Abstract
2SUMMARYBordetella species cause lower respiratory tract infections in mammals. B. pertussis and B. bronchiseptica are the causative agents of whooping cough and kennel cough, respectively. The current acellular vaccine for B. pertussis protects against the pertussis toxin but does not prevent transmission or colonization. Cases of B. pertussis infections are on the rise even in areas of high vaccination. The PlrSR two-component system, is required for persistence in the mouse lung. A partial plrS deletion strain and a plrS H521Q strain cannot survive past three days in the lung, suggesting PlrSR works in a phosphorylation dependent mechanism. We characterized the biochemistry of B. bronchiseptica PlrSR and found that both proteins function as a canonical two-component system. His521 and Glu522 were essential for PlrS autophosphorylation. Asn525 was essential for phosphatase activity. The PAS domain was critical for both PlrS autophosphorylation and phosphatase activities. PlrS can both phosphotransfer to and exert phosphatase activity towards PlrR. Unexpectedly, PlrR forms a tetramer when unphosphorylated and a dimer upon phosphorylation. Finally, we demonstrated the importance of PlrS phosphatase activity for persistence within the murine lung. By characterizing PlrSR we hope to guide future in vivo investigation for development of new vaccines and therapeutics.10GRAPHICAL ABSTRACT
Publisher
Cold Spring Harbor Laboratory