Aldridge Phillip, Karlinsey Joyce E, Becker Eric, Chevance Fabienne F V, Hughes Kelly T
Department of Biology, University of Utah, Salt Lake City, UT 84112, USA.
Mol Microbiol. 2006 May;60(3):630-43. doi: 10.1111/j.1365-2958.2006.05135.x.
The flk locus of Salmonella typhimurium was identified as a regulator of flagellar gene expression in strains defective in P- and l-ring formation. Flk acts as a regulator of flagellar gene expression by modulating the protein levels of the anti-sigma28 factor FlgM. Evidence is presented which suggests that Flk is a cytoplasmic-facing protein anchored to the inner membrane by a single, C-terminal transmembrane-spanning domain (TMS). The specific amino acid sequence of the TMS is not essential for Flk activity, but membrane anchoring is essential. Membrane fractionation and visualization of protein fusions of green fluorescent protein derivatives to Flk suggested that the Flk protein is present in the membrane as punctate spots in number that are much greater than the number of flagellar basal structures. The turnover of the anti-sigma28 factor FlgM was increased in flk mutant strains. Using FlgM-beta-lactamase fusions we show the increased turnover of FlgM in flk null mutations is due to FlgM secretion into the periplasm where it is degraded. Our data suggest that Flk inhibits FlgM secretion by acting as a braking system for the flagellar-associated type III secretion system. A model is presented to explain a role for Flk in flagellar assembly and gene regulatory processes.
鼠伤寒沙门氏菌的flk位点被确定为在P环和L环形成有缺陷的菌株中鞭毛基因表达的调节因子。Flk通过调节抗σ28因子FlgM的蛋白质水平来充当鞭毛基因表达的调节因子。有证据表明,Flk是一种面向细胞质的蛋白质,通过单个C末端跨膜结构域(TMS)锚定在内膜上。TMS的特定氨基酸序列对Flk活性不是必需的,但膜锚定是必需的。膜分级分离以及绿色荧光蛋白衍生物与Flk的蛋白质融合物的可视化表明,Flk蛋白以点状形式存在于膜中,其数量远多于鞭毛基部结构的数量。在flk突变菌株中,抗σ28因子FlgM的周转增加。使用FlgM-β-内酰胺酶融合物,我们表明在flk基因缺失突变中FlgM周转增加是由于FlgM分泌到周质中并在那里被降解。我们的数据表明,Flk通过充当鞭毛相关III型分泌系统的制动系统来抑制FlgM分泌。提出了一个模型来解释Flk在鞭毛组装和基因调控过程中的作用。
