Verticalization of bacterial biofilms

Publication Year
2018

Type

Journal Article
Abstract
Biofilms are communities of bacteria adhered to surfaces. Recently, biofilms of rod-shaped bacteria were observed at single-cell resolution and shown to develop from a disordered, two-dimensional layer of founder cells into a three-dimensional structure with a vertically-aligned core. Here, we elucidate the physical mechanism underpinning this transition using a combination of agent-based and continuum modeling. We find that verticalization proceeds through a series of localized mechanical instabilities on the cellular scale. For short cells, these instabilities are primarily triggered by cell division, whereas long cells are more likely to be peeled off the surface by nearby vertical cells, creating an "inverse domino effect". The interplay between cell growth and cell verticalization gives rise to an exotic mechanical state in which the effective surface pressure becomes constant throughout the growing core of the biofilm surface layer. This dynamical isobaricity determines the expansion speed of a biofilm cluster and thereby governs how cells access the third dimension. In particular, theory predicts that a longer average cell length yields more rapidly expanding, flatter biofilms. We experimentally show that such changes in biofilm development occur by exploiting chemicals that modulate cell length.
Journal
Nat Phys
Volume
14
Pages
954-960
Date Published
09/2018
ISBN
1745-2473 (Print)1745-2473
Accession Number
30906420

Beroz, FarzanYan, JingSabass, BenediktStone, Howard ABassler, Bonnie LWingreen, Ned SMeir, YigalHHMI_/Howard Hughes Medical Institute/United StatesR01 GM065859/GM/NIGMS NIH HHS/United StatesR01 GM082938/GM/NIGMS NIH HHS/United StatesR37 GM065859/GM/NIGMS NIH HHS/United StatesJournal Article2019/03/25Nat Phys. 2018 Sep;14(9):954-960. doi: 10.1038/s41567-018-0170-4. Epub 2018 Jun 18.