regions composing it, suggesting an evolutionary path for motor specialization. Additionally, analysis of the transition from ADP to rigor provides a structural rationale for force sensitivity in this step of the mechanochemical cycle. Finally, we observe reciprocal rearrangements in actin and myosin accompanying the transition between these states, supporting a role for actin structural plasticity during force generation by myosin VI.

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