Activation of the Global Gene Regulator PrrA (RegA) from <i>Rhodobacter sphaeroides</i>

Laguri, Cédric; Stenzel, Rachelle A.; Donohue, Timothy J.; Phillips‐Jones, Mary K.; Williamson, Michael P.

doi:10.1021/bi060683g

Cited by 22 publications

(25 citation statements)

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“…The PrrBA two-component redox sensing pathway plays a critical role in the formation of the photosynthetic apparatus and also serves as a global regulator of gene expression when the oxygen tension decreases (11,21). The cbb 3 cytochrome c oxidase regulates PS gene expression via the PrrBA two-component system by monitoring O 2 levels through sensing the rate of transfer and volume of electrons that travel through the oxidase on their way to O 2 (24,25,(37)(38)(39)41). The same redox flow has been proposed to play a role in the control of carotenoid accumulation (35,36,40).…”

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confidence: 99%

The Use of Chromatin Immunoprecipitation to Define PpsR Binding Activity in Rhodobacter sphaeroides 2.4.1

et al. 2008

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The expression of genes involved in photosystem development in Rhodobacter sphaeroides is dependent upon three major regulatory networks: FnrL, the PrrBA (RegBA) two-component system, and the transcriptional repressor/antirepressor PpsR/AppA. Of the three regulators, PpsR appears to have the narrowest range of physiological effects, which are limited to effects on the structural and pigment biosynthetic activities involved in photosynthetic membrane function. Although a PrrA ؊ mutant is unable to grow under photosynthetic conditions, when a ppsR mutation was present, photosynthetic growth occurred. An examination of the double mutant under anaerobic-dark-dimethyl sulfoxide conditions using microarray analysis revealed the existence of an "extended" PpsR regulon and new physiological roles. To characterize the PpsR regulon and to better ascertain the significance of degeneracy within the PpsR binding sequence in vivo, we adapted the chromatin immunoprecipitation technique to R. sphaeroides. We demonstrated that in vivo there was direct and significant binding by PpsR to newly identified genes involved in microaerobic respiration and periplasmic stress resistance, as well as to photosynthesis genes. The new members of the PpsR regulon are located outside the photosynthesis gene cluster and have degenerate PpsR binding sequences. The possible interaction under physiologic conditions with degenerate binding sequences in the presence of other biologically relevant molecules is discussed with respect to its importance in physiological processes and to the existence of complex phenotypes associated with regulatory mutants. This study further defines the DNA structure necessary for PpsR binding in situ.

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confidence: 99%

The Use of Chromatin Immunoprecipitation to Define PpsR Binding Activity in Rhodobacter sphaeroides 2.4.1

et al. 2008

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“…These results suggest either that unphosphorylated PrrA can dimerize and bind DNA or, far less likely, that monomeric PrrA binds to site I with affinities comparable to those of dimeric phosphorylated PrrA. Since the PrrA protein used in our in vitro studies differed from the protein used by Laguri et al (22) in that the protein of Laguri et al was a PrrA protein in which 21 amino acids, including a polyhistidine tag, were added to the N terminus, while the purified protein used here had a Pro-Gly extension at its C terminus (4), and since the importance of the cytoplasmic environment for PrrA or phosphorylated PrrA dimer formation is not known, we used a genetic approach with R. sphaeroides in order to evaluate PrrA dimerization in the cell.…”

Section: Befmentioning

confidence: 69%

“…Previously, phosphorylation of PrrA was achieved by incubation of the purified protein with acetyl phosphate (30). However, it has been reported that the efficiency of modification of PrrA with BeF 3 Ϫ , which emulates phosphorylation of the D63 residue (22), is estimated to be 90%, compared to the approximately 20% efficiency of acetyl phosphate treatment (22). Therefore, we expected BeF 3 Ϫ modification of PrrA would increase the sensitivity of the EMSAs.…”

Section: Resultsmentioning

confidence: 93%

“…While in vitro transcription assays involving both hemA (30) and cycA (the P2 promoter [4]) have demonstrated that unphosphorylated PrrA can bind DNA and activate transcription, other studies were unable to detect DNA binding of unmodified PrrA to the cycA sequences in the absence of RNA polymerase (22 Ϫ -PrrA for its target within the cycA upstream sequences has been reported to be approximately 5 M, while the K d of unmodified PrrA for the same sequence is approximately 1 mM (22). Thus, while the affinity of unphosphorylated PrrA for one of its target sequences, hemA binding site I, is greater than the affinity of phosphorylated PrrA, the affinity of unphosphorylated PrrA for another target sequence, the cycA binding site, is 200-fold less than the affinity of phosphorylated PrrA.…”

Section: Resultsmentioning

confidence: 99%

“…Further, multicopy analysis of a prrA gene coding for the D63K-PrrA protein revealed that it behaves in a dominant-negative fashion in wild-type cells. Laguri et al (22) demonstrated that the monomer-dimer equilibrium is shifted toward the dimeric form for the phosphoprotein, while the amount of dimeric unphosphorylated PrrA was below the level that could be detected using their methods. We have not examined the relative concentrations of the dimer and the monomer.…”

Section: Discussionmentioning

confidence: 98%

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Regulation of the Rhodobacter sphaeroides 2.4.1 hemA Gene by PrrA and FnrL

Ranson-Olson

Zeilstra-Ryalls

2008

J Bacteriol

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Part of the oxygen responsiveness of Rhodobacter sphaeroides 2.4.1 tetrapyrrole production involves changes in transcription of the hemA gene, which codes for one of two isoenzymes catalyzing 5-aminolevulinic acid synthesis. Regulation of hemA transcription from its two promoters is mediated by the DNA binding proteins FnrL and PrrA. The two PrrA binding sites, binding sites I and II, which are located upstream of the more-5 hemA promoter (P1), are equally important to transcription under aerobic conditions, while binding site II is more important under anaerobic conditions. By using phosphoprotein affinity chromatography and immunoblot analyses, we showed that the phosphorylated PrrA levels in the cell increase with decreasing oxygen tensions. Then, using both in vivo and in vitro methods, we demonstrated that the relative affinities of phosphorylated and unphosphorylated PrrA for the two binding sites differ and that phosphorylated PrrA has greater affinity for site II. We also showed that PrrA regulation is directed toward the P1 promoter. We propose that the PrrA component of anaerobic induction of P1 transcription is attributable to higher affinity of phosphorylated PrrA than of unphosphorylated PrrA for binding site II. Anaerobic activation of the more-3 hemA promoter (P2) is thought to involve FnrL binding to an FNR consensuslike sequence located upstream of the P2 promoter, but the contribution of FnrL to P1 induction may be indirect since the P1 transcription start is within the putative FnrL binding site. We present evidence suggesting that the indirect action of FnrL works through PrrA and discuss possible mechanisms.

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Regulation of Gene Expression in Response to Oxygen Tension

Bauer

Setterdahl

et al. 2009

The Purple Phototrophic Bacteria

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Activation of the Global Gene Regulator PrrA (RegA) from Rhodobacter sphaeroides

Cited by 22 publications

References 43 publications

The Use of Chromatin Immunoprecipitation to Define PpsR Binding Activity in Rhodobacter sphaeroides 2.4.1

The Use of Chromatin Immunoprecipitation to Define PpsR Binding Activity in Rhodobacter sphaeroides 2.4.1

Regulation of the Rhodobacter sphaeroides 2.4.1 hemA Gene by PrrA and FnrL

Regulation of Gene Expression in Response to Oxygen Tension

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