A DNA damage response in
            <i>Escherichia coli</i>
            involving the alternative sigma factor, RpoS

Merrikh, Houra; Ferrazzoli, Alexander E.; Bougdour, Alexandre; Olivier-Mason, Anique; Lovett, Susan T.

doi:10.1073/pnas.0803665106

Cited by 81 publications

(87 citation statements)

References 37 publications

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“…IraP and IraD are normally present in the cell at low levels; their synthesis increases enough to stabilize RpoS only under specific stress conditions (2,4,18). The fact that IraP and IraD stabilize RpoS in an aceE::kan mutant suggests that their expression is induced in this background.…”

Section: Rpos Stabilization In the Acee Mutant Is Dependent Upon Indumentioning

confidence: 99%

“…IraM, induced via activation of the PhoQ/PhoP two-component system, is similarly critical for RpoS stabilization during low Mg 2+ growth (2). IraD induction is not fully understood, but it clearly plays a role both in the transition to stationary phase, via induction of a ppGpp-dependent promoter, and after DNA damage (4,5). IraM and IraD are also negatively regulated by H-NS (6).…”

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confidence: 99%

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Stress sigma factor RpoS degradation and translation are sensitive to the state of central metabolism

Battesti

Majdalani

Gottesman

2015

Proc. Natl. Acad. Sci. U.S.A.

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RpoS, the stationary phase/stress sigma factor of Escherichia coli, regulates a large cohort of genes important for the cell to deal with suboptimal conditions. Its level increases quickly in the cell in response to many stresses and returns to low levels when growth resumes. Increased RpoS results from increased translation and decreased RpoS degradation. Translation is positively regulated by small RNAs (sRNAs). Protein stability is positively regulated by anti-adaptors, which prevent the RssB adaptor-mediated degradation of RpoS by the ClpXP protease. Inactivation of aceE, a subunit of pyruvate dehydrogenase (PDH), was found to increase levels of RpoS by affecting both translation and protein degradation. The stabilization of RpoS in aceE mutants is dependent on increased transcription and translation of IraP and IraD, two known antiadaptors. The aceE mutation also leads to a significant increase in rpoS translation. The sRNAs known to positively regulate RpoS are not responsible for the increased translation; sequences around the start codon are sufficient for the induction of translation. PDH synthesizes acetyl-CoA; acetate supplementation allows the cell to synthesize acetyl-CoA by an alternative, less favored pathway, in part dependent upon RpoS. Acetate addition suppressed the effects of the aceE mutant on induction of the antiadaptors, RpoS stabilization, and rpoS translation. Thus, the bacterial cell responds to lowered levels of acetyl-CoA by inducing RpoS, allowing reprogramming of E. coli metabolism.RssB | ClpXP | acetyl CoA | RpoS | pyruvate dehydrogenase

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Section: Rpos Stabilization In the Acee Mutant Is Dependent Upon Indumentioning

confidence: 99%

mentioning

confidence: 99%

Stress sigma factor RpoS degradation and translation are sensitive to the state of central metabolism

Battesti

Majdalani

Gottesman

2015

Proc. Natl. Acad. Sci. U.S.A.

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“…Accordingly, we conclude that phosphorylation of SprE is not integral to the carbon starvation signaling pathway that regulates RpoS. SprE was recently found to regulate mRNA stability (Carabetta et al 2009), and it is not known if phosphorylation plays a role in that activity.In response to other stresses, such as phosphate starvation, magnesium starvation, and DNA damage, a major mechanism for RpoS accumulation is antagonism of the adaptor SprE by the anti-adaptor proteins IraP, IraM, and IraD, respectively (Bougdour et al 2006(Bougdour et al , 2008Merrikh et al 2009). However, none of the Ira proteins have been associated with carbon starvation, and despite extensive screens, no other proteins have been identified in the carbon starvation signaling pathway.…”

mentioning

confidence: 99%

“…In response to other stresses, such as phosphate starvation, magnesium starvation, and DNA damage, a major mechanism for RpoS accumulation is antagonism of the adaptor SprE by the anti-adaptor proteins IraP, IraM, and IraD, respectively (Bougdour et al 2006(Bougdour et al , 2008Merrikh et al 2009). However, none of the Ira proteins have been associated with carbon starvation, and despite extensive screens, no other proteins have been identified in the carbon starvation signaling pathway.…”

mentioning

confidence: 99%

RpoS proteolysis is controlled directly by ATP levels in Escherichia coli

Peterson¹,

Levchenko²,

Rabinowitz³

et al. 2012

Genes Dev.

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The master regulator of stationary phase in Escherichia coli, RpoS, responds to carbon availability through changes in stability, but the individual steps in the pathway are unknown. Here we systematically block key steps of glycolysis and the citric acid cycle and monitor the effect on RpoS degradation in vivo. Nutrient upshifts trigger RpoS degradation independently of protein synthesis by activating metabolic pathways that generate small energy molecules. Using metabolic mutants and inhibitors, we show that ATP, but not GTP or NADH, is necessary for RpoS degradation. In vitro reconstitution assays directly demonstrate that ClpXP fails to degrade RpoS, but not other proteins, at low ATP hydrolysis rates. These data suggest that cellular ATP levels directly control RpoS stability.Supplemental material is available for this article.Received November 17, 2011; revised version accepted February 9, 2012. RpoS, also known as s S or s 38 , is an alternate s factor that serves as the master regulator of stationary phase and the general stress response in many proteobacteria (Loewen and Hengge-Aronis 1994;Dong and Schellhorn 2009). In Escherichia coli, it has been reported to control transcription of up to 10% of the genome (Weber et al. 2005) and is necessary for survival in numerous environments (McCann et al. 1991). In healthy growing cells, RpoS is still produced but is immediately directed by the adaptor protein SprE (RssB) to the AAA + ATPase ClpXP protease for unfolding and degradation (Muffler et al. 1996;Pratt and Silhavy 1996;Baker and Sauer 2012). When carbon sources are depleted, RpoS proteolysis ceases, causing it to rapidly accumulate and compete with other s factors for binding to the core RNA polymerase. This s exchange in turn leads to changes in gene expression that protect against stresses and prepare the cell for long-term survival. Conversely, when carbon sources are replenished, RpoS is actively degraded, and RpoS-controlled genes are no longer expressed. We wish to understand the molecular signals that control RpoS stability.There are several plausible mechanisms of RpoS regulation. SprE is an adaptor specific for RpoS degradation and belongs to the response regulator family of twocomponent signaling proteins. It has a highly conserved N-terminal receiver domain with a conserved aspartic acid, D58, so it was possible that its activity was controlled by phosphorylation of this site. However, it is an orphan response regulator; there is no cognate sensor kinase. We and others have mutated the phosphorylation site of the chromosomal allele of sprE and found that RpoS proteolysis was still regulated upon carbon starvation in a SprE-dependent manner (Peterson et al. 2004;Zhou and Gottesman 2006). Accordingly, we conclude that phosphorylation of SprE is not integral to the carbon starvation signaling pathway that regulates RpoS. SprE was recently found to regulate mRNA stability (Carabetta et al. 2009), and it is not known if phosphorylation plays a role in that activity.In response to other stress...

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“…It was reported that an engineered sigma factor library could reprogram metabolic flux and thus led to diverse phenotypes, and some of mutant strains could be used for industrial production purposes [12]. Additionally, sigma factors were shown to be associated with the cell survival under stress conditions [13][14][15]. Based on above information, we speculated that sigma factors may affect promoter activity.…”

Section: Introductionmentioning

confidence: 86%

Enhanced Promoter Activity by Replenishment of Sigma Factor rpoE in Klebsiella pneumoniae

Chen

Tian

2016

Indian J Microbiol

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Plasmid-dependent overexpression of enzyme(s) aims to divert carbon flux toward a desired compound. One drawback of this strategy is compromise of growth due to massive consumption of host resources. Here we show that replenishment of sigma factor rpoE improves the growth of Klebsiella pneumoniae. The gene rpoE was expressed alone or coexpressed with Ald4 (an aldehyde dehydrogenase from Saccharomyces cerevisiae) in K. pneumoniae. We found that the Ald4 activity was higher in the strain coexpressing Ald4 and rpoE (32.3 U/mg) than that expressing Ald4 alone (29.9 U/mg). Additionally, under shake-flask conditions, the strain coexpressing Ald4 and rpoE produced 0.5 g 3-hydroxypropionic acid (3-HP) and 9.8 g 1,3-propanediol (1,3-PD) per liter in 24 h, which were 1.6-and 0.85-fold enhancement, respectively, compared to those expressing Ald4 alone. Notably, under nonoptimized bioreactor conditions, the strain coexpressing Ald4 and rpoE produced 13.5 g 3-HP and 37.8 g 1,3-PD per liter with glycerol conversion ratio of 0.45 mol/mol. These results indicate that replenishment of rpoE enhanced promoter activity and stimulated glycerol consumption.

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A DNA damage response in Escherichia coli involving the alternative sigma factor, RpoS

Cited by 81 publications

References 37 publications

Stress sigma factor RpoS degradation and translation are sensitive to the state of central metabolism

Stress sigma factor RpoS degradation and translation are sensitive to the state of central metabolism

RpoS proteolysis is controlled directly by ATP levels in Escherichia coli

Enhanced Promoter Activity by Replenishment of Sigma Factor rpoE in Klebsiella pneumoniae

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