Abstract
Microbial populations are ubiquitous and some form a robust, multicellular structure called biofilm that protects the cells from environmental damage. The dispersion cycle is critical for controlling the population of important target microbes (both pathogenic and beneficial). Here, we show that the hysteresis of Bacillus subtilis cell-type regulation with respect to auto-inducing signal strength triggers the migration cycle of the cell population. We investigate migration cycle and its dependence on environmental conditions by quantitative analysis of cyclically expanding, concentric circular colonies. Next, we construct an input/output model that controls cell types in response to environmental conditions and signal density. On the basis of this model, we propose a migration cycle model for cell populations. The proposed model will widely predict biofilm-related phenomena and provide the basis for the description of highly self-regulating multicellular systems.
Competing Interest Statement
The authors have declared no competing interest.
Footnotes
Fig. 2(d) changed to a logarithmic graph. This has resulted in the addition of additional discussion text. Many other minor corrections have been made as pointed out by one of the authors. Also, the order of authors was changed according to their roles and contributions.
