Convergence of the Transcriptional Responses to Heat Shock and Singlet Oxygen Stresses

Dufour, Y.; Imam, Saheed; Koo, Bon Chul; Green, Heather A.; Donohue, Timothy J.

doi:10.1371/journal.pgen.1002929

Cited by 43 publications

(82 citation statements)

References 50 publications

(86 reference statements)

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“…The AppA-PpsR regulatory system is composed of a DNA-binding repressor, PpsR, and the light-and redox-sensitive antirepressor AppA (18). FnrL, a member of the FNR (fumarate and nitrate reductase) family of transcription factors, is a global regulator of anaerobic gene expression that is directly inhibited by the presence of O 2 (19,20). These three pathways each contribute to increased expression of photosynthesis genes at low O 2 tension, including those in the puf and puc operons (encoding polypeptides of the RC, LH1, and LH2 complexes), biosynthetic enzymes for bacteriochlorophyll (BChl) and carotenoid (Crt) pigments, and electron transport chain components (12,13,16,(21)(22)(23).…”

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confidence: 99%

Oxygen-Dependent Regulation of Bacterial Lipid Production

et al. 2015

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Understanding the mechanisms of lipid accumulation in microorganisms is important for several reasons. In addition to providing insight into assembly of biological membranes, lipid accumulation has important applications in the production of renewable fuels and chemicals. The photosynthetic bacterium Rhodobacter sphaeroides is an attractive organism to study lipid accumulation, as it has the ability to increase membrane production at low O 2 tensions. Under these conditions, R. sphaeroides develops invaginations of the cytoplasmic membrane to increase its membrane surface area for housing of the membrane-bound components of its photosynthetic apparatus. Here we use fatty acid levels as a reporter of membrane lipid content. We show that, under low-O 2 and anaerobic conditions, the total fatty acid content per cell increases 3-fold. We also find that the increases in the amount of fatty acid and photosynthetic pigment per cell are correlated as O 2 tensions or light intensity are changed. To ask if lipid and pigment accumulation were genetically separable, we analyzed strains with mutations in known photosynthetic regulatory pathways. While a strain lacking AppA failed to induce photosynthetic pigment-protein complex accumulation, it increased fatty acid content under low-O 2 conditions. We also found that an intact PrrBA pathway is required for low-O 2 -induced fatty acid accumulation. Our findings suggest a previously unknown role of R. sphaeroides transcriptional regulators in increasing fatty acid and phospholipid accumulation in response to decreased O 2 tension. IMPORTANCELipids serve important functions in living systems, either as structural components of membranes or as a form of carbon storage. Understanding the mechanisms of lipid accumulation in microorganisms is important for providing insight into the assembly of biological membranes and additionally has important applications in the production of renewable fuels and chemicals. In this study, we investigate the ability of Rhodobacter sphaeroides to increase membrane production at low O 2 tensions in order to house its photosynthetic apparatus. We demonstrate that this bacterium has a mechanism to increase lipid content in response to decreased O 2 tension and identify a transcription factor necessary for this response. This is significant because it identifies a transcriptional regulatory pathway that can increase microbial lipid content. Lipids serve important functions in living systems, either as structural components of membranes or as a form of carbon storage. Lipids derived from oil-rich microorganisms (including bacteria, yeasts, and microalgae) also offer a promising source of renewable fuels and chemicals (1, 2). However, the genetic and biochemical mechanisms regulating lipid accumulation in microorganisms are poorly understood, have been difficult to study, and are typically linked to stress conditions that hinder growth (3-5). Much effort has been directed at increasing lipid accumulation through alteration of enzymes involved in ...

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Oxygen-Dependent Regulation of Bacterial Lipid Production

et al. 2015

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“…For example, the genes of one of the nuo operons (RSP_0100 to RSP_0112) are regulated by RpoHI and RpoHII, and binding of the sigma factors upstream of the first gene of the operon was demonstrated (15), but these nuo genes mostly showed decreased expression in outgrowth phase, which was also strongly dependent on RpoHI in our transcriptome analysis. The facts that not all promoters induced in outgrowth following late stationary phase in R. sphaeroides have RpoH recognition motifs and, further, that genes preceded by RpoH binding sites show different growthphase-dependent expression suggest that additional factors are responsible for the differential expression patterns of some genes.…”

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confidence: 74%

“…3) or by an RpoHII-or RpoHI/RpoHII-dependent promoter (Table S1) (15,16). Since a role of the alternative RpoHI/RpoHII sigma factors in the response to singlet oxygen was observed in previous studies (12,16,25,28), we also tested for a correlation of genes induced during outgrowth (following prolonged stationary phase of 72 h after inoculation) (this study) and genes induced by singlet oxygen, as determined in the study by Berghoff et al (25) (Fig.…”

Section: Resultsmentioning

confidence: 91%

“…Among the 265 genes which showed at least 2-fold higher expression after 20 min of outgrowth than in exponential phase (following late stationary phase), 105 genes were known or predicted to be transcribed by the alternative sigma factor RpoHI, RpoHII, or both (Table S1) (12,15,16). Members of the RpoH family of sigma factors often control genes during a heat shock response.…”

Section: Resultsmentioning

confidence: 99%

“…The alternative sigma factor RpoE activates the rpoHII gene in response to singlet oxygen, and RpoHII consequently activates many genes with functions in the detoxification of peroxides or methylglyoxal, singlet oxygen scavenging, and iron and redox homeostasis (12). RpoHI also has an important role in the singlet oxygen response, and there is a big overlap of the RpoHI and RpoHII regulons (15,16). More recently, it was demonstrated that several stress factors besides heat and singlet oxygen, like organic peroxides, hydrogen peroxide, superoxide, and CdCl 2 , can activate RpoHI/RpoHIIdependent promoters (17).…”

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An RpoHI-Dependent Response Promotes Outgrowth after Extended Stationary Phase in the Alphaproteobacterium Rhodobacter sphaeroides

et al. 2017

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Under unfavorable growth conditions, bacteria enter stationary phase and can maintain cell viability over prolonged periods with no increase in cell number. To obtain insights into the regulatory mechanisms that allow bacteria to resume growth when conditions become favorable again (outgrowth), we performed global transcriptome analyses at different stages of growth for the alphaproteobacterium Rhodobacter sphaeroides. The majority of genes were not differentially expressed across growth phases. After a short stationary phase (about 20 h after growth starts to slow down), only 7% of the genes showed altered expression (fold change of Ͼ1.6 or less than Ϫ1.6, corresponding to a log 2 fold change of Ͼ0.65 or less than Ϫ0.65, respectively) compared to expression at exponential phase. Outgrowth induced a distinct response in gene expression which was strongly influenced by the length of the preceding stationary phase. After a long stationary phase (about 64 h after growth starts to slow down), a much larger number of genes (15.1%) was induced in outgrowth than after a short stationary phase (1.7%). Many of those genes are known members of the RpoHI/RpoHII regulons and have established functions in stress responses. A main effect of RpoHI on the transcriptome in outgrowth after a long stationary phase was confirmed. Growth experiments with mutant strains further support an important function in outgrowth after prolonged stationary phase for the RpoHI and RpoHII sigma factors.IMPORTANCE In natural environments, the growth of bacteria is limited mostly by lack of nutrients or other unfavorable conditions. It is important for bacterial populations to efficiently resume growth after being in stationary phase, which may last for long periods. Most previous studies on growth-phase-dependent gene expression did not address outgrowth after stationary phase. This study on growth-phase-dependent gene regulation in a model alphaproteobacterium reveals, for the first time, that the length of the stationary phase strongly impacts the transcriptome during outgrowth. The alternative sigma factors RpoHI and RpoHII, which are important regulators of stress responses in alphaproteobacteria, play a major role during outgrowth following prolonged stationary phase. These findings provide the first insight into the regulatory mechanisms enabling efficient outgrowth.

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An Omics View on the Response to Singlet Oxygen

Berghoff

Klug

2016

Stress and Environmental Regulation of Gene Expression and Adaptation in Bacteria

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Convergence of the Transcriptional Responses to Heat Shock and Singlet Oxygen Stresses

Cited by 43 publications

References 50 publications

Oxygen-Dependent Regulation of Bacterial Lipid Production

Oxygen-Dependent Regulation of Bacterial Lipid Production

An RpoHI-Dependent Response Promotes Outgrowth after Extended Stationary Phase in the Alphaproteobacterium Rhodobacter sphaeroides

An Omics View on the Response to Singlet Oxygen

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