2006 APS March Meeting
Monday–Friday, March 13–17, 2006;
Baltimore, MD
Session R1: Cytoskeletal Dynamics and Mechanics
2:30 PM–4:54 PM,
Wednesday, March 15, 2006
Baltimore Convention Center
Room: Ballroom IV
Sponsoring
Units:
DCMP DBP
Chair: Gerard Wong, University of Illinois
Abstract ID: BAPS.2006.MAR.R1.3
Abstract: R1.00003 : Fluorescent Speckle Microrheology
3:42 PM–4:18 PM
Preview Abstract
Abstract
Author:
Margaret Gardel
(The Scripps Research Institute)
The actin cortex is the dense shell of actin filaments between the cell
membrane and the cytoplasm maintaining and regulating cell shape. It is one
of the principal determinants of cell mechanical properties, whose
spatiotemporal modulations play a central role in processes that involve
architectural dynamics of a cell, such as cell migration, division and
morphogenesis. However, the exact mechanism of cortical actin elasticity
regulation \textit{in vivo} is still unresolved.
We present a high-resolution and molecularly specific assay of \textit{in vivo} cortical
actin elasticity, fluorescent speckle microrheology. Speckles originate when
fluorescent actin is randomly incorporated into the network along with
abundant endogeneous non-fluorescent actin, leading to high spatial
variations of the local fluorophore density; high-density areas appear as
diffraction-limited spots (speckles) upon high-resolution imaging. Speckles
act as fiduciary marks of the network and can be used to directly image
strain fluctuations, in contrast to classical microrheology techniques using
imbedded probes. When tracking positional fluctuations of actin speckles in
cells without convective network flow with subpixel precision, we find that
the displacements of neighboring speckles are spatially correlated. Their
correlation function decays as 1/r with interspeckle distance r, which is
consistent with theoretical predictions for strain field decay in a 3D
continuous viscoelastic medium. On the basis of these results, we use the
amplitude of the correlation function to measure viscoelastic properties of
the actin network. Due to high intracellular speckle densities and their
homogeneous distribution throughout the cell, this approach yields much
higher spatial resolution than other microrheology techniques, which is
validated using \textit{in vitro} actin networks. Thus, this assay allows us to map
intracellular actin cortex elasticity with micron resolution, and to relate
intracellular heterogeneities of elasticity to heterogeneities in other
dynamic cellular parameters.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2006.MAR.R1.3