Moreland, J.
(2011),
Magnetic manipulation of actin orientation, polymerization, and gliding on myosin using superparamagnetic iron oxide particles, Nanotechnology
(Accessed January 15, 2025)
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Magnetic manipulation of actin orientation, polymerization, and gliding on myosin using superparamagnetic iron oxide particles
Published
Author(s)
Abstract
The actin cytoskeleton controls cell shape, motility, as well as intracellular molecular trafficking. The ability to remotely manipulate actin is therefore highly desirable as a tool to probe and manipulate biological processes at the molecular level. We demonstrate actin manipulation by labeling actin filaments with superparamagnetic iron oxide particles (IOPs) and applying a uniform magnetic field to affect actin orientation, polymerization and gliding on myosin. We show for the first time magnetic manipulation of magnetizable actin filaments at the molecular level while gliding on a bed of myosin molecules and during polymerization. A model for the magnetic alignment and guiding mechanism is proposed based on the torque from the induced molecular anisotropy due to interactions between neighboring IOPs distributed along magnetically labeled actin molecules. Online supplementary data available from stacks.iop.org/Nano/22/065101/mmediaCitation
Nanotechnology
Volume
22
Issue
065101
Pub Type
Journals
Keywords
actin, nanoparticles, magnetic torque, superparamagnetic iron-oxide particles (SPIO)
Citation
Issues
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Created January 7, 2011, Updated February 19, 2017