80th Annual Meeting of the APS Southeastern Section
Volume 58, Number 17
Wednesday–Saturday, November 20–23, 2013;
Bowling Green, Kentucky
Session GB: Cellular Mechanics and Biomechanics
1:30 PM–4:55 PM,
Friday, November 22, 2013
Room: 1
Chair: Martin Guthold, Wake Forest University
Abstract ID: BAPS.2013.SES.GB.5
Abstract: GB.00005 : Mechanisms of Cell Adhesion and Migration on Simple and Complex Surfaces
3:10 PM–3:35 PM
Preview Abstract
Abstract
Author:
Donald T. Haynie
(University of South Florida)
Coordinated motion is a hallmark of animal behavior at diverse length
scales, ranging over about 9 orders of magnitude for individuals and about 3
orders of magnitude more for populations. My laboratory is studying selected
biophysical and biochemical aspects of cell adhesion and migration with a
view towards novel materials applications in biotechnology and medicine. The
cells of this talk are normal human dermal fibroblasts, skin cells. The
materials are non-woven electrospun fibers made of synthetic polypeptides.
We have characterized physical properties of these materials. We have
analyzed cell interactions with fibers by microscopy. Specific protein
constituents of focal adhesions (FAs) have been stained with fluorescent
antibodies, and cell migration in real time has been monitored by
phase-contrast microscopy and confocal laser-scanning microscopy. Analysis
of samples stained for specific focal adhesion proteins showed that the
surface density of FAs on fibers, 6 x 10$^{-3}\mu
$m$^{2}$, was about 2-fold higher than on glass, essentially a
planar substrate. Further analysis showed that the average angle between the
major axis of focal adhesions and the fiber trajectory was 22 deg., roughly
half of the expected value for random orientation. The alignment data have
been interpreted in terms of beam statistical mechanics, yielding a flexural
rigidity of 8.3 x 10$^{-26}$ N-m$^{2}$. This stiffness is
about 10$^{3}$-fold smaller than for microtubules and 25{\%}
greater than for actin filaments. Modeling based on this result is
consistent with the experimental result that FA alignment increases as fiber
diameter decreases. We have also utilized near-UV circular dichroism
spectroscopy and intrinsic fluorescence emission spectroscopy to obtain
Langmuir isotherms for cytoplasmic tails of integrin $\beta $ subunits
associating with intracellular focal adhesion constituents in vitro.
Dissociation constants obtained by fitting a single-site model to the
experimental data range from 8.3 $\mu $M to 50 nM at ambient temperature.
Taken together, the results suggest that the coupling between FAs and stress
fibers is tight and highly specific, and there is a quantifiable thermal
limit to the energy cost a cell will pay to form an adhesion site. The
results further suggest a limit to the benefits that can be derived from
cellular interaction with disorganized nanostructured materials.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2013.SES.GB.5