12 research outputs found
Killing by type VI secretion drives genetic phase separation and correlates with increased cooperation
By nature of their small size, dense growth and frequent need for extracellular metabolism, microbes face persistent public goods dilemmas. Genetic assortment is the only general solution stabilizing cooperation, but all known mechanisms structuring microbial populations depend on the availability of free space, an often unrealistic constraint. Here we describe a class of self-organization that operates within densely packed bacterial populations. Through mathematical modelling and experiments with Vibrio cholerae, we show how killing adjacent competitors via the Type VI secretion system (T6SS) precipitates phase separation via the ‘Model A' universality class of order-disorder transition mediated by killing. We mathematically demonstrate that T6SS-mediated killing should favour the evolution of public goods cooperation, and empirically support this prediction using a phylogenetic comparative analysis. This work illustrates the twin role played by the T6SS, dealing death to local competitors while simultaneously creating conditions potentially favouring the evolution of cooperation with kin
Emergency Preparedness in High School–Based Athletics: A Review of the Literature and Recommendations for Sport Health Professionals
Interaction networks for identifying coupled molecular processes in microbial communities
Gaining voice in the mass media: The effect of parties’ strategies on party–issue linkages in election news coverage
Spatial structure, cooperation and competition in biofilms
Biofilm formation, in which cells form matrix-enclosed communities, is a major mode of microbial life. The study of biofilms has revealed vast complexity both in terms of their resident species composition and phenotypic diversity. Despite this complexity, theoretical and experimental work in the past decade has identified common principles for understanding microbial biofilms. In this Review, we discuss how the spatial arrangement of genotypes within a community influences the cooperative and competitive cell-cell interactions that define biofilm form and function. Furthermore, we argue that a perspective rooted in ecology and evolution is fundamental to progress in microbiology