By combining single-molecule tracking, single-cell protein quantitation, quantitative kinetic analysis, and genetic engineering, the authors have made novel discoveries on how the behavior of a metal-responsive transcription regulator in live bacterial cells challenges two long-standing mechanistic paradigms in regulator-DNA interactions.

Using in vitro generated capped mRNA, the influence of the first transcribed nucleotide and its methylation status on translation was systematically studied. Translation rates were found to depend strongly on the identity of the nucleotide and its methylation, mRNA purity and the immune state of the cell. These findings are of broad interest both in terms of describing potential strategies to improve expression of exogenous proteins (for applications such as gene therapies) while also providing considerable new insights in the mechanisms of regulation of mRNA translation.

This study reports the structure of the WhiB1 bacterial transcription factor bound to the C-terminal domain of the primary sigma factor σA (σA CTD) from M. tuberculosis. This protein, like others in the Wbl protein family, contains a [4Fe-4S] cluster and is widely distributed in actinobacteria. WhiB proteins play versatile roles in diverse biological processes. WhiB1 is of particular interest because it is essential for cell growth, and it is suggested to have a role in the initiation of dormancy in response to nitric oxide (NO). NO is a potent antimicrobial chemical produced by the host to combat tuberculosis infection. Consequently, the transcription factors in the defense system of M. tuberculosis that swiftly sense and respond to NO are critical for the survival and pathogenesis of the bacterium. The reactivity of the [4Fe-4S] cluster in WhiB1 is highly selective for NO over O2, making it a specific NO sensor in aerobic bacteria.