A PhoP/PhoQ-induced Lipase (PagL) that catalyzes 3-O-deacylation of lipid A precursors in membranes of Salmonella typhimurium

Pathogenic bacteria modify the structure of the lipid A portion of their lipopolysaccharide in response to environmental changes. Some lipid A modifications are important for virulence and resistance to cationic antimicrobial peptides. The two-component system PhoP/PhoQ plays a central role in regulating lipid A modification. We now report the discovery of a PhoP/PhoQ-activated gene (pagL) in Salmonella typhimurium, encoding a deacylase that removes the R-3-hydroxymyristate moiety attached at position 3 of certain lipid A precursors. The deacylase gene (pagL) was identified by assaying for loss of deacylase activity in extracts of 14 random TnphoA::pag insertion mutants. The pagL gene encodes a protein of 185 amino acid residues unique to S. typhimurium and closely related organisms such as Salmonella typhi. Heterologous expression of pagL in Escherichia coli on plasmid pWLP21 results in loss of the R-3-hydroxymyristate moiety at position 3 in approximately 90% of the lipid A molecules but does not inhibit cell growth. PagL is synthesized with a 20-amino acid N-terminal signal peptide and is localized mainly in the outer membrane, as judged by assays of separated S. typhimurium membranes and by SDS-polyacrylamide gel analysis of membranes from E. coli cells that overexpress PagL. The function of PagL is unknown, given that S. typhimurium mutants lacking pagL display no obvious phenotypes, but PagL might nevertheless play a role in pathogenesis if it serves to modulate the cytokine response of an infected animal host.     

Novel persistence genes in Pseudomonas aeruginosa identified by high-throughput screening

Salmonella enterica polymyxin B (PM) resistance is modulated mainly by substitutions of the acyl chains and the phosphate groups on the lipid A moiety of lipopolysaccharide. These modifications are mediated by genes under the control of the PmrA/PmrB and PhoP/PhoQ two-component regulatory systems. In this study, a deletion in the gene encoding the alternative σ⁵⁴ factor, rpoN , was shown to increase PM resistance without affecting protamine sensitivity. The results presented here showed that the increased polymyxin resistance observed in the Δ rpoN mutant occurs through a PmrA/PhoP-independent pathway. Downregulation of one or more genes belonging to the RpoN regulon may provide an additional mechanism of defence against membrane-permeabilizing antimicrobial peptides that helps the pathogen to survive in different environments.     

Lipid A modifications in polymyxin-resistant Salmonella typhimurium: PMRA-dependent 4-amino-4-deoxy-L-arabinose, and phosphoethanolamine incorporation

Lipid A of Salmonella typhimurium can be resolved into multiple molecular species. Many of these substances are more polar than the predominant hexa-acylated lipid A 1,4'-bisphosphate of Escherichia coli K-12. By using new isolation methods, we have purified six lipid A subtypes (St1 to St6) from wild type S. typhimurium. We demonstrate that these lipid A variants are covalently modified with one or two 4-amino-4-deoxy-l-arabinose (l-Ara4N) moieties. Each lipid A species with a defined set of polar modifications can be further derivatized with a palmitoyl moiety and/or a 2-hydroxymyristoyl residue in place of the secondary myristoyl chain at position 3'. The unexpected finding that St5 and St6 contain two l-Ara4N residues accounts for the anomalous structures of lipid A precursors seen in S. typhimurium mutants defective in 3-deoxy-d-manno-octulosonic acid biosynthesis in which only the 1-phosphate group is modified with the l-Ara4N moiety (Strain, S. M., Armitage, I. M., Anderson, L., Takayama, K., Quershi, N., and Raetz, C. R. H. (1985) J. Biol. Chem. 260, 16089-16098). Phosphoethanolamine (pEtN)-modified lipid A species are much less abundant than l-Ara4N containing forms in wild type S. typhimurium grown in broth but accumulate to high levels when l-Ara4N synthesis is blocked in pmrA(C)pmrE(-) and pmrA(C)pmrF(-) mutants. Purification and analysis of selected compounds demonstrate that one or two pEtN moieties may be present. Our findings show that S. typhimurium contains versatile enzymes capable of modifying both the 1- and 4'-phosphates of lipid A with l-Ara4N and/or pEtN groups. PmrA null mutants of S. typhimurium produce lipid A species without any pEtN or l-Ara4N substituents. However, PmrA is not needed for the incorporation of 2-hydroxymyristate or palmitate.     

Insights into the structure of the PmrD protein with molecular dynamics simulations

Resistance to cationic antimicrobial peptide polymyxin B from Gram-negative bacteria is accomplished by two-component systems (TCSs), protein complexes PmrA/PmrB and PhoP/PhoQ. PmrD is the first protein identified to mediate the connectivity between two TCSs. The 3D structure of PmrD has been recently solved by NMR and its unique fold was revealed. Here, a molecular dynamics study is presented started from the NMR structure. Numerous hydrophobic and electrostatic interactions were identified to contribute to PmrD's 3D stability. Moreover, the mobility of the five loops that connect the protein's six β-strands has been explored. Solvent-accessible surface area calculation revealed that a Leucine-rich hydrophobic cluster of the protein stabilized the protein's structure.     

PmrA–PmrB-regulated genes necessary for 4-aminoarabinose lipid A modification and polymyxin resistance

Antimicrobial peptides are distributed throughout the animal kingdom and are a key component of innate immunity. Salmonella typhimurium regulates mechanisms of resistance to cationic antimicrobial peptides through the two-component systems PhoP–PhoQ and PmrA–PmrB. Polymyxin resistance is encoded by the PmrA–PmrB regulon, whose products modify the lipopolysaccharide (LPS) core and lipid A regions with ethanolamine and add aminoarabinose to the 4' phosphate of lipid A. Two PmrA–PmrB-regulated S . typhimurium loci ( pmrE and pmrF ) have been identified that are necessary for resistance to polymyxin and for the addition of aminoarabinose to lipid A. One locus, pmrE , contains a single gene previously identified as pagA (or ugd ) that is predicted to encode a UDP-glucose dehydrogenase. The second locus, pmrF , is the second gene of a putative operon predicted to encode seven proteins, some with similarity to glycosyltransferases and other complex carbohydrate biosynthetic enzymes. Genes immediately flanking this putative operon are also regulated by PmrA–PmrB and/or have been associated with S . typhimurium polymyxin resistance. This work represents the first identification of non-regulatory genes necessary for modification of lipid A and subsequent antimicrobial peptide resistance, and provides support for the hypothesis that lipid A aminoarabinose modification promotes resistance to cationic antimicrobial peptides.     

Quantitative proteomic analysis of Salmonella enterica serovar Typhimurium under PhoP/PhoQ activation conditions

The PhoP/PhoQ two-component system plays a central regulatory role in the pathogenesis of Salmonella enterica serovar Typhimurium (S. Typhimurium), and it can be activated by low Mg(2+) concentrations and sublethal concentrations of cationic antimicrobial peptides (CAMP). Therefore, these two PhoP/PhoQ activation signals are considered as in vivo environmental cues sensed by S. Typhimurium for adaptation and survival. In this work, we conducted a SILAC (stable isotope labeling by amino acids in cell culture)-based quantitative proteomic study to survey the proteomic changes of S. Typhimurium in response to low Mg(2+) concentrations or CAMP. We discovered that CAMP activated a portion of the PhoP/PhoQ regulatory network, whereas low Mg(2+) concentrations upregulated nearly all known members of this network, a number of previously unknown proteins, and some proteins regulated by IHF and RpoS. Systematic analysis following metabolic pathways revealed that low Mg(2+) concentrations selectively influenced proteins of certain metabolic functions while CAMP did not. Our study indicates that the low Mg(2+)-concentration condition may lead S. Typhimurium into a growth-control lifestyle, which provides new perspectives about Salmonella's adaptation to the host environment.     

The PhoP/PhoQ system and its role in Serratia marcescens pathogenesis

Serratia marcescens is able to invade, persist, and multiply inside nonphagocytic cells, residing in nonacidic, nondegradative, autophagosome-like vacuoles. In this work, we have examined the physiological role of the PhoP/PhoQ system and its function in the control of critical virulence phenotypes in S. marcescens. We have demonstrated the involvement of the PhoP/PhoQ system in the adaptation of this bacterium to growth on scarce environmental Mg(2+), at acidic pH, and in the presence of polymyxin B. We have also shown that these environmental conditions constitute signals that activate the PhoP/PhoQ system. We have found that the two S. marcescens mgtE orthologs present a conserved PhoP-binding motif and demonstrated that mgtE1 expression is PhoP dependent, reinforcing the importance of PhoP control in magnesium homeostasis. Finally, we have demonstrated that phoP expression is activated intracellularly and that a phoP mutant strain is defective in survival inside epithelial cells. We have shown that the Serratia PhoP/PhoQ system is involved in prevention of the delivery to degradative/acidic compartments.     

The phosphatase activity is the target for Mg2+ regulation of the sensor protein PhoQ in Salmonella

The PhoP/PhoQ two-component system controls the expression of essential virulence traits in the pathogenic bacterium Salmonella enterica serovar Typhimurium. Environmental deprivation of Mg(2+) activates the PhoP/PhoQ signal transduction cascade, which results in an increased expression of genes necessary for survival inside the host. It was previously demonstrated that the interaction of Mg(2+) with the periplasmic domain of PhoQ promotes a conformational change in the sensor protein that leads to the down-regulation of PhoP-activated genes. We have now examined the regulatory effect of Mg(2+) on the putative activities of the membrane-bound PhoQ. We demonstrated that Mg(2+) promotes a phospho-PhoP phosphatase activity in the sensor protein. This activity depends on the intactness of the conserved His-277, suggesting that the phosphatase active site overlaps the H box. The integrity of the N-terminal domain of PhoQ was essential for the induction of the phosphatase activity, because Mg(2+) did not stimulate the release of inorganic phosphate from phospho-PhoP in a fusion protein that lacks this sensing domain. These findings reveal that the sensor PhoQ harbors a phospho-PhoP phosphatase activity, and that this phosphatase activity is the target of the extracellular Mg(2+)-triggered regulation of the PhoP/PhoQ system.