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ABSTRACT: Swarming motility is the movement of bacteria over a solid surface powered by rotating flagella. The expression of flagellar biosynthesis genes is governed by species-specific master regulator transcription factors. Mutations that reduce or enhance master regulator activity have a commensurate effect on swarming motility. Here we review what is known about the proteins that modulate swarming motility and appear to act upstream of the master flagellar regulators in diverse swarming bacteria. We hypothesize that environmental control of the master regulators is important to the swarming phenotype perhaps at the level of controlling flagellar number.
Molecular Microbiology 11/2011; 83(1):14-23. · 5.01 Impact Factor
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ABSTRACT: Growing tendrils of aflagellate hag mutants of Bacillus subtilis were found to show an avoidance response when colonizing a semi-solid medium, suggesting a tip-to-tip communication mechanism between colonies. There may be a second sensing mechanism involved in shaping the morphology of tendrils. Tendril growth in B. subtilis was dependent on and possibly shaped by the release of surfactin, a biosurfactant. Transposon mutagenesis yielded two mutants with 'touching' tendrils, and each had a disrupted gspA gene that encodes a putative glycosyltransferase. Tendrils of gspA mutants, unlike the parental strain, were unresponsive to tendril tip growth by surfactin, suggesting disruption of intercellular signaling. Tendril sensing and avoidance could be physiologically relevant in habitats, such as plant roots, where some limiting nutrient might induce this type of multicellular behavior, promoting avoidance of previously explored areas by sibling colonies.
FEMS Microbiology Letters 10/2009; 298(1):12-9. · 2.04 Impact Factor
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ABSTRACT: We redemonstrate that SwrA is essential for swarming motility in Bacillus subtilis, and we reassert that laboratory strains of B. subtilis do not swarm. Additionally, we find that a number of other genes, previously reported to be required for swarming in laboratory strains, are dispensable for robust swarming motility in an undomesticated strain. We attribute discrepancies in the literature to a lack of reproducible standard experimental conditions, selection for spontaneous swarming suppressors, inadvertent genetic linkage to swarming mutations, and auxotrophy.
Journal of bacteriology 09/2009; 191(22):7129-33. · 3.94 Impact Factor
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ABSTRACT: In Bacillus subtilis, FtsZ ring formation and cell division is favoured at the midcell because the inhibitor proteins MinC and MinD are indirectly restricted to the cell poles by the protein DivIVA. Here we identify MinJ, a topological determinant of medial FtsZ positioning that acts as an intermediary between DivIVA and MinD. Due to unrestricted MinD activity, cells mutated for minJ exhibited pleiotropic defects in homologous recombination, swarming motility and cell division. MinJ restricted MinD activity by localizing MinD to the cell poles through direct protein-protein interaction. MinJ itself localized to cell poles in a manner that was dependent on DivIVA. MinJ is conserved in other low G+C Gram-positive bacteria and may be an important component of cell division site selection in these organisms.
Molecular Microbiology 01/2009; 70(5):1166-79. · 5.01 Impact Factor
