Project description:Mammalian TFEB and TFE3, as well as their ortholog in C. elegans HLH-30, play an important role in mediating cellular response to a variety of stress conditions, including nutrient deprivation, oxidative stress and pathogen infection. In this study we identify a novel mechanism of TFEB/HLH-30 regulation through a cysteine-mediated redox switch. Under stress conditions, TFEB-C212 undergoes oxidation, allowing the formation of intermolecular disulfide bonds that result in TFEB oligomerization. TFEB oligomers display increased resistance to mTORC1-mediated inactivation and are more stable under prolonged stress conditions. Mutation of the only cysteine residue present in HLH-30 (C284) significantly reduced its activity, resulting in developmental defects and increased pathogen susceptibility. Therefore, cysteine oxidation represents a new type of TFEB post-translational modification that functions as a molecular switch to link changes in redox balance with expression of TFEB/HLH-30 target genes.

Project description:Nonsteroidal anti-inflammatory drugs (NSAIDs), including salicylic acid (SA), target mammalian cyclooxygenases. In plants, SA is a defense hormone that regulates NON-EXPRESSOR OF PATHOGENESIS RELATED GENES 1 (NPR1), the master transcriptional regulator of immunity-related genes. We identify that the oxicam-type NSAIDs tenoxicam (TNX), meloxicam, and piroxicam, but not other types of NSAIDs, exhibit an inhibitory effect on immunity to bacteria and SA-dependent plant immune response. TNX treatment decreases NPR1 levels, independently from the proposed SA receptors NPR3 and NPR4. Instead, TNX induces oxidation of cytosolic redox status, which is also affected by SA and regulates NPR1 homeostasis. A cysteine labeling assay reveals that cysteine residues in NPR1 can be oxidized in vitro, leading to disulfide-bridged oligomerization of NPR1, but not in vivo regardless of SA or TNX treatment. Therefore, this study indicates that oxicam inhibits NPR1-mediated SA signaling without affecting the redox status of NPR1.

Project description:p16INK4A inhibits the CDK4/6 kinases and is therefore an important cell cycle regulator. Accumulation of p16INK4A in response to oncogenic transformation leads to cellular senescence and it is therefore frequently lost in cancer. p16INK4A is also known to accumulate under conditions of cellular oxidative stress and therefore could potentially be regulated by redox signaling, which is a form of signal transduction that is mediated by the reversible oxidation of cysteine-thiol side chains in proteins. We found that oxidation of the single cysteine residue in p16INK4A in human cells occurs under relatively mild oxidizing conditions and that this leads to disulfide dependent dimerization. p16INK4A is a well-characterized all alpha-helical protein, but we find that upon cysteine-dependent dimerization, p16INK4A undergoes a dramatic structural rearrangement and forms aggregates that have the typical features of amyloid fibrils, including binding of diagnostic dyes, presence of cross-β sheet structure, and typical dimensions found in electron microscopy. We find that p16INK4A amyloid formation abolishes its function as a CDK4/6 inhibitor in human cells. Taken together, these observations mechanistically link the cellular redox state to the inactivation of p16INK4A through the formation of amyloid fibrils.

Project description:Low glutathione levels are associated with crystallin oxidation in age-related nuclear cataract (ARNC). To understand the role of cysteine residue oxidation, we used the novel approach of comparing human cataracts with glutathione-depleted LEGSKO mouse lenses for intra- vs. intermolecular disulfide crosslinks using 2D-PAGE and proteomics, and then systematically identified in vivo and in vitro all disulfide forming sites using ICAT labeling method coupled with proteomics. Crystallins rich in intramolecular disulfides were abundant at young age in human and WT mouse lens but shifted to multimeric intermolecular disulfides at older age. The shift was ~4x accelerated in LEGSKO lens. Most cysteine disulfides in β-crystallins (except βA4 in human) were highly conserved in mouse and human and could be generated by oxidation with H2O2, while γ-crystallin oxidation selectively affected γC23/42/79/80/154, γD42/33 and γS83/115/130 in human cataracts, and γB79/80/110, γD19/109, γF19/79, γE19, γS83/130 and γN26/128 in mouse. Analysis based on available crystal structure suggests that conformational changes are needed to expose C42, C79/80, C154 in γC; C42, C33 in γD, and C83, C115 and C130 in γS. In conclusion, while the β-crystallin disulfidome is highly conserved in ARNC and LEGSKO mouse, and reproducible by in vitro oxidation, some of the disulfide formation sites in γ-crystallins necessitate prior conformational changes. Overall, the LEGSKO mouse model is closely reminiscent of ARNC.

