Escherichia coli limits Salmonella Typhimurium infections after diet shifts and fat-mediated microbiota perturbation in mice.

The microbiota confers colonization resistance, which blocks Salmonella gut colonization. As diet affects microbiota composition, we studied whether food composition shifts enhance susceptibility to infection. Shifting mice to diets with reduced fibre or elevated fat content for 24 h boosted Salmonella Typhimurium or Escherichia coli gut colonization and plasmid transfer.

Inflammation boosts bacteriophage transfer between spp.

Bacteriophage transfer (lysogenic conversion) promotes bacterial virulence evolution. There is limited understanding of the factors that determine lysogenic conversion dynamics within infected hosts. A murine Typhimurium (Tm) diarrhea model was used to study the transfer of SopEΦ, a prophage from Tm SL1344, to Tm ATCC14028S.

Analysis of bacterial-surface-specific antibodies in body fluids using bacterial flow cytometry.

Antibacterial antibody responses that target surfaces of live bacteria or secreted toxins are likely to be relevant in controlling bacterial pathogenesis. The ability to specifically quantify bacterial-surface-binding antibodies is therefore highly attractive as a quantitative correlate of immune protection. Here, binding of antibodies from various body fluids to pure-cultured live bacteria is made visible with fluorophore-conjugated secondary antibodies and measured by flow cytometry.

Peracetic Acid Treatment Generates Potent Inactivated Oral Vaccines from a Broad Range of Culturable Bacterial Species.

Our mucosal surfaces are the main sites of non-vector-borne pathogen entry, as well as the main interface with our commensal microbiota. We are still only beginning to understand how mucosal adaptive immunity interacts with commensal and pathogenic microbes to influence factors such as infectivity, phenotypic diversity, and within-host evolution. This is in part due to difficulties in generating specific mucosal adaptive immune responses without disrupting the mucosal microbial ecosystem itself.

IL-17 regulates systemic fungal immunity by controlling the functional competence of NK cells.

Interleukin 17 (IL-17)-mediated immunity plays a key role in protection from fungal infections in mice and man. Here, we confirmed that mice deficient in the IL-17 receptor or lacking the ability to secrete IL-17 are highly susceptible to systemic candidiasis, but we found that temporary blockade of the IL-17 pathway during infection in wild-type mice did not impact fungal control. Rather, mice lacking IL-17 receptor signaling had a cell-intrinsic impairment in the development of functional NK cells, which accounted for the susceptibility of these mice to systemic fungal infection.