A CysB-regulated and σ54-dependent regulator, SfnR, is essential for dimethyl sulfone metabolism of Pseudomonas putida strain DS1

Endoh, Takayuki; Habe, Hiroshi; Yoshida, Takako; Nojiri, Hideaki; Omori, Toshio

doi:10.1099/mic.0.26031-0

Cited by 35 publications

(56 citation statements)

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“…Because we had found a 54 -dependent promoter-like sequence upstream of the sfnE translation start point, we first believed that the expression of sfnECR was autoregulated by SfnR. However, in our previous study, the expression of sfnECR was observed in an sfnR-defective mutant (Dfi74J) (9). Therefore, we postulated that the expression of sfnECR is controlled by another 54 -dependent transcriptional regulator or that additional promoters exist in the upstream region of sfnECR.…”

Section: Resultsmentioning

confidence: 79%

“…Many 54 -dependent transcriptional regulators share a common domain architecture that includes three domains: a C-terminal DNA-binding domain, a central module for ATPase activity and interaction with 54 -RNA polymerase, and an N-terminal regulatory domain (37). However, as reported previously, SfnR lacks an N-terminal regulatory domain (8,9); therefore, it is of interest in this context to examine how sulfate is sensed and represses the expression of sfnFG. Several studies have reported on 54 -dependent transcriptional regulators lacking an N-terminal regulatory domain like SfnR.…”

Section: Discussionmentioning

confidence: 98%

“…Each amplified fragment was cloned into a pT7Blue (R) vector (Novagen), and the nucleotide sequences of each reporter plasmid were confirmed. Clones were digested with both HindIII and EcoRI (sites incorporated in the primers) (see Table S1 in the supplemental material), and the fragments were then cloned between the HindIII and EcoRI sites of pMElacZ (9).…”

Section: Chemicalsmentioning

confidence: 99%

“…More interestingly, SfnR lacks an N-terminal regulatory domain, unlike many other 54 -dependent transcriptional regulators (8,9). Therefore, determining the role that SfnR plays in the sulfate starvation response would be of great interest.…”

mentioning

confidence: 99%

“…Expression of the sfnFG operon is directly regulated by a novel 54 -dependent transcriptional regulator, SfnR, which is encoded within the sfnECR operon (Fig. 1B) (8,9). SfnR also activates the expression of the sfnAB operon, and sfnA is suggested to be involved in the use of methanethiol as a sulfur source (11).…”

mentioning

confidence: 99%

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Transcription Factors CysB and SfnR Constitute the Hierarchical Regulatory System for the Sulfate Starvation Response inPseudomonas putida

et al. 2008

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Pseudomonas putida DS1 is able to utilize dimethyl sulfone as a sulfur source. Expression of the sfnFG operon responsible for dimethyl sulfone oxygenation is directly regulated by a 54 -dependent transcriptional activator, SfnR, which is encoded within the sfnECR operon. We investigated the transcription mechanism for the sulfate starvation-induced expression of these sfn operons. Using an in vivo transcription assay and in vitro DNAbinding experiments, we revealed that SfnR negatively regulates the expression of sfnECR by binding to the downstream region of the transcription start point. Additionally, we demonstrated that a LysR-type transcriptional regulator, CysB, directly activates the expression of sfnECR by binding to its upstream region. CysB is a master regulator that controls the sulfate starvation response of the sfn operons, as is the case for the sulfonate utilization genes of Escherichia coli, although CysB DS1 appeared to differ from that of E. coli CysB in terms of the effect of O-acetylserine on DNA-binding ability. Furthermore, we investigated what effector molecules repress the expression of sfnFG and sfnECR in vivo by using the disruptants of the sulfate assimilatory genes cysNC and cysI. The measurements of mRNA levels of the sfn operons in these gene disruptants suggested that the expression of sfnFG is repressed by sulfate itself while the expression of sfnECR is repressed by the downstream metabolites in the sulfate assimilatory pathway, such as sulfide and cysteine. These results indicate that SfnR plays a role independent of CysB in the sulfate starvation-induced expression of the sfn operons.Sulfur, an essential element for bacterial growth, is assimilated from a range of sources. The preferred sulfur source for bacteria is inorganic sulfate, but in soil environments, sulfate may not be freely available because inorganic sulfate constitutes less than 5% of the total sulfur (1). The remainder is largely in the form of sulfate esters and carbon-bound sulfur such as peptides/amino acids and sulfonates (1). Volatile organic sulfur compounds, for example, dimethyl sulfide (DMS) and methanethiol, are also widely distributed in the environment because they are emitted from oceans (2), freshwater sediments (28, 29), and soils (26, 31). Thus, several soil bacterial species have developed a number of systems that allow the use of these organosulfur compounds.Metabolic use of these organosulfur compounds, especially alkanesulfonates, taurine, and alkanesulfate ester, has been extensively investigated in Escherichia coli and Pseudomonas spp. (reviewed in reference 19). Bacterial organosulfur assimilation is mediated by the sulfate starvation response, which involves a set of proteins synthesized by several species of bacteria when the supply of their preferred sulfur sources, such as inorganic sulfate, cysteine, and thiosulfate, is limited. These proteins are known as sulfate starvation-induced (SSI) proteins and include enzymes and transport systems for scavenging sulfur from organic compounds (19...

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Section: Resultsmentioning

confidence: 79%

Section: Discussionmentioning

confidence: 98%

Section: Chemicalsmentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Transcription Factors CysB and SfnR Constitute the Hierarchical Regulatory System for the Sulfate Starvation Response inPseudomonas putida

et al. 2008

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Not as easy as π: An insertional residue does not explain the π‐helix gain‐of‐function in two‐component FMN reductases

et al. 2018

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The π-helix located at the tetramer interface of two-component FMN-dependent reductases contributes to the structural divergence from canonical FMN-bound reductases within the NADPH:FMN reductase family. The π-helix in the SsuE FMN-dependent reductase of the alkanesulfonate monooxygenase system has been proposed to be generated by the insertion of a Tyr residue in the conserved α4-helix. Variants of Tyr118 were generated, and their X-ray crystal structures determined, to evaluate how these alterations affect the structural integrity of the π-helix. The structure of the Y118A SsuE π-helix was converted to an α-helix, similar to the FMN-bound members of the NADPH:FMN reductase family. Although the π-helix was altered, the FMN binding region remained unchanged. Conversely, deletion of Tyr118 disrupted the secondary structural properties of the π-helix, generating a random coil region in the middle of helix 4. Both the Y118A and Δ118 SsuE SsuE variants crystallize as a dimer. The MsuE FMN reductase involved in the desulfonation of methanesulfonates is structurally similar to SsuE, but the π-helix contains a His insertional residue. Exchanging the π-helix insertional residue of each enzyme did not result in equivalent kinetic properties. Structure-based sequence analysis further demonstrated the presence of a similar Tyr residue in an FMN-bound reductase in the NADPH:FMN reductase family that is not sufficient to generate a π-helix. Results from the structural and functional studies of the FMN-dependent reductases suggest that the insertional residue alone is not solely responsible for generating the π-helix, and additional structural adaptions occur to provide the altered gain of function.

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Metabolism of Sulphur-Containing Organic Compounds

Kertesz

2004

Pseudomonas

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A CysB-regulated and σ54-dependent regulator, SfnR, is essential for dimethyl sulfone metabolism of Pseudomonas putida strain DS1

Cited by 35 publications

References 50 publications

Transcription Factors CysB and SfnR Constitute the Hierarchical Regulatory System for the Sulfate Starvation Response inPseudomonas putida

Transcription Factors CysB and SfnR Constitute the Hierarchical Regulatory System for the Sulfate Starvation Response inPseudomonas putida

Not as easy as π: An insertional residue does not explain the π‐helix gain‐of‐function in two‐component FMN reductases

Metabolism of Sulphur-Containing Organic Compounds

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