Project description:Protein cysteinyl thiols are susceptible to reduction-oxidation reactions that can influence protein function, urging the need for accurate cysteine oxidation quantification to decode protein redox regulation. Here, we present a novel approach called CysQuant that enables simultaneous quantification of cysteine oxidation degrees and protein abundancies. Reduced and reversibly oxidized cysteines are differentially labeled with light and heavy iodoacetamide isotopologues and analyzed using data-dependent acquisition (DDA) or data-independent acquisition (DIA) mass spectrometry. Using in silico predicted spectral libraries, plexDIA quantified on average 18% oxidized in the model plant Arabidopsis thaliana, though revealed a subset of highly oxidized cysteines part of disulfide bridges in AlphaFold2 predicted protein structures. Studying protein redox regulation of plant seedlings in response to excessive light, CysQuant successfully identified the well-established increased reduction of Calvin-Benson cycle enzymes, in addition to discovery of other, yet uncharacterized redox-sensitive disulfides in plastidial enzymes. CysQuant is widely applicable to diverse mass spectrometry platforms studying the cysteine modification status.

Project description:The redox-sensing MarR/DUF24-type repressor YodB controls expression of the azoreductase AzoR1 and the nitroreductase YodC that are involved in detoxification of quinones and diamide in Bacillus subtilis. In the present paper, we identified YodB and its paralog YvaP (CatR) as repressors of the yfiDE (catDE) operon encoding a catechol-2,3-dioxygenase that also contributes to quinone resistance. Inactivation of both paralogs, CatR and YodB, results in full derepression of catDE transcription. DNA-binding assays and promoter mutagenesis studies showed that CatR protects two inverted repeats with the consensus sequence TTAC-N5-GTAA overlapping the -35 promoter region (BS1) and the transcriptional start site (BS2). The BS1 operator was required for binding of YodB in vitro. CatR and YodB share the conserved N-terminal Cys residue that is essential for redox-sensing of CatR in vivo as shown by Cys-to-Ser mutagenesis. Our data suggest that CatR is modified by intermolecular disulfide formation in response to diamide and quinones in vitro and in vivo. Redox-regulation of CatR occurs independently of YodB and no protein interaction was detected between CatR and YodB in vivo using protein-crosslinking and mass spectrometry. Control of Bacillus subtilis 168 wild type (Ko_WT) vs. DyvaP mutant (Ko_DyvaP). The experiment was conducted in duplicates using two independent total RNA preparations. For all datasets used for final analysis, wild-type samples were labeled with Cy3 and DyvaP mutant samples were labeled with Cy5.

Project description:Reduction-oxidation (redox) signaling, the translation of an oxidative intracellular environment into a cellular response, is mediated by the reversible oxidation of specific cysteine thiols. The latter results in disulfide formation between protein (hetero)dimers that alter protein function until the cellular redox has returned to the basal state. We have previously shown that this mechanism promotes the nuclear localization and activity of the FOXO4 transcription factor. Here, we present evidence that FOXO3 and FOXO4 have acquired paralog-specific cysteines throughout vertebrate evolution. Using a proteome-wide screen we identified previously unknown redox-dependent FOXO3 interaction partners. The nuclear import receptor IPO7 forms a disulfide-dependent heterodimer with FOXO3, but not with FOXO4, which is required for reactive oxygen species (ROS)-induced nuclear translocation . These findings suggest that evolutionary acquisition of cysteines has contributed to functional divergence of FOXO paralogs.

Project description:Reduction-oxidation (redox) signaling, the translation of an oxidative intracellular environment into a cellular response, is mediated by the reversible oxidation of specific cysteine thiols. The latter results in disulfide formation between protein (hetero)dimers that alter protein function until the cellular redox has returned to the basal state. We have previously shown that this mechanism promotes the nuclear localization and activity of the FOXO4 transcription factor. Here, we present evidence that FOXO3 and FOXO4 have acquired paralog-specific cysteines throughout vertebrate evolution. Using a proteome-wide screen we identified previously unknown redox-dependent FOXO3 interaction partners. The nuclear import receptor IPO7 forms a disulfide-dependent heterodimer with FOXO3, but not with FOXO4, which is required for reactive oxygen