TY - JOUR A1 - García-Betancur, Juan-Carlos A1 - Goñi-Moreno, Angel A1 - Horger, Thomas A1 - Schott, Melanie A1 - Sharan, Malvika A1 - Eikmeier, Julian A1 - Wohlmuth, Barbara A1 - Zernecke, Alma A1 - Ohlsen, Knut A1 - Kuttler, Christina A1 - Lopez, Daniel T1 - Cell differentiation defines acute and chronic infection cell types in Staphylococcus aureus JF - eLife N2 - A central question to biology is how pathogenic bacteria initiate acute or chronic infections. Here we describe a genetic program for cell-fate decision in the opportunistic human pathogen Staphylococcus aureus, which generates the phenotypic bifurcation of the cells into two genetically identical but different cell types during the course of an infection. Whereas one cell type promotes the formation of biofilms that contribute to chronic infections, the second type is planktonic and produces the toxins that contribute to acute bacteremia. We identified a bimodal switch in the agr quorum sensing system that antagonistically regulates the differentiation of these two physiologically distinct cell types. We found that extracellular signals affect the behavior of the agr bimodal switch and modify the size of the specialized subpopulations in specific colonization niches. For instance, magnesium-enriched colonization niches causes magnesium binding to S. aureusteichoic acids and increases bacterial cell wall rigidity. This signal triggers a genetic program that ultimately downregulates the agr bimodal switch. Colonization niches with different magnesium concentrations influence the bimodal system activity, which defines a distinct ratio between these subpopulations; this in turn leads to distinct infection outcomes in vitro and in an in vivo murine infection model. Cell differentiation generates physiological heterogeneity in clonal bacterial infections and helps to determine the distinct infection types. KW - Staphylococcus aureus KW - infection KW - cell differentiation KW - pathogenic bacteria Y1 - 2017 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-170346 VL - 6 IS - e28023 ER - TY - JOUR A1 - Schneider, Johannes A1 - Klein, Teresa A1 - Mielich-Süss, Benjamin A1 - Koch, Gudrun A1 - Franke, Christian A1 - Kuipers, Oskar P. A1 - Kovács, Ákos T. A1 - Sauer, Markus A1 - Lopez, Daniel T1 - Spatio-temporal Remodeling of Functional Membrane Microdomains Organizes the Signaling Networks of a Bacterium JF - PLoS Genetics N2 - Lipid rafts are membrane microdomains specialized in the regulation of numerous cellular processes related to membrane organization, as diverse as signal transduction, protein sorting, membrane trafficking or pathogen invasion. It has been proposed that this functional diversity would require a heterogeneous population of raft domains with varying compositions. However, a mechanism for such diversification is not known. We recently discovered that bacterial membranes organize their signal transduction pathways in functional membrane microdomains (FMMs) that are structurally and functionally similar to the eukaryotic lipid rafts. In this report, we took advantage of the tractability of the prokaryotic model Bacillus subtilis to provide evidence for the coexistence of two distinct families of FMMs in bacterial membranes, displaying a distinctive distribution of proteins specialized in different biological processes. One family of microdomains harbors the scaffolding flotillin protein FloA that selectively tethers proteins specialized in regulating cell envelope turnover and primary metabolism. A second population of microdomains containing the two scaffolding flotillins, FloA and FloT, arises exclusively at later stages of cell growth and specializes in adaptation of cells to stationary phase. Importantly, the diversification of membrane microdomains does not occur arbitrarily. We discovered that bacterial cells control the spatio-temporal remodeling of microdomains by restricting the activation of FloT expression to stationary phase. This regulation ensures a sequential assembly of functionally specialized membrane microdomains to strategically organize signaling networks at the right time during the lifespan of a bacterium. KW - membrane proteins KW - gene expression KW - bacillus subtilis KW - fluorescence microscopy KW - cell fusion KW - signal transduction KW - gene regulation KW - lipids Y1 - 2015 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-125577 VL - 11 IS - 4 ER -