Bacterial biofilms are a public health threat because they cause chronic and hospital-acquired infections but are resistant to antibiotics. Failure to characterize the biochemical machinery that drives biofilm dispersal risks missing key targets for treatment of infectious disease. Although nitric oxide (NO)-triggered biofilm dispersal in Pseudomonas aeruginosa (PA), a principal pathogen in cystic fibrosis and hospital-acquired infections, is well documented, the underlying biochemical processes responsible are not understood. To bridge this knowledge gap, a long-term goal of the PI is to determine the mechanism of NO signaling in bacteria and to use this knowledge to develop therapeutic strategies to disperse biofilms. In her previous RO1 funding period, the PI established the NosP (NO sensing protein) family of hemoproteins, which were discovered in her laboratory, as NO sensors that regulate biofilm in many bacteria. Based on studies from the previous funding period, the objective of the proposed work is to characterize the NosP-associated histidine kinase (NahK) and determine the molecular mechanism underlying NO/NosP/NahK regulation of biofilm and virulence in PA. It is hypothesized that NO produced downstream of RsmA binds NosP to trigger biofilm dispersal through NahK and the GacS/Rsm MKN. The GacS/Rsm MKN integrates signals from many sensor kinases to control RsmA, the master regulator of motility/acute infection v. biofilm/chronic infection in PA. The proposal is innovative because it challenges the established GacS/Rsm MKN and forges new logical connections between anaerobic respiration, NO, biofilm, and virulence. This proposal is significant because elucidation of the basis for NO signaling in PA will open new therapeutic opportunities for controlling infection caused by this important human pathogen. The hypothesis will be tested by pursuing three specific aims: (1) to identify NosP/NahK interactions within the GacS/Rsm MKN; (2) to delineate the role of NosP/NahK in modulation of RsmA-controlled phenotypes; and (3) to establish the link between RsmA-regulated denitrification and NosP/NahK signaling. Under aim 1, NahK protein-protein and phosphotransfer interactions with GacS/Rsm MKN members will be characterized as a function of NO/NosP regulation. Under aim 2, the effect of NO/NosP/NahK on virulence, quorum sensing, and cyclic-di-GMP pathways controlled by the RsmA will be quantified. Under aim 3, the effect of NO/NosP/NahK on RsmA-controlled denitrification will be quantified and investigated as a regulatory feedback loop. The PI has significant experience with the proposed assays. Upon completion of these aims, NO/NosP/NahK is expected to be established in controlling the GacS/Rsm motility/virulence switch. This would represent a fundamentally important discovery, defining a new signaling pathway and novel antibiotic targets, for which there is a pressing need, especially considering the increased antibiotic resistance typically s...