APS March Meeting 2016
Volume 61, Number 2
Monday–Friday, March 14–18, 2016;
Baltimore, Maryland
Session Y36: Soft Mechanics in Biological Systems
11:15 AM–1:51 PM,
Friday, March 18, 2016
Room: 339
Sponsoring
Units:
GSOFT DBIO
Chair: Moumita Das, Rochester Institute of Technology
Abstract ID: BAPS.2016.MAR.Y36.10
Abstract: Y36.00010 : Mechanics governs single-cell signaling and multi-cell robustness in biofilm infections.*
1:03 PM–1:39 PM
Preview Abstract
Abstract
Author:
Vernita Gordon
(The University of Texas at Austin)
In biofilms, bacteria and other microbes are embedded in extracellular
polymers (EPS). Multiple types of EPS can be produced by a single bacterial
strain - the reasons for this redundancy are not well-understood. Our work
suggests that different polymers may confer distinct mechanical benefits.
Our model organism is \textit{Pseudomonas aeruginosa}, an opportunistic human pathogen that forms chronic
biofilm infections associated with increased antibiotic resistance and
evasion of the immune defense.
Biofilms initiate when bacteria attach to a surface, sense the surface, and
change their gene expression. Changes in gene expression are regulated by a
chemical signal, cyclic-di-GMP. We find that one EPS material, called
``PEL,'' enhances surface sensing by increasing mechanical coupling of
single bacteria to the surface. Measurements of bacterial motility suggest
that PEL may increase frictional interactions between the surface and the
bacteria. Consistent with this, we show that bacteria increase cyclic-di-GMP
signaling in response to mechanical shear stress. Mechanosensing has long
been known to be important to the function of cells in higher eukaryotes,
but this is one of only a handful of studies showing that bacteria can sense
and respond to mechanical forces.
For the mature biofilm, the embedding polymer matrix can protect bacteria
both chemically and mechanically. \textit{P. aeruginosa} infections in the cystic fibrosis (CF)
lung often last for decades, ample time for the infecting strain(s) to
evolve. Production of another EPS material, alginate, is well-known to tend
to increase over time in CF infections. Alginate chemically protects
biofilms, but also makes them softer and weaker. Recently, it is being
increasingly recognized that bacteria in chronic CF infections also evolve
to increase PSL production. We use oscillatory bulk rheology to determine
the unique contributions of EPS materials to biofilm mechanics. Unlike
alginate, increased PSL stiffens biofilms. Increasing both PSL and alginate
expression increases the energy cost to break the biofilm. We compare the
elastic moduli of biofilms to estimated stresses exerted by phagocytotic
immune cells, and infer that increased PSL could confer a mechanical fitness
benefit.
*This work was supported by start-up funds from The University of Texas at Austin and a gift from ExxonMobile to VDG, and by grants from the Human Frontiers Science Program (HFSP RGY0081/2012-GORDON) and the National Science Foundation (NSF 1337670).
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2016.MAR.Y36.10