Red Light Activates the SigmaB-mediated General Stress Response of Bacillus Subtilis Via the Energy Branch of the Upstream Signaling Cascade

Overview

Journal J Bacteriol

Publisher American Society for Microbiology

Specialty Microbiology

Date 2009 Dec 2

PMID 19948797

Citations 18

Authors

Marcela Avila-Perez

Jeroen B van der Steen

Remco Kort

Klaas J Hellingwerf

Affiliations

Soon will be listed here.

Abstract

The sigma(B)-dependent general stress response in the common soil bacterium Bacillus subtilis can be elicited by a range of stress factors, such as starvation or an ethanol, salt, or heat shock, via a complex upstream signaling cascade. Additionally, sigma(B) can be activated by blue light via the phototropin homologue YtvA, a component of the environmental branch of the signaling cascade. Here we use a reporter-gene fusion to show that sigma(B) can also be activated by red light via the energy branch of its upstream signaling cascade. Deletion mutagenesis and homologous overproduction experiments indicate that the RsbP protein (composed of an N-terminal Per-ARNT-Sim [PAS] domain and a C-terminal PP2C-type phosphatase domain) is involved in the red light response. This second light input pathway functions complementarily to YtvA; it shows broader spectral sensitivity but requires higher light intensities. These results are confirmed by transcriptome analyses, which show that both light effects result in upregulation of the sigma(B) regulon, with minimal activation of other responses.

Citing Articles

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