Synopsis

An experimental-computational approach is applied to dissect the contribution of specific transcription factor-mediated versus global growth-dependent regulation to bacterial gene expression, and obtain a quantitative understanding of dynamic adaptations in arginine biosynthesis of E. coli.

• We present a model-based approach to quantitatively dissect simultaneous contributions from specific transcription factors and the global growth status to bacterial gene expression, based on parameter inference from GFP-based promoter activity measurements.
• We show that growth rate can be used to predict the unregulated expression baseline of a gene, since growth rate dependence of global regulation occurs both in steady state and during transient changes in growth rate.
• We obtain a quantitative understanding of both specific and global regulation in arginine biosynthesis, as demonstrated by accurate model-based predictions of complex transient gene-expression responses to simultaneous perturbation in growth rate and arginine availability.
• We uncover two principles of joint regulation of the arginine biosynthesis pathway: (i) specific regulation by repression dominates in steady metabolic states and (ii) global regulation sets the maximal expression reachable during transition between steady metabolic states.