Probing teichoic acid genetics with bioactive molecules reveals new interactions among diverse processes in bacterial cell wall biogenesis.

The bacterial cell wall has been a celebrated target for antibiotics and holds real promise for the discovery of new antibacterial chemical matter. In addition to peptidoglycan, the walls of Gram-positive bacteria contain large amounts of the polymer teichoic acid, covalently attached to peptidoglycan. Recently, wall teichoic acid was shown to be essential to the proper morphology of Bacillus subtilis and an important virulence factor for Staphylococcus aureus.

Pathogenic adaptation of intracellular bacteria by rewiring a cis-regulatory input function.

The acquisition of DNA by horizontal gene transfer enables bacteria to adapt to previously unexploited ecological niches. Although horizontal gene transfer and mutation of protein-coding sequences are well-recognized forms of pathogen evolution, the evolutionary significance of cis-regulatory mutations in creating phenotypic diversity through altered transcriptional outputs is not known. We show the significance of regulatory mutation for pathogen evolution by mapping and then rewiring a cis-regulatory module controlling a gene required for murine typhoid.

Thermosensing coordinates a cis-regulatory module for transcriptional activation of the intracellular virulence system in Salmonella enterica serovar Typhimurium.

The expression of bacterial virulence genes is tightly controlled by the convergence of multiple extracellular signals. As a zoonotic pathogen, virulence gene regulation in Salmonella enterica serovar Typhimurium must be responsive to multiple cues from the general environment as well as from multiple niches within animal and human hosts. Previous work has identified combined magnesium and phosphate limitation as an environmental cue that activates genes required for intracellular virulence.