Microrheology of active actin-microtubule networks

ORAL

Abstract



The cytoskeleton, composed of actin, microtubules, and associated motor and binding proteins, self-organizes into different structures and morphologies to drive diverse mechanical processes in eukaryotic cells. While in vitro actomyosin networks are well-characterized, few studies have examined how the structure and activity of these networks are altered by the presence of microtubules. We previously synthesized steady-state actin-microtubule networks, finding that mechanical properties, such as network elasticity, depend on molecular interactions between actin and microtubules, such as the degree of crosslinking and bundling. Here, we create active actin-microtubule networks by adding the motor protein myosin. Using confocal microscopy and microrheology, we characterize how the network structure evolves during motor activity, and connect how microscopic changes in network structure affect the mechanical properties of the network. Our results shed important new light on how actin-microtubule interactions influence the structure, mechanics and activity that motor-driven cytoskeleton networks exhibit.

*W.M. Keck Foundation Research Grant

Presenters

  • Gloria Lee

    • Univ of San Diego
    • University of San Diego

Authors

  • Gloria Lee

    • Univ of San Diego
    • University of San Diego

  • Shea Ricketts

    • Univ of San Diego

  • Michael Rust

    • University of Chicago
    • Department of Molecular Genetics and Cell Biology, University of Chicago
    • Univ of Chicago
    • Molecular Genetics and Cell Biology, University of Chicago

  • Moumita Das

    • Rochester Institute of Technology
    • School of Physics and Astronomy, Rochester Institute of Technology

  • Jennifer L Ross

    • Syracuse University
    • Physics, Syracuse University
    • Department of Physics, Syracuse University