Project description:Redox-mediated posttranslational modifications represent a molecular switch that controls major mechanisms of cell function. Nitric oxide (NO) can mediate redox reactions via S-nitrosylation, representing transfer of an NO group to a critical protein thiol. NO is known to modulate neurogenesis and neuronal survival in various brain regions in disparate neurodegenerative conditions. However, a unifying molecular mechanism linking these phenomena remains unknown. Here we report that S-nitrosylation of myocyte enhancer factor 2 (MEF2) transcription factors acts as a redox switch to inhibit both neurogenesis and neuronal survival. Structure-based analysis reveals that MEF2 dimerization creates a pocket, facilitating S-nitrosylation at an evolutionally conserved cysteine residue in the DNA binding domain. S-Nitrosylation disrupts MEF2-DNA binding and transcriptional activity, leading to impaired neurogenesis and survival in vitro and in vivo. Our data define a novel molecular switch whereby redox-mediated posttranslational modification controls both neurogenesis and neurodegeneration via a single transcriptional signaling cascade. Total RNA obtained from human NSCs transfected with constitutively-active MEF2 (MEF2CA) compared to vector control (ptd-Tomato)

Project description:Hydrogen sulfide-mediated signaling pathways regulates many physiological and pathophysiological processes in mammalian and plant systems. The molecular mechanism by which hydrogen sulfide exerts its action involves the post-translational modification of cysteine residues to form a persulfidated thiol motif, named as protein S-sulfhydration or persulfidation. We have developed a comparative and quantitative proteomic analysis approach for the detection of endogenous S-sulfhydrated proteins in wild-type Arabidopsis and L-CYSTEINE DESULFHYDRASE 1 mutant leaves by using the tag-switch method. Bioinformatic analysis of the identified proteins revealed that S-sulfhydrated cysteines are part of a wide range of biological functions regulating important processes such as carbon metabolism, plant responses to abiotic and biotic stresses, plant growth and development, and RNA translation. Quantitative analysis in both genetic backgrounds reveals that protein sulfhydration is mainly involved in primary metabolic pathways such as tricarboxylic acid cycle, glycolysis or Calvin cycle, suggesting that this protein modification is a new regulatory component in these pathways

Project description:Protein S-thiolation is a post-translational thiol-modification that controls redox-sensing transcription factors and protects active site cysteine residues against irreversible oxidation. In B. subtilis, the MarR-type repressor OhrR was shown to sense organic hydroperoxides via formation of mixed disulfides with the redox buffer bacillithiol (Cys-GlcN-Malate) termed as S-bacillithiolation. We have studied changes in the transcriptome and redox proteome caused by the strong oxidant hypochloric acid (NaOCl), the active component of house-hold bleach. The OhrR-controlled peroxiredoxin OhrA was most strongly up-regulated by NaOCl stress and conferred specific protection against NaOCl. Inactivation of the OhrR repressor was caused by S-bacillithiolation of the redox-sensing Cys15 residue in response to NaOCl. Two cobalamin-independent methionine synthases MetE and YxjG were identified as S-bacillithiolated at their essential active site cysteines resulting in hypochlorite-induced methionine limitation. In summary, our studies show that S-bacillithiolation of OhrR and the methionine synthases is the major mechanism in protection against hypochlorite stress in B. subtilis. The B. subtilis 168 wild type strain was grown in minimal medium to OD500 of 0.4 and harvested before and 10 minutes after exposure to 50 µM NaOCl. Microarray hybridizations were performed in triplicate using RNA isolated from independent cultures.

Project description:Redox-mediated posttranslational modifications represent a molecular switch that controls major mechanisms of cell function. Nitric oxide (NO) can mediate redox reactions via S-nitrosylation, representing transfer of an NO group to a critical protein thiol. NO is known to modulate neurogenesis and neuronal survival in various brain regions in disparate neurodegenerative conditions. However, a unifying molecular mechanism linking these phenomena remains unknown. Here we report that S-nitrosylation of myocyte enhancer factor 2 (MEF2) transcription factors acts as a redox switch to inhibit both neurogenesis and neuronal survival. Structure-based analysis reveals that MEF2 dimerization creates a pocket, facilitating S-nitrosylation at an evolutionally conserved cysteine residue in the DNA binding domain. S-Nitrosylation disrupts MEF2-DNA binding and transcriptional activity, leading to impaired neurogenesis and survival in vitro and in vivo. Our data define a novel molecular switch whereby redox-mediated posttranslational modification controls both neurogenesis and neurodegeneration via a single transcriptional signaling cascade.

Project description:Abstract of associated menuscript; Quinones and alpha,beta-unsaturated carbonyls are naturally occurring electrophiles that target cysteine residues via thiol-(S)-alkylation. We analyzed the global expression profile of Bacillus subtilis to the toxic carbonyls methylglyoxal (MG) and formaldehyde (FA). Both carbonyl compounds cause a stress response characteristic for thiol-reactive electrophiles as revealed by the induction of the Spx, CtsR, CymR, PerR, ArsR, CzrA, CsoR and SigmaD regulons. MG and FA triggered also a SOS response which indicates DNA damage. Protection against FA is mediated by both the hxlAB operon, encoding the ribulose monophosphate pathway for FA fixation, and a thiol-dependent formaldehyde dehydrogenase (AdhA) and DJ-1/PfpI-family cysteine proteinase (YraA). The adhA-yraA operon and the yraC gene, encoding gamma-carboxymuconolactone decarboxylase, are positively regulated by the MerR-family regulator, YraB(AdhR). AdhR binds specifically to its target promoters which contain a 7-4-7 inverted repeat (CTTAAAG-N4-CTTTAAG) between the -35 and -10 elements. Activation of adhA-yraA transcription by AdhR requires the conserved Cys52 residue in vivo. We speculate that AdhR is redox-regulated via thiol-(S)-alkylation by aldehydes and that AdhA and YraA are specifically involved in reduction of aldehydes and degradation or repair of damaged thiol-containing proteins, respectively. WT (-FA) vs. WT (+ 1 mM FA), WT (-MG) vs. WT (+ 2.8 mM MG), WT (-MG) vs. WT (+ 5.6 mM MG). Each experiement was conducted triplicates using three independent total RNA preparations. For all datasets used for final analysis, untreated samples were labeled with Cy3 and treated samples with Cy5.

Project description:Hydrogen sulfide-mediated signaling pathways regulates many physiological andpathophysiological processes in mammalian and plant systems. The molecular mechanism bywhich hydrogen sulfide exerts its action involves the oxidative post-translational modificationof cysteine residues to form a persulfidated thiol motif, named as protein S-sulfhydration orpersulfidation. We have developed a comparative and quantitative proteomic analysisapproach for the detection of endogenous S-sulfhydrated proteins in wild-type Arabidopsisand L-CYSTEINE DESULFHYDRASE 1 mutant leaves by using the tag-switch method.Bioinformatic analysis of the identified proteins revealed that S-sulfhydrated cysteines arepart of a wide range of biological functions regulating important processes such as carbonmetabolism, plant responses to abiotic and biotic stresses, plant growth and development, andRNA translation. Quantitative analysis in both genetic backgrounds reveals hydrogen sulfidemediatedprotein sulfhydration as a new regulatory component in primary metabolic pathwayssuch as tricarboxylic acid cycle, glycolysis or Calvin cycle. In addition, studies on thesubcellular localization of glyceraldehyde-3-phosphate dehydrogenase show that sulfideregulates the cytosolic/nuclear partitioning by enhancing the nuclear localization of theprotein and appears to be a critical step for reprogramming cellular metabolism.

Project description:Hydrogen sulfide (H2S)-mediated signaling pathways regulate many physiological and pathophysiological processes in mammalian and plant systems. The molecular mechanism by which hydrogen sulfide exerts its action involves the post-translational modification of cysteine residues to form a persulfidated thiol motif, and it is named protein Persulfidation. We have developed a comparative and label-free quantitative proteomic analysis approach for the detection of endogenous persulfidated proteins in Arabidopsis thaliana nitrogen-starved roots and carbon-starved leaves by using the tag-switch method. In this work, we have identified 5214 and 4691 unique proteins from root and leaf tissue, respectively, that represent almost a 13% of the entire annotate proteome in Arabidopsis. Bioinformatic analysis revealed that persulfidated cysteines are part of a wide range of biological functions, regulating important processes such as carbon metabolism, plant responses to abiotic and biotic stresses, plant growth and development, RNA translation and protein degradation. Quantitative analysis in both tissues showed important H2S-regulated metabolic processes through changes in the persulfidation level of key protein targets involved in ubiquitin-dependent protein degradation and autophagy, among others.

Project description:Protein S-thiolation is a post-translational thiol-modification that controls redox-sensing transcription factors and protects active site cysteine residues against irreversible oxidation. In Bacillus subtilis the MarR-type repressor OhrR was shown to sense organic hydroperoxides via formation of mixed disulfides with the redox buffer bacillithiol (Cys-GlcN-Malate, BSH), termed as S-bacillithiolation. Here, we have studied changes in the transcriptome and redox proteome caused by the strong oxidant hypochloric acid in B. subtilis. The expression profile of NaOCl stress is indiciative of disulfide stess as shown by the induction of the thiol- and oxidative stress-specific Spx, CtsR and PerR regulons. Thiol redox proteomics identified only few cytoplasmic proteins with reversible thiol-oxidations in response to NaOCl stress that include GapA and MetE. Shotgun-LC-MS/MS analyses revealed that GapA, Spx and PerR are oxidized to intramolecular disulfides by NaOCl stress. Furthermore, we identified six S-bacillithiolated proteins in NaOCl-treated cells, including the OhrR repressor, two methionine synthases MetE and YxjG, the inorganic pyrophosphatase PpaC, the 3-D-phophoglycerate dehydrogenase SerA and the putative bacilliredoxin YphP. S-bacillithiolation of the OhrR repressor leads to up-regulation of the OhrA peroxiredoxin that confers together with BSH specific protection against NaOCl. S-bacillithiolation of MetE, YxjG, PpaC and SerA causes hypochlorite-induced methionine starvation as supported by the induction of the S-box regulon. The mechanism of S-glutathionylation of MetE has been described in Escherichia coli also leading to enzyme inactivation and methionine auxotrophy. In summary, our studies discover an important role of the BSH redox buffer in protection against hypochloric acid by S-bacillithiolation of the redox-sensing regulator OhrR and of four enzymes of the methionine biosynthesis pathway.

Project description:Abstract of associated menuscript; Quinones and alpha,beta-unsaturated carbonyls are naturally occurring electrophiles that target cysteine residues via thiol-(S)-alkylation. We analyzed the global expression profile of Bacillus subtilis to the toxic carbonyls methylglyoxal (MG) and formaldehyde (FA). Both carbonyl compounds cause a stress response characteristic for thiol-reactive electrophiles as revealed by the induction of the Spx, CtsR, CymR, PerR, ArsR, CzrA, CsoR and SigmaD regulons. MG and FA triggered also a SOS response which indicates DNA damage. Protection against FA is mediated by both the hxlAB operon, encoding the ribulose monophosphate pathway for FA fixation, and a thiol-dependent formaldehyde dehydrogenase (AdhA) and DJ-1/PfpI-family cysteine proteinase (YraA). The adhA-yraA operon and the yraC gene, encoding gamma-carboxymuconolactone decarboxylase, are positively regulated by the MerR-family regulator, YraB(AdhR). AdhR binds specifically to its target promoters which contain a 7-4-7 inverted repeat (CTTAAAG-N4-CTTTAAG) between the -35 and -10 elements. Activation of adhA-yraA transcription by AdhR requires the conserved Cys52 residue in vivo. We speculate that AdhR is redox-regulated via thiol-(S)-alkylation by aldehydes and that AdhA and YraA are specifically involved in reduction of aldehydes and degradation or repair of damaged thiol-containing proteins, respectively.

Project description:Glioblastoma (GBM) remains among the deadliest of human malignancies, and the emergence of the cancer stem cell (CSC) phenotype represents a major challenge to durable treatment response. Because the environmental and lifestyle factors that impact CSC populations are not clear, we sought to understand the consequences of diet on CSC enrichment. We evaluated disease progression in mice fed an obesity-inducing high-fat diet (HFD) versus a low-fat, control diet. HFD resulted in hyper-aggressive disease accompanied by CSC enrichment and shortened survival. HFD drove intracerebral accumulation of saturated fats, which inhibited the production of the cysteine metabolite and gasotransmitter, hydrogen sulfide (H2S). H2S functions principally through protein S-sulfhydration and regulates multiple programs including bioenergetics and metabolism. Inhibition of H2S increased proliferation and chemotherapy resistance, whereas treatment with H2S donors led to death of cultured GBM cells and stasis of GBM tumors in vivo. GBM specimens present an overall reduction in protein S-sulfhydration, primarily associated with proteins regulating cellular metabolism. These findings provide new evidence that diet modifiable H2S signaling serves to suppress GBM by restricting metabolic fitness, while its loss triggers CSC enrichment and disease acceleration. Interventions augmenting H2S bioavailability concurrent with GBM standard of care may improve outcomes for GBM patients.