Summary: | Type IV pili (T4P) are bacterial biomolecular machines that mediate interactions with the environment. Bacterial pathogens such as Pseudomonas aeruginosa require T4P for virulence. Significant progress has been made in recent years towards our understanding of how the proteins in the T4P system interact and function. While over 50 different proteins are involved in T4P biogenesis, the two outer membrane components, PilF and PilQ, are the focus of the work presented in this thesis.
PilF was found to be required for assembly of PilQ into secretins, the outer membrane channels through which T4P fibers exit the cell. The functions of PilF are consistent with a family of lipoproteins called pilotins, to which the roles of secretin assembly and/or localization are attributed. Structure determination by X-ray crystallography revealed that PilF is composed of six tetratricopeptide (TPR) protein-protein interaction motifs. Functional mapping of PilF indicated that a hydrophobic groove on the first TPR is involved in secretin assembly. Secretin localization correlated directly with that of PilF. The effects of pilF mutations and the structural data led to the hypothesis that PilF and PilQ interact directly. We propose that PilF and PilQ interact at the inner membrane and are co-transported to the outer membrane by the Lol lipoprotein sorting system. PilQ multimerizes into secretins upon outer membrane insertion and aligns with inner membrane T4P proteins to form a complete molecular machine.
PilQ mutagenesis mapping showed that: the N-terminal “system specific” domain is important but not essential for secretin function; the central “multimerization” domain is critical for secretin assembly and function; and the C-terminal tail implicated in secretin-pilotin interactions is dispensable for PilQ function. Purified PilQ enabled copurification of PilF from cell lysates, providing the first evidence for their interaction. These data provide a framework for future exploration of T4P assembly in P. aeruginosa.
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