Section of Molecular Genetics and Microbiology and Institute of Cellular and Molecular Biology, University of Texas at Austin, Austin, Texas, USA.
J Bacteriol. 2013 Mar;195(5):919-29. doi: 10.1128/JB.02064-12. Epub 2012 Dec 21.
We show in this study that Salmonella cells, which do not upregulate flagellar gene expression during swarming, also do not increase flagellar numbers per μm of cell length as determined by systematic counting of both flagellar filaments and hooks. Instead, doubling of the average length of a swarmer cell by suppression of cell division effectively doubles the number of flagella per cell. The highest agar concentration at which Salmonella cells swarmed increased from the normal 0.5% to 1%, either when flagella were overproduced or when expression of the FliL protein was enhanced in conjunction with stator proteins MotAB. We surmise that bacteria use the resulting increase in motor power to overcome the higher friction associated with harder agar. Higher flagellar numbers also suppress the swarming defect of mutants with changes in the chemotaxis pathway that were previously shown to be defective in hydrating their colonies. Here we show that the swarming defect of these mutants can also be suppressed by application of osmolytes to the surface of swarm agar. The "dry" colony morphology displayed by che mutants was also observed with other mutants that do not actively rotate their flagella. The flagellum/motor thus participates in two functions critical for swarming, enabling hydration and overriding surface friction. We consider some ideas for how the flagellum might help attract water to the agar surface, where there is no free water.
在这项研究中我们表明,在群体游动期间并不上调鞭毛基因表达的沙门氏菌细胞,也不会增加鞭毛数量/μm 细胞长度,这是通过对鞭毛丝和钩的系统计数来确定的。相反,通过抑制细胞分裂将游动细胞的平均长度加倍,实际上可以使每个细胞的鞭毛数量加倍。当鞭毛过度产生或与定子蛋白 MotAB 一起增强 FliL 蛋白的表达时,沙门氏菌细胞在最高琼脂浓度从正常的 0.5%增加到 1%时可以游动。我们推测,细菌利用增加的动力来克服与更硬的琼脂相关的更高摩擦。更高的鞭毛数量也抑制了化学趋性途径突变体的游动缺陷,这些突变体以前被证明在水合其菌落方面存在缺陷。在这里,我们表明,通过向 swarm 琼脂表面施加渗透剂,这些突变体的游动缺陷也可以被抑制。在其他不主动旋转其鞭毛的突变体中也观察到 che 突变体的“干燥”菌落形态。因此,鞭毛/马达参与了对群体游动至关重要的两个功能,使水合作用和克服表面摩擦成为可能。我们考虑了一些关于鞭毛如何帮助将水吸引到没有自由水的琼脂表面的想法。