Growth-rate dependent partitioning of RNA polymerases in bacteria

TL;DR

This paper presents a physical model of RNA polymerase partitioning in bacteria, linking growth rate to gene expression regulation and allowing predictions of promoter activity changes without extra parameters.

Contribution

The study introduces a quantitative model of RNAP partitioning that explains growth-rate dependent gene expression and can interpret mutant and stress response data.

Findings

Model accurately predicts RNAP distribution at different growth rates.

Disentangles effects of free RNAP concentration from promoter regulation.

Explains gene expression changes during amino acid starvation.

Abstract

Physiological changes which result in changes in bacterial gene expression are often accompanied by changes in the growth rate for fast adapting enteric bacteria. Since the availability of RNA polymerase (RNAP) in cells is dependent on the growth rate, transcriptional control involves not only the regulation of promoters, but also depends on the available (or free) RNAP concentration which is difficult to quantify directly. Here we develop a simple physical model describing the partitioning of cellular RNAP into different classes: RNAPs transcribing mRNA and ribosomal RNA (rRNA), RNAPs non-specifically bound to DNA, free RNAP, and immature RNAP. Available experimental data for E. coli allow us to determine the two unknown parameters of the model and hence deduce the free RNAP concentration at different growth rates. The results allow us to predict the growth-rate dependence of the activities of constitutive (unregulated) promoters, and to disentangle the growth-rate dependent regulation of promoters (e.g., the promoters of rRNA operons) from changes in transcription due to changes in the free RNAP concentration at different growth rates. Our model can quantitatively account for the observed changes in gene expression patterns in mutant E. coli strains with altered levels of RNAP expression without invoking additional parameters. Applying our model to the case of the stringent response following amino acid starvation, we can evaluate the plausibility of various scenarios of passive transcriptional control proposed to account for the observed changes in the expression of rRNA and biosynthetic operons.