Ryan, Kylie Meghan2022-06-222022-06-222021-11-15vt_gsexam:33149http://hdl.handle.net/10919/110871Signal transduction networks enable organisms to respond to environmental stimuli. Bacteria utilize two-component systems (TCSs) and phosphorelays as their primary means of signal transduction. Histidine kinase (HK) and response regulator (RR) proteins comprise these TCSs and phosphorelays. Previously, signal transduction within TCSs and phosphorelays was thought to only occur through a linear series of phosphotransfers between HKs and RRs. Recently multikinase networks have been shown to be involved in TCS and phosphorelay signal transmission. A multikinase network that includes the HKs RetS and GacS controls the switch between the motile invasive lifestyle and the sessile biofilm lifestyle of the opportunistic human pathogen Pseudomonas aeruginosa. GacS promotes the sessile biofilm lifestyle, while RetS promotes the motile invasive lifestyle via the inhibition of GacS. This inhibition occurs through three distinct mechanisms. Two of the mechanisms are dephosphorylating mechanisms and the third mechanism is a direct interaction between RetS and GacS which results in the inhibition of GacS autophosphorylation. This study examines the direct binding interaction between RetS and GacS using structural biology. We observed a heterodimeric RetS-GacS complex in which the canonical homodimerization interface was replaced with a heterodimeric interface. Heterodimerization between bacterial HKs is currently a novel observation, but it is likely that other HKs heterodimerize. The RetS-GacS direct interaction can serve as a model for HK-HK binding in multikinase networks.ETDenIn Copyrightbacterial histidine kinaseprotein-protein interactionsbiofilmPseudomonas aeruginosaTwo-component systemscrosstalkDissertation