Robust Salmonella metabolism limits possibilities for new antimicrobials.

New antibiotics are urgently needed to control infectious diseases. Metabolic enzymes could represent attractive targets for such antibiotics, but in vivo target validation is largely lacking. Here we have obtained in vivo information about over 700 Salmonella enterica enzymes from network analysis of mutant phenotypes, genome comparisons and Salmonella proteomes from infected mice.

Salmonella enterica highly expressed genes are disease specific.

During in vitro broth culture, bacterial gene expression is typically dominated by highly expressed factors involved in protein biosynthesis, maturation, and folding, but it is unclear if this also applies to conditions in natural environments. Here, we used a promoter trap strategy with an unstable green fluorescent protein reporter that can be detected in infected mouse tissues to identify 21 Salmonella enterica promoters with high levels of activity in a mouse enteritis model. We then measured the activities of these and 31 previously identified Salmonella promoters in both the enteritis and a murine typhoid fever model.

Antigen selection based on expression levels during infection facilitates vaccine development for an intracellular pathogen.

Vaccines effective against intracellular pathogens could save the lives of millions of people every year, but vaccine development has been hampered by the slow largely empirical search for protective antigens. In vivo highly expressed antigens might represent a small attractive antigen subset that could be rapidly evaluated, but experimental evidence supporting this rationale, as well as practical strategies for its application, is largely lacking because of technical difficulties. Here, we used Salmonella strains expressing differential amounts of a fluorescent model antigen during infection to show that, in a mouse typhoid fever model, CD4 T cells preferentially recognize abundant Salmonella antigens.

Binding of sigma(A) and sigma(B) to core RNA polymerase after environmental stress in Bacillus subtilis.

In Bacillus subtilis, the alternative sigma factor sigma(B) is activated in response to environmental stress or energy depletion. The general stress regulon under the control of sigma(B) provides the cell with multiple stress resistance. Experiments were designed to determine how activated sigma(B) replaces sigma(A) as a constituent of the RNA polymerase holoenzyme.