Dynamics of bacterial operons during genome-wide stresses

Abstract

SUMMARYBacterial gene networks have many operons, each coordinating the kinetics of a few genes in time and strength. InEscherichia coli, nearly half of these operons have internal promoters, which allow regulating the downstream genes, independently from upstream genes. We studied their role during genome-wide stresses targeting a few key elements of the transcription machinery, namely, RNAP and gyrase. We show that absolute differences in response strength between genes in the same operon follow a sinusoidal function of the distance between them. This results from the combined effect of elongation fall-offs and internal promoters. The frequency of this function is regulated by the positioning of internal promoters, while its amplitude differs with the perturbation strength. Moreover, we find that positive supercoiling buildup partially explains the RNAP fall-off rates. Finally, we report similar sinusoidal patterns inE. colicells subject to several other stresses, as well as inBacillus subtilis, Corynebacterium glutamicum, and Helicobacter pylori. Overall, our results suggest that the strength, number, and positioning of internal promoters in operons are influenced by a genome-wide need to compensate for RNAP fall-offs, and thus provide distal genes in the operon with similar response strength as genes proximal to the primary promoter.