Regulation of Biofilm Aging and Dispersal in Bacillus subtilis by the Alternative Sigma Factor SigB

Bacterial biofilms are important in natural settings, biotechnology, and medicine. However, regulation of biofilm development and its persistence in different niches is complex and only partially understood. One key step during the biofilm life cycle is dispersal, when motile cells abandon the matur...

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Bibliographic Details
Published in:Journal of bacteriology 2019-01, Vol.201 (2)
Main Authors: Bartolini, M, Cogliati, S, Vileta, D, Bauman, C, Rateni, L, Leñini, C, Argañaraz, F, Francisco, M, Villalba, J M, Steil, L, Völker, U, Grau, R
Format: Article
Language:English
Subjects:
Aging
Aging (natural)
Bacillus subtilis
Bacillus subtilis - genetics
Bacillus subtilis - growth & development
Bacillus subtilis - metabolism
Bacteria
Bacterial Proteins - metabolism
Bacteriology
Biofilms
Biofilms - growth & development
Biotechnology
Cell death
Control
Culture Media - chemistry
Dispersal
Dispersion
Fitness
Gene Expression Regulation, Bacterial
Life cycle engineering
Life cycles
Locomotion
Metabolism
Nutrients
Sigma factor
Sigma Factor - deficiency
Sigma Factor - metabolism
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Summary:Bacterial biofilms are important in natural settings, biotechnology, and medicine. However, regulation of biofilm development and its persistence in different niches is complex and only partially understood. One key step during the biofilm life cycle is dispersal, when motile cells abandon the mature biofilm to spread out and colonize new niches. Here, we show that in the model bacterium the general stress transcription factor SigB is essential for halting detrimental overgrowth of mature biofilm and for triggering dispersal when nutrients become limited. Specifically, SigB-deficient biofilms were larger than wild-type biofilms but exhibited accelerated cell death, significantly greater sensitivity to different stresses, and reduced dispersal. Interestingly, the signal detected by SigB to limit biofilm growth was transduced through the RsbP-dependent metabolic arm of the SigB regulatory cascade, which in turn positively controlled expression of SinR, the master regulator of biofilm formation and cell motility. This novel SigB-SinR regulatory circuit might be important in controlling the fitness of biofilms (either beneficial or harmful) in diverse environments. Biofilms are crucial for bacterial survival, adaptation, and dissemination in natural, industrial, and medical systems. Sessile cells embedded in the self-produced extracellular matrix of the biofilm benefit from a division of labor and are protected from environmental insults. However, as the biofilm ages, cells become stressed because of overcrowding, starvation, and accumulation of waste products. How does the sessile biofilm community sense and respond to stressful conditions? Here, we show that in , the transcription factors SigB and SinR control whether cells remain in or leave a biofilm when metabolic conditions become unfavorable. This novel SigB-SinR regulatory circuit might be important for controlling the fitness of biofilms (either beneficial or harmful) in diverse environments.
ISSN:0021-9193
1098-5530
DOI:10.1128/JB.00473-18