In summary, the swarming motility of C. freundii has been described in this work. Our results demonstrated that the nutritional requirement for swarming motility in C. freundii is quite high. A mixture of amino acids was found to be unable to induce swarming of C. freundii, although they could induce swarming in some other swarming bacteria such as P. mirabilis, P. aeruginosa, and S. enterica serovar Typhimurium
(Allison et al., 1993; Kohler et al., 2000; Toguchi et al., 2000). In swarming colonies, C. freundii cells became hyperflagellated and slightly elongated compared with the vegetative cells grown in liquid media. To date, many species have been found to possess the ability to swarm on agar surfaces. However, the genes required specifically for this Deforolimus molecular weight type of motility are not completely understood and vary among species. In this work, numerous swarming genes have been identified in our attempt to screen the genetic determinants for C. freundii swarming. Among the mutants with mutations that have been mapped to previously characterized genes, there are several unique characteristics in C. freundii. For example, the mutants related to lipopolysaccharide synthesis and the RcsCDB signal
system showed a propensity to form less motile aggregates in the swarming colonies, APO866 and the rcsD and rcsC mutants do not display precocious swarming phenotype as in other bacteria. Moreover, insertion mutation in the five genetic loci, which have not been demonstrated to
be involved in swarming, have been identified to result in defective swarming behavior in C. freundii. Some of these have interesting phenotypes; for example, the yeeZ mutant displayed an elongated shape, which may provide a clue for studying the function of related genes. Our results indicate that swarming motility is more complicated than currently known; in addition, its features vary among swarming bacteria. Thus, further studies on swarming in different bacteria are needed to achieve a complete understanding of this special motility. We thank Tomofusa Tsuchiya of Okayama University, Japan, most for providing strain C. freundii. We also gratefully acknowledge Victor de Lorenzo of Centro Nacional de Biotecnologia CSIC, Spain, for providing Mini-Tn5 transposon. Fig. S1. Electron micrograph of bacterial cell collected from LB plate with 1.5% agar; scale bar=2 μm. Fig. S2. Bacterial surface hydrophilicities measured by BATH method, as described in the Materials and methods. Fig. S3. Growth curves of the mutant and wild-type strains. Fig. S4. SDS-PAGE of lipopolysaccharide profiles. Fig. S5. Swarming colonies of Proteus mirabilis CMCC49003 stained in situ with TTC. Video S1. Movement of wild type cells on swarm media. Video S2. Movement of wzx mutant cells on swarm media (episode 1). Video S3. Movement of wzx mutant cells on swarm media (episode 2).
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