ABSTRACTThe stress-responsive alternative sigma factor σBis conserved across diverse Gram-positive bacterial genera. InListeria monocytogenes, σBregulates transcription of >150 genes, including genes contributing to virulence and to bacterial survival under host-associated stress conditions, such as those encountered in the human gastrointestinal lumen. An inhibitor ofL. monocytogenesσBactivity was identified by screening ~57,000 natural and synthesized small molecules using a high-throughput cell-based assay. The compound fluoro-phenyl-styrene-sulfonamide (FPSS) (IC50= 3.5 µM) downregulated the majority of genes previously identified as members of the σBregulon inL. monocytogenes10403S, thus generating a transcriptional profile comparable to that of a 10403S ΔsigBstrain. Specifically, of the 208 genes downregulated by FPSS, 75% had been identified previously as positively regulated by σB. Downregulated genes included key virulence and stress response genes, such asinlA,inlB,bsh,hfq,opuC, andbilE. From a functional perspective, FPSS also inhibitedL. monocytogenesinvasion of human intestinal epithelial cells and bile salt hydrolase activity. The ability of FPSS to inhibit σBactivity in bothL. monocytogenesandBacillus subtilisindicates its utility as a specific inhibitor of σBacross multiple Gram-positive genera.IMPORTANCEThe σBtranscription factor regulates expression of genes responsible for bacterial survival under changing environmental conditions and for virulence; therefore, this alternative sigma factor is important for transmission ofL. monocytogenesand other Gram-positive bacteria. Regulation of σBactivity is complex and tightly controlled, reflecting the key role of this factor in bacterial metabolism. We present multiple lines of evidence indicating that fluoro-phenyl-styrene-sulfonamide (FPSS) specifically inhibits activity of σBacross Gram-positive bacterial genera, i.e., in bothListeria monocytogenesandBacillus subtilis. Therefore, FPSS is an important new tool that will enable novel approaches for exploring complex regulatory networks inL. monocytogenesand other Gram-positive pathogens and for investigating small-molecule applications for controlling pathogen transmission.