Browsing by Subject "Helicobacter pylori"
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Item Membrane remodeling in epsilon proteobacteria and its impact on pathogenesis(2012-05) Cullen, Thomas Wilson; Trent, Michael Stephen; Whiteley, Marvin; Harshey, Rasika M.; Stevens, Scott W.; O'Halloran, Terry J.Bacterial pathogens assemble complex surface structures in an attempt to circumvent host immune detection. A great example is the glycolipid known as lipopolysaccharide or lipooligosaccharide (LPS), the major surface molecule in nearly all gram-negative organisms. LPS is anchored to the bacterial cell surface by a anionic hydrophobic lipid known as lipid A, the major agonist of the mammalian TLR4-MD2 receptor and likely target for cationic antimicrobial peptides (CAMPs) secreted by host cells (i.e. defensins). In this work we investigate LPS modification machinery in related ε-proteobacteria, Helicobacter pylori and Campylobacter jejuni, two important human pathogens, and demonstrate that enzymes involved in LPS modification not only play a role in evasion of host defenses but also an unexpected role in bacterial locomotion. More specifically, we identify the enzyme responsible for 4'-dephosphorylation of H. pylori lipid A, LpxF. Demonstrating that lipid A depohsphorylation at the 1 and 4'-positions by LpxE and LpxF, respectively, are the primary mechanisms used by H. pylori for CAMP resistance, contribute to attenuated TRL4-MD2 activation and are required for colonization of a the gastric mucosa in murine host. Similarly in C. jejuni, we identify an enzyme, EptC, responsible for modification of lipid A at both the 1 and 4'-positions with phosphoethanolamine (pEtN), also required for CAMP resistance in this organism. Suprisingly, EptC was found to serve a dual role in modifying not only lipid A with pEtN but also the flagellar rod protein FlgG at residue Thr75, required for motility and efficient flagella production. This work links membrane biogenesis with flagella assembly, both shown to be required for colonization of a host and adds to a growing list of post-translational modifications found in prokaryotes. Understanding how pathogens evade immune detection, interphase with the surrounding environment and assemble major surface features is key in the development of novel treatments and vaccines.Item Unexpected biochemistry determines endotoxin structure in two enteric gram-negatives(2015-05) Di Pierro, Erica Jacqueline; Trent, Michael Stephen; Davies, Bryan W; Ehrlich, Lauren; Maynard, Jennifer; Payne, ShelleyMost gram-negative organisms require lipopolysaccharide and its membrane anchor, lipid A, for growth and survival. Also known as endotoxin, lipid A is synthesized via a nine-step enzymatic process, culminating in a conserved hexa-acylated, bis-phosphorylated disaccharide of glucosamine. This framework is often altered by condition- or species-specific lipid A modifications, which change the biochemical properties of the molecule in response to and to defend against environmental stress signals. Here, we expound on two stories in different gram-negative organisms, both involving novel or unanticipated biochemistry that impacts lipid A structure. First, the missing acyltransferase in the Epsilonproteobacterium Helicobacter pylori lipid A biosynthesis pathway is identified. This enzyme transfers a secondary acyl chain to the 3'-linked primary acyl chain of lipid A like E. coli LpxM, but shares almost no sequence similarity with the E. coli acyltransferase. It is reannotated as LpxJ and demonstrated to possess an unprecedented ability to act before the 2'-secondary acyltransferase, LpxL, as well as the 3-deoxy-D-manno-octulosonic acid transferase, KdtA. LpxJ is one member of a large class of acyltransferases found in a diverse range of organisms that lack an E. coli LpxM homolog, suggesting that LpxJ participates in lipid A biosynthesis in place of an LpxM homolog. The second story focuses on regulation of modifications to endotoxin structure that occur after the conserved biosynthesis pathway. E. coli pmrD is shown to be required for PmrAB-dependent lipid A modifications in conditions that exclusively activate PhoPQ; this result proves that PmrD connects PhoPQ and PmrAB despite previous reports that it is an inactive connector in this organism. Further, RNA sequencing and polymyxin B survival assays solidify the role of E. coli pmrD in influencing expression of pmrA and its target genes and promoting survival during exposure to cationic antimicrobial peptides. Notably, the presence of an unknown factor or system capable of activating pmrD to promote lipid A modification in the absence of the PhoPQ system is also revealed. In all, the findings presented here expand our understanding of alternative approaches to lipid A biosynthesis and the complex systems that regulate modifications of this dynamic molecule.