A successful symbiotic relationship between Sinorhizobium meliloti and its host Medicago sativa (alfalfa) depends on several signaling mechanisms, such as the biosynthesis of exopolysaccharides (EPS) by S. meliloti. Previous work in our laboratory has shown that a quorum-sensing mechanism controls the production of the symbiotically active EPS II. Recent microarray analysis of the whole-genome expression profile of S. meliloti reveals that the ExpR/Sin quorum-sensing system regulates additional physiological processes that include low-molecular-weight succinoglycan production, nitrogen utilization, metal transport, motility, and chemotaxis. Nearly half of the flagellar genes and their dependence on quorum sensing are prominently displayed in our microarray analyses. We extend those observations in this work and confirm the findings by real-time PCR expression analysis of selected genes, including the flaF, flbT, flaC, cheY1, and flgB genes, involved in motility and chemotaxis. These genes code for regulators of flagellum synthesis, the chemotactic response, or parts of the flagellar apparatus. Gene expression analyses and visualization of flagella by electron microscopy performed at different points in the growth phase support our proposed model in which quorum sensing downregulates motility in S. meliloti. We demonstrate that the ExpR/Sin quorum-sensing system controls motility gene expression through the VisN/VisR/Rem relay. We also show that the ExoS-dependent twocomponent system suppresses motility gene expression through VisN and Rem in parallel to quorum sensing. This study contributes to our understanding of the mechanisms that govern motility in S. meliloti. An organism's ability to sense and move toward a favorable environment or away from a hazardous one provides it with a substantial and often crucial advantage over nonmotile competitors. More than 70% of microorganisms are motile and chemotactic, and much of the ground-breaking work in this field has been derived from the studies of such bacteria as Escherichia coli, Pseudomonas aeruginosa, and Serratia marcescens (12,26,29,40,47,52,57). Although equipped with an extremely useful ability, motile organisms must expend large amounts of energy to synthesize, assemble, and activate the machinery for motility and chemotaxis. As much as 2% of the energy expenditure in the cell can be attributed to the maintenance of such activities; therefore, it is often in the bacterium's best interest to strictly regulate its ability to move toward those conditions most favorable for survival (35, 52). Many factors can influence an organism's movement including, but not limited to, temperature, pH, ion concentration, and the availability of metabolites (52). There is increasing evidence that connects the mechanism of quorum sensing, a populationdensity-dependent mode of gene regulation, to the control of motility. In S. marcescens, Vibrio cholerae, and E. coli, production of the motility machinery is upregulated as the population density increases (3,14,53,54,61). In th...
