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Literature DB >> 29712426

Hydrogen Sulfide Sensing through Reactive Sulfur Species (RSS) and Nitroxyl (HNO) in Enterococcus faecalis.

Jiangchuan Shen^1,2, Brenna J C Walsh¹, Ana Lidia Flores-Mireles³, Hui Peng^1,2, Yifan Zhang^1,2, Yixiang Zhang^1,4, Jonathan C Trinidad^1,4, Scott J Hultgren³, David P Giedroc^1,5.

Abstract

Recent studies of hydrogen sulfide (H2S) signaling implicate low molecular weight (LMW) thiol persulfides and other reactive sulfur species (RSS) as signaling effectors. Here, we show that a CstR protein from the human pathogen Enterococcus faecalis ( E. faecalis), previously identified in Staphylococcus aureus ( S. aureus), is an RSS-sensing repressor that transcriptionally regulates a cst-like operon in response to both exogenous sulfide stress and Angeli's salt, a precursor of nitroxyl (HNO). E. faecalis CstR reacts with coenzyme A persulfide (CoASSH) to form interprotomer disulfide and trisulfide bridges between C32 and C61', which negatively regulate DNA binding to a consensus CstR DNA operator. A Δ cstR strain exhibits deficiency in catheter colonization in a catheter-associated urinary tract infection (CAUTI) mouse model, suggesting sulfide regulation and homeostasis is critical for pathogenicity. Cellular polysulfide metabolite profiling of sodium sulfide-stressed E. faecalis confirms an increase in both inorganic polysulfides and LMW thiols and persulfides sensed by CstR. The cst-like operon encodes two authentic thiosulfate sulfurtransferases and an enzyme we characterize here as an NADH and FAD-dependent coenzyme A (CoA) persulfide reductase (CoAPR) that harbors an N-terminal CoA disulfide reductase (CDR) domain and a C-terminal rhodanese homology domain (RHD). Both cysteines in the CDR (C42) and RHD (C508) domains are required for CoAPR activity and complementation of a sulfide-induced growth phenotype of a S. aureus strain lacking cstB, encoding a nonheme FeII persulfide dioxygenase. We propose that S. aureus CstB and E. faecalis CoAPR employ orthogonal chemistries to lower CoASSH that accumulates under conditions of cellular sulfide toxicity and signaling.

Entities: Chemical Disease Gene Mutation Species

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Year: 2018 PMID： 29712426 PMCID： PMC6088750 DOI： 10.1021/acschembio.8b00230

Source DB: PubMed Journal: ACS Chem Biol ISSN： 1554-8929 Impact factor: 5.100

73 in total

1. The chemical biology of protein hydropersulfides: Studies of a possible protective function of biological hydropersulfide generation.

Authors: Robert Millikin; Christopher L Bianco; Corey White; Simran S Saund; Stephanie Henriquez; Victor Sosa; Takaaki Akaike; Yoshito Kumagai; Shuhei Soeda; John P Toscano; Joseph Lin; Jon M Fukuto
Journal: Free Radic Biol Med Date: 2016-05-27 Impact factor: 7.376

2. Coenzyme A disulfide reductase, the primary low molecular weight disulfide reductase from Staphylococcus aureus. Purification and characterization of the native enzyme.

Authors: S B delCardayre; K P Stock; G L Newton; R C Fahey; J E Davies
Journal: J Biol Chem Date: 1998-03-06 Impact factor: 5.157

Review 3. The emerging roles of hydrogen sulfide in the gastrointestinal tract and liver.

Authors: Stefano Fiorucci; Eleonora Distrutti; Giuseppe Cirino; John L Wallace
Journal: Gastroenterology Date: 2006-03-06 Impact factor: 22.682

4. Mechanism of H₂S-mediated protection against oxidative stress in Escherichia coli.

Authors: Alexander Mironov; Tatyana Seregina; Maxim Nagornykh; Lyly G Luhachack; Natalya Korolkova; Liubov Errais Lopes; Vera Kotova; Gennady Zavilgelsky; Rustem Shakulov; Konstantin Shatalin; Evgeny Nudler
Journal: Proc Natl Acad Sci U S A Date: 2017-05-22 Impact factor: 11.205

5. Angeli's salt (Na2N2O3) is a precursor of HNO and NO: a voltammetric study of the reactive intermediates released by Angeli's salt decomposition.

Authors: Christian Amatore; Stéphane Arbault; Claire Ducrocq; Shenghua Hu; Issa Tapsoba
Journal: ChemMedChem Date: 2007-06 Impact factor: 3.466

Review 6. The enzymology of cystathionine biosynthesis: strategies for the control of substrate and reaction specificity.

Authors: Susan M Aitken; Jack F Kirsch
Journal: Arch Biochem Biophys Date: 2005-01-01 Impact factor: 4.013

7. Evidence that hydrogen sulfide is a genotoxic agent.

Authors: Matias S Attene-Ramos; Elizabeth D Wagner; Michael J Plewa; H Rex Gaskins
Journal: Mol Cancer Res Date: 2006-01 Impact factor: 5.852

Review 8. Intestinal metabolism of sulfur amino acids.

Authors: Caroline Bauchart-Thevret; Barbara Stoll; Douglas G Burrin
Journal: Nutr Res Rev Date: 2009-12 Impact factor: 7.800

9. Sulfide Homeostasis and Nitroxyl Intersect via Formation of Reactive Sulfur Species in Staphylococcus aureus.

Authors: Hui Peng; Jiangchuan Shen; Katherine A Edmonds; Justin L Luebke; Anne K Hickey; Lauren D Palmer; Feng-Ming James Chang; Kevin A Bruce; Thomas E Kehl-Fie; Eric P Skaar; David P Giedroc
Journal: mSphere Date: 2017-06-21 Impact factor: 4.389

10. Polysulfides (H₂S_n) produced from the interaction of hydrogen sulfide (H₂S) and nitric oxide (NO) activate TRPA1 channels.

Authors: Ryo Miyamoto; Shin Koike; Yoko Takano; Norihiro Shibuya; Yuka Kimura; Kenjiro Hanaoka; Yasuteru Urano; Yuki Ogasawara; Hideo Kimura
Journal: Sci Rep Date: 2017-04-05 Impact factor: 4.379

12 in total

1. Functional asymmetry and chemical reactivity of CsoR family persulfide sensors.

Authors: Joseph N Fakhoury; Yifan Zhang; Katherine A Edmonds; Mauro Bringas; Justin L Luebke; Giovanni Gonzalez-Gutierrez; Daiana A Capdevila; David P Giedroc
Journal: Nucleic Acids Res Date: 2021-12-02 Impact factor: 16.971

2. Rhodaneses minimize the accumulation of cellular sulfane sulfur to avoid disulfide stress during sulfide oxidation in bacteria.

Authors: Mingxue Ran; Qingbin Li; Yufeng Xin; Shaohua Ma; Rui Zhao; Min Wang; Luying Xun; Yongzhen Xia
Journal: Redox Biol Date: 2022-05-26 Impact factor: 10.787

3. Staphylococcus aureus Glucose-Induced Biofilm Accessory Protein A (GbaA) Is a Monothiol-Dependent Electrophile Sensor.

Authors: Abhinaba Ray; Katherine A Edmonds; Lauren D Palmer; Eric P Skaar; David P Giedroc
Journal: Biochemistry Date: 2020-07-29 Impact factor: 3.162

Review 4. H₂S and reactive sulfur signaling at the host-bacterial pathogen interface.

Authors: Brenna J C Walsh; David P Giedroc
Journal: J Biol Chem Date: 2020-07-22 Impact factor: 5.157

5. The Response of Acinetobacter baumannii to Hydrogen Sulfide Reveals Two Independent Persulfide-Sensing Systems and a Connection to Biofilm Regulation.

Authors: Brenna J C Walsh; Jiefei Wang; Katherine A Edmonds; Lauren D Palmer; Yixiang Zhang; Jonathan C Trinidad; Eric P Skaar; David P Giedroc
Journal: mBio Date: 2020-06-23 Impact factor: 7.867

6. CBS-derived H2S facilitates host colonization of Vibrio cholerae by promoting the iron-dependent catalase activity of KatB.

Authors: Yao Ma; Xiaoman Yang; Hongou Wang; Zixin Qin; Chunrong Yi; Changping Shi; Mei Luo; Guozhong Chen; Jin Yan; Xiaoyun Liu; Zhi Liu
Journal: PLoS Pathog Date: 2021-07-20 Impact factor: 6.823

Hydrogen Sulfide Sensing through Reactive Sulfur Species (RSS) and Nitroxyl (HNO) in Enterococcus faecalis.

1. The chemical biology of protein hydropersulfides: Studies of a possible protective function of biological hydropersulfide generation.

2. Coenzyme A disulfide reductase, the primary low molecular weight disulfide reductase from Staphylococcus aureus. Purification and characterization of the native enzyme.

Review 3. The emerging roles of hydrogen sulfide in the gastrointestinal tract and liver.

4. Mechanism of H₂S-mediated protection against oxidative stress in Escherichia coli.

5. Angeli's salt (Na2N2O3) is a precursor of HNO and NO: a voltammetric study of the reactive intermediates released by Angeli's salt decomposition.

Review 6. The enzymology of cystathionine biosynthesis: strategies for the control of substrate and reaction specificity.

7. Evidence that hydrogen sulfide is a genotoxic agent.

Review 8. Intestinal metabolism of sulfur amino acids.

9. Sulfide Homeostasis and Nitroxyl Intersect via Formation of Reactive Sulfur Species in Staphylococcus aureus.

10. Polysulfides (H₂S_n) produced from the interaction of hydrogen sulfide (H₂S) and nitric oxide (NO) activate TRPA1 channels.

1. Functional asymmetry and chemical reactivity of CsoR family persulfide sensors.

2. Rhodaneses minimize the accumulation of cellular sulfane sulfur to avoid disulfide stress during sulfide oxidation in bacteria.

3. Staphylococcus aureus Glucose-Induced Biofilm Accessory Protein A (GbaA) Is a Monothiol-Dependent Electrophile Sensor.

Review 4. H₂S and reactive sulfur signaling at the host-bacterial pathogen interface.

5. The Response of Acinetobacter baumannii to Hydrogen Sulfide Reveals Two Independent Persulfide-Sensing Systems and a Connection to Biofilm Regulation.

6. CBS-derived H2S facilitates host colonization of Vibrio cholerae by promoting the iron-dependent catalase activity of KatB.

7. Proteomics Profiling of S-sulfurated Proteins in Acinetobacter baumannii.

8. Thioredoxin Profiling of Multiple Thioredoxin-Like Proteins in Staphylococcus aureus.

Review 9. Enzymatic Regulation and Biological Functions of Reactive Cysteine Persulfides and Polysulfides.

10. Structural basis for persulfide-sensing specificity in a transcriptional regulator.

Review 3. The emerging roles of hydrogen sulfide in the gastrointestinal tract and liver.

Review 6. The enzymology of cystathionine biosynthesis: strategies for the control of substrate and reaction specificity.

Review 8. Intestinal metabolism of sulfur amino acids.

Review 4. H2S and reactive sulfur signaling at the host-bacterial pathogen interface.

Review 9. Enzymatic Regulation and Biological Functions of Reactive Cysteine Persulfides and Polysulfides.

Review 4. H₂S and reactive sulfur signaling at the host-bacterial pathogen interface.