TY - JOUR T1 - Quorum sensing in <em>Bacillus subtilis</em> slows down biofilm formation by enabling sporulation bet hedging JF - bioRxiv DO - 10.1101/768671 SP - 768671 AU - Mihael Spacapan AU - Tjaša Danevčič AU - Polonca Štefanic AU - Ines Mandic-Mulec Y1 - 2019/01/01 UR - http://biorxiv.org/content/early/2019/09/16/768671.abstract N2 - The ComQXPA quorum sensing (QS) system of Bacillus subtilis, a Gram-positive, industrially relevant, endospore forming bacterium, promotes surfactin production. This lipopeptide increases transcription of several genes involved in biofilm matrix synthesis via the Spo0A-P master regulator. We hypothesized that the inactivation of the QS system will therefore result in decreased rates of floating biofilm formation. We find that this is not the case and that the QS deficient mutant forms pellicles with a faster rate and produces more biofilm matrix components than the wild type. As Spo0A-P is the master regulator of sporulation initiation we hypothesized that the ComQXPA dependent signaling promotes sporulation and consequently slows the growth rate of the wild type strain. Indeed, our results confirm that cells with the inactive QS initiate endospore formation in biofilms later and more synchronously than the wild type, as evidenced by spore frequencies and the PspoIIQ promoter activity. We argue, that the QS system acts as a switch that promotes stochastic sporulation initiation and consequently bet hedging behavior. By committing a subpopulation of cells to sporulation early during growth, wild type population grows slower and produces thinner biofilms but also assures better survival under stressful conditions.IMPORTANCE Bacillus subtilis is widely employed model organism to study biofilm formation and sporulation in Gram-positive bacteria. The ComQXPA quorum sensing (QS) system indirectly increases the transcription of genes involved in biofilm matrix formation, which predicts a positive role of this QS in biofilm development Here we show that QS mutants actually form more matrix components per pellicle than the wild type and that their pellicles are thicker and form with a faster rate. We explain this, by showing that cells with an inactive QS exhibit a delay in sporulation entry, which is also more synchronous relative to the wild type. We argue, that the ComQXPA QS system acts as a switch that contributes to the stochastic sporulation initiation and though this path promotes bet hedging behavior. This finding is important in terms of “quorum quenching” strategies aiming to down modulate biofilm development through inhibition of QS signaling and underscores the richness of QS regulated phenotypic outcomes among bacterial species. ER -