Abstract
Haemophilus influenzae is a host adapted human mucosal pathogen involved in a variety of acute and chronic respiratory tract infections, including chronic obstructive pulmonary disease and asthma, all of which rely on its ability to efficiently establish continuing interactions with the host. Here we report the characterization of a novel molybdenum enzyme, TorZ/MtsZ that supports interactions of H. influenzae with host cells during growth in oxygen-limited environments. Strains lacking TorZ/MtsZ showed a reduced ability to survive in contact with epithelial cells as shown by immunofluorescence microscopy and adherence/invasion assays. This included a reduction in the ability of the strain to invade human epithelial cells, a trait that could be linked to the persistence of H. influenzae. The observation that in a murine model of H. influenzae infection, strains lacking TorZ/MtsZ were almost undetectable after 72 h of infection, while ∼3.6 × 103 CFU/mL of the wild type strain were measured under the same conditions is consistent with this view. To understand how TorZ/MtsZ mediates this effect we purified and characterized the enzyme, and were able to show that it is an S- and N-oxide reductase with a stereospecificity for S-sulfoxides. The enzyme converts two physiologically relevant sulfoxides, biotin sulfoxide and methionine sulfoxide (MetSO), with the kinetic parameters suggesting that MetSO is the natural substrate of this enzyme. TorZ/MtsZ was unable to repair sulfoxides in oxidized Calmodulin, suggesting that a role in cell metabolism/energy generation and not protein repair is the key function of this enzyme. Phylogenetic analyses showed that H. influenzae TorZ/MtsZ is only distantly related to the Escherichia coli TorZ TMAO reductase, but instead is a representative of a new, previously uncharacterized clade of molybdenum enzyme that is widely distributed within the Pasteurellaceae family of pathogenic bacteria. It is likely that MtsZ/TorZ has a similar role in supporting host/pathogen interactions in other members of the Pasteurellaceae, which includes both human and animal pathogens.
Highlights
An emerging aspect of bacterial pathogenesis that is receiving increased attention is the role of metabolic interactions between the host and pathogen (Rhee et al, 2011; Bliska and Van Der Velden, 2012; Grubmüller et al, 2014; Heroven and Dersch, 2014; Hofreuter, 2014; Othman et al, 2014)
Haemophilus influenzae is known for its high genetic variability, our analyses showed that the torYZ operon is conserved in 65/80 (81%) of the available complete and partial genomes of HI strains, in some cases one of the two genes was annotated as a pseudogene (Supplementary Table S1), possibly due to sequencing errors
Group 2A contained sequences from Yersinia sp., Serratia sp., Enterobacter sp., Photobacterium and Aeromonas sp., while Group 2B was dominated by sequences originating from various species of Pasteurellaceae, including HI, and in addition contained some sequences from Campylobacter sp. and Helicobacter sp. These data clearly indicate that HITorZ protein is a unique protein within the Dor/Tor-type enzymes of the dimethyl sulfoxide (DMSO) reductase family, and based on its apparent preference for methionine sulfoxide (MetSO) as a substrate we propose that the HITorY and TorZ proteins be renamed to MtsY and MtsZ (Mts, Methioninesulfoxide) to clearly distinguish them from the E. coli TorY and TorZ
Summary
An emerging aspect of bacterial pathogenesis that is receiving increased attention is the role of metabolic interactions between the host and pathogen (Rhee et al, 2011; Bliska and Van Der Velden, 2012; Grubmüller et al, 2014; Heroven and Dersch, 2014; Hofreuter, 2014; Othman et al, 2014). Our previous analyses indicated that strain- as well as niche-specific factors including varying oxygen tension influence the metabolite profile of HI strains and alter gene expression profiles, especially in genes involved in central carbon metabolism and the respiratory chain (Othman et al, 2014) These results suggested that the energy generation processes in HI provide the adaptability required for specific niches, e.g., during infection of the middle-ear or in biofilms, which would be mostly anaerobic, or for colonization of the more aerobic environment of the nasopharynx and respiratory tract, while specific, strain related adaptations may confer the ability to cause disease in these particular body niches
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