Nature Communications (Aug 2024)

Motor domain phosphorylation increases nucleotide exchange and turns MYO6 into a faster and stronger motor

  • Janeska J. de Jonge,
  • Andreas Graw,
  • Vasileios Kargas,
  • Christopher Batters,
  • Antonino F. Montanarella,
  • Tom O’Loughlin,
  • Chloe Johnson,
  • Susan D. Arden,
  • Alan J. Warren,
  • Michael A. Geeves,
  • John Kendrick-Jones,
  • Nathan R. Zaccai,
  • Markus Kröss,
  • Claudia Veigel,
  • Folma Buss

DOI
https://doi.org/10.1038/s41467-024-49898-3
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 18

Abstract

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Abstract Myosin motors perform many fundamental functions in eukaryotic cells by providing force generation, transport or tethering capacity. Motor activity control within the cell involves on/off switches, however, few examples are known of how myosins regulate speed or processivity and fine-tune their activity to a specific cellular task. Here, we describe a phosphorylation event for myosins of class VI (MYO6) in the motor domain, which accelerates its ATPase activity leading to a 4-fold increase in motor speed determined by actin-gliding assays, single molecule mechanics and stopped flow kinetics. We demonstrate that the serine/threonine kinase DYRK2 phosphorylates MYO6 at S267 in vitro. Single-molecule optical-tweezers studies at low load reveal that S267-phosphorylation results in faster nucleotide-exchange kinetics without change in the working stroke of the motor. The selective increase in stiffness of the acto-MYO6 complex when proceeding load-dependently into the nucleotide-free rigor state demonstrates that S267-phosphorylation turns MYO6 into a stronger motor. Finally, molecular dynamic simulations of the nucleotide-free motor reveal an alternative interaction network within insert-1 upon phosphorylation, suggesting a molecular mechanism, which regulates insert-1 positioning, turning the S267-phosphorylated MYO6 into a faster motor.