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Molecular Basis of Diverse PagP::Lipid Interactions in Gram-Negative Bacteria / Diverse PagP::Lipid Interactions in Gram-Negative Bacteria

PagP is an integral outer membrane enzyme that transfers a palmitoyl group from a phospholipid to lipid A and the polar headgroup of phosphatidylglycerol (PG). Palmitoyl-lipid A and palmitoyl-PG (PPG) have been implicated in resistance to host immune defenses. PagP proteins are diverse, the E. coli PagP belongs to the major clade of PagP homologs and palmitoylates lipid A regiospecifically at the 2-position, whereas P. aeruginosa PagP belongs to the minor clade of PagP homologs and instead palmitoylates lipid A regiospecifically at the 3’-position. Our objective was to understand how PagP has been adapted in nature to interact with multiple lipid substrates and products. We investigated the structure-function relationships of key major clade homologs, to show that Bordetella PagP palmitoylates lipid A at the 3’-position and employs surface residue T29 in its palmitoyltransferase reaction. Legionella PagP palmitoylates lipid A at the 2-position and was confirmed to select a palmitate chain from a pool including iso-methyl branched phospholipids characteristic of this species. PagP is usually encoded as a single copy on the chromosome in most bacteria, but two copies of pagP are found in endophytic bacteria. These duplicated PagP homologs from the major clade branch into two subclades, namely chromosomal and plasmid-based PagP homologs. The chromosomal PagP homologs exhibit interacting periplasmic D61 and H67 residues, which are naturally mutated in plasmid-based PagP homologs, and are associated with a conformational change in the -barrel that determines its ability to palmitoylate PG. Chromosomal PagPs can convert PPG to bis(monoacylglycero)phosphate (BMP) and lysophosphatidylglycerol (LPG) through a periplasmic active site controlled by the invariant Y87 residue of E. coli PagP. Plasmid-based PagP homologs appear to have been adapted instead as monofunctional lipid A palmitoyltransferases. These results points to a common ancestor for PagP proteins. Knowledge gained from these studies can be applied to protein engineering. / Thesis / Doctor of Philosophy (PhD)

Identiferoai:union.ndltd.org:mcmaster.ca/oai:macsphere.mcmaster.ca:11375/24077
Date January 2018
CreatorsMiller, Sanchia
ContributorsBishop, Russell, Biochemistry and Biomedical Sciences
Source SetsMcMaster University
LanguageEnglish
Detected LanguageEnglish
TypeThesis

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