Abstract

BackgroundAmong the seven different sigma factors in E. coli σ70 has the highest concentration and affinity for the core RNA polymerase. The E. coli protein Rsd is regarded as an anti-sigma factor, inhibiting σ70-dependent transcription at the onset of stationary growth. Although binding of Rsd to σ70 has been shown and numerous structural studies on Rsd have been performed the detailed mechanism of action is still unknown.Methodology/Principal FindingsWe have performed studies to unravel the function and regulation of Rsd expression in vitro and in vivo. Cross-linking and affinity binding revealed that Rsd is able to interact with σ70, with the core enzyme of RNA polymerase and is able to form dimers in solution. Unexpectedly, we find that Rsd does also interact with σ38, the stationary phase-specific sigma factor. This interaction was further corroborated by gel retardation and footprinting studies with different promoter fragments and σ38- or σ70-containing RNA polymerase in presence of Rsd. Under competitive in vitro transcription conditions, in presence of both sigma factors, a selective inhibition of σ70-dependent transcription was prevailing, however. Analysis of rsd expression revealed that the nucleoid-associated proteins H-NS and FIS, StpA and LRP bind to the regulatory region of the rsd promoters. Furthermore, the major promoter P2 was shown to be down-regulated in vivo by RpoS, the stationary phase-specific sigma factor and the transcription factor DksA, while induction of the stringent control enhanced rsd promoter activity. Most notably, the dam-dependent methylation of a cluster of GATC sites turned out to be important for efficient rsd transcription.Conclusions/SignificanceThe results contribute to a better understanding of the intricate mechanism of Rsd-mediated sigma factor specificity changes during stationary phase.

Highlights

  • Reprogramming the specificity of transcription during the change from exponential to stationary growth or under conditions of environmental stress is an essential feature of bacterial physiology

  • The shift to stationary growth conditions is regulated by a complex network of cellular responses to reduce the wasteful transcription of genes related to growth in favour to the expression of stationary phase-specific genes

  • The results indicate that Rsd interferes with the ability of Es70 RNA polymerase holoenzyme to form complexes with the rrnB P1 promoter, in vitro

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Summary

Introduction

Reprogramming the specificity of transcription during the change from exponential to stationary growth or under conditions of environmental stress is an essential feature of bacterial physiology. Polymerase bound to the bolA P1 promoter DNA in presence and absence of Rsd. In the absence of Rsd increasing amounts of the Es38 RNA polymerase holoenzyme resulted in a clear footprint on both DNA strands between nucleotide positions +30 and 260, relative to the bolA P1 transcription start, largely consistent with previous studies [36] (Figure 3a and b, lanes 2 to 5).

Results
Conclusion

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