AhR sensing of bacterial pigments regulates antibacterial defence.

The aryl hydrocarbon receptor (AhR) is a highly conserved ligand-dependent transcription factor that senses environmental toxins and endogenous ligands, thereby inducing detoxifying enzymes and modulating immune cell differentiation and responses. We hypothesized that AhR evolved to sense not only environmental pollutants but also microbial insults. We characterized bacterial pigmented virulence factors, namely the phenazines from Pseudomonas aeruginosa and the naphthoquinone phthiocol from Mycobacterium tuberculosis, as ligands of AhR. Upon ligand binding, AhR activation leads to virulence factor degradation and regulated cytokine and chemokine production. The relevance of AhR to host defence is underlined by heightened susceptibility of AhR-deficient mice to both P. aeruginosa and M. tuberculosis. Thus, we demonstrate that AhR senses distinct bacterial virulence factors and controls antibacterial responses, supporting a previously unidentified role for AhR as an intracellular pattern recognition receptor, and identify bacterial pigments as a new class of pathogen-associated molecular patterns.

A sophisticated multi-step secretion mechanism: how the type 3 secretion system is regulated.

Many Gram-negative pathogens utilize type 3 secretion systems (T3SSs) for a successful infection. The T3SS is a large macromolecular complex which spans both bacterial membranes and delivers effector proteins into the host cell. The infection requires spatiotemporal control of diverse sets of secreted effectors and various mechanisms have evolved to regulate T3SS in response to external stimuli. This review will describe mechanisms that may control type 3 secretion, revealing a multi-step regulatory strategy. We then propose an updated model of T3SS that illustrates different stages of secretion and integrates the most recent structural and functional data.

Protein HP1028 from the human pathogen Helicobacter pylori belongs to the lipocalin family.

Helicobacter pylori is a bacterial pathogen that causes severe diseases, including gastritis, ulcers and gastric cancer. Although this bacterium has been extensively studied, the physiological functions of a large number of the proteins encoded by its genome are unknown. HP1028 is a protein that is relevant to colonization and to the survival of the bacterium in the stomach, but its function is not clearly understood. Bioinformatics studies suggest that HP1028 is a monomeric protein that is secreted in the H. pylori periplasm. The crystal structure of HP1028 has been determined at 2.6 Šresolution using the SAD method. The three-dimensional structure of the protein reveals that it belongs to the lipocalin family, a group of proteins that bind and transport (often hydrophobic) small molecules. The structure of HP1028, together with the possible localization of the mature protein in the bacterial periplasm and the position of the hp1028 gene in the bacterial genome, point to a role in H. pylori chemotaxis.

Interaction of MxiG with the cytosolic complex of the type III secretion system controls Shigella virulence.

Gram-negative bacteria use the type 3 secretion system (T3SS) to colonize host cells. T3SSs are ring-shaped macromolecular complexes specific for the transport of effector molecules into host cells. It was recently suggested that a cytosolic ring-shaped protein complex delivers effector molecules to the T3SS. However, how transport of effector proteins is regulated is not known. Here, we report the high-resolution X-ray crystal structure of the whole cytosolic domain of MxiG (MxiG(1-126)), a major component of the inner T3SS rings in Shigella flexneri. MxiG(1-126) folds as an FHA domain, which specifically binds phosphorylated threonines. Indeed, MxiG(1-126) binds to Spa33, a cytoplasmic-ring component of Shigella, as revealed in pulldown studies. Surface plasmon resonance analysis showed specific interaction of MxiG with a Spa33 peptide only if phosphorylated. In total, 24 copies of the MxiG(1-126) crystal structure were fitted into the cryo-EM map of the Shigella T3SS. The phosphoprotein binding site of each MxiG molecule faces the channel of the T3SS, allowing interaction with cytosolic binding partners. Secretion assays and host cell invasion studies of complemented Shigella knockout cells indicated that the phosphoprotein binding of MxiG is essential for bacterial virulence. Our findings suggest that MxiG is involved in T3SS regulation.

The Helicobacter pylori CagD (HP0545, Cag24) protein is essential for CagA translocation and maximal induction of interleukin-8 secretion.

Pathogenic strains of Helicobacter pylori use a type IV secretion system (T4SS) to deliver the toxin CagA into human host cells. The T4SS, along with the toxin itself, is coded into a genomic insert, which is termed the cag pathogenicity island. The cag pathogenicity island contains about 30 open-reading frames, for most of which the exact function is not well characterized or totally unknown. We have determined the crystal structure of one of the proteins coded by the cag genes, CagD, in two crystal forms. We show that the protein is a covalent dimer in which each monomer folds as a single domain that is composed of five beta-strands and three alpha-helices. Our data show that in addition to a cytosolic pool, CagD partially associates with the inner membrane, where it may be exposed to the periplasmic space. Furthermore, CagA tyrosine phosphorylation and interleukin-8 assays identified CagD as a crucial component of the T4SS that is involved in CagA translocation into host epithelial cells; however, it does not seem absolutely necessary for pilus assembly. We have also identified significant amounts of CagD in culture supernatants, which are not a result of general bacterial lysis. Since this localization was independent of the various tested cag mutants, our findings may indicate that CagD is released into the supernatant during host cell infection and then binds to the host cell surface or is incorporated in the pilus structure. Overall, our results suggest that CagD may serve as a unique multifunctional component of the T4SS that may be involved in CagA secretion at the inner membrane and may localize outside the bacteria to promote additional effects on the host cell.

Structural and mutational analysis of TenA protein (HP1287) from the Helicobacter pylori thiamin salvage pathway - evidence of a different substrate specificity.

HP1287 (tenA) from Helicobacter pylori is included among the genes that play a relevant role in bacterium colonization and persistence. The gene has been cloned and its product, protein TenA, has been expressed and purified. The crystal structures of the wild-type protein and the mutant F47Y have been determined at resolutions of 2.7 and 2.4 A, respectively. The molecular model, a homotetramer with 222 symmetry, shows that the H. pylori TenA structure belongs to the thiaminase II class of proteins. These enzymes were recently found to be involved in a salvage pathway for the synthesis of the thiamin precursor hydroxypyrimidine, which constitutes a building block in thiamin biosynthesis, in particular in bacteria living in the soil. By contrast, enzymatic measurements on TenA from H. pylori indicate that the activity on the putative substrate 4-amino-5-aminomethyl-2-methylpyrimidine is very modest. Moreover, in the present study, we demonstrate that the mutation at residue 47, a position where a phenylalanine occurs in all the strains of H. pylori sequenced to date, is not sufficient to explain the very low catalytic activity toward the expected substrate. As a result of differences in the colonization environment of H. pylori as well as the TenA structural and catalytic peculiar features, we suggest a possible pivotal role for the H. pylori enzyme in the thiamin biosynthetic route, which is in agreement with the relevance of this protein in the stomach colonization process.