Collagen IV-derived peptide binds hydrophobic cavity of Legionella pneumophila Mip and interferes with bacterial epithelial transmigration.

The Legionella virulence factor Mip (macrophage infectivity potentiator) contributes to bacterial dissemination within infected lung tissue. The Mip protein, which belongs to the enzyme family of FK506-binding proteins (FKBP), binds specifically to collagen IV. We identified a surface-exposed Mip-binding sequence in the NC1 domain of human collagen IV α1. The corresponding collagen IV-derived peptide (P290) co-precipitated with Mip and competitively inhibited the Mip-collagen IV binding. Transmigration of Legionella pneumophila across a barrier of NCI-H292 lung epithelial cells and extracellular matrix was efficiently inhibited by P290. This significantly reduced transmigration was comparable to the inefficient transmigration of PPIase-negative Mip mutant or rapamycin-treated L. pneumophila. Based on NMR data and docking studies a model for the mode of interaction of P290 and Mip was developed. The amino acids of the hydrophobic cavity of Mip, D142 and to a lesser extent Y185 were identified to be part of the interaction surface. In the complex structure of Mip(77-213) and P290, both amino acid residues form hydrogen bonds to P290. Utilizing modelling, molecular dynamics (MD) simulations and structural data of human PPIase FKBP12, the most related human orthologue of Mip, we were able to propose optimized P290 variants with increased binding specificity and selectivity for the putative bacterial drug target Mip.

RpkA, a highly conserved GPCR with a lipid kinase domain, has a role in phagocytosis and anti-bacterial defense.

RpkA (Receptor phosphatidylinositol kinase A) is an unusual seven-helix transmembrane protein of Dictyostelium discoideum with a G protein coupled receptor (GPCR) signature and a C-terminal lipid kinase domain (GPCR-PIPK) predicted as a phosphatidylinositol-4-phosphate 5-kinase. RpkA-homologs are present in all so far sequenced Dictyostelidae as well as in several other lower eukaryotes like the oomycete Phytophthora, and in the Legionella host Acanthamoeba castellani. Here we show by immunofluorescence that RpkA localizes to endosomal membranes and is specifically recruited to phagosomes. RpkA interacts with the phagosomal protein complex V-ATPase as proteins of this complex co-precipitate with RpkA-GFP as well as with the GST-tagged PIPK domain of RpkA. Loss of RpkA leads to a defect in phagocytosis as measured by yeast particle uptake. The uptake of the pathogenic bacterium Legionella pneumophila was however unaltered whereas its intra-cellular replication was significantly enhanced in rpkA(-). The difference between wild type and rpkA(-) was even more prominent when L. hackeliae was used. When we investigated the reason for the enhanced susceptibility for L. pneumophila of rpkA(-) we could not detect a difference in endosomal pH but rpkA(-) showed depletion of phosphoinositides (PIP and PIP(2)) when we compared metabolically labeled phosphoinositides from wild type and rpkA(-). Furthermore rpkA(-) exhibited reduced nitrogen starvation tolerance, an indicator for a reduced autophagy rate. Our results indicate that RpkA is a component of the defense system of D. discoideum as well as other lower eukaryotes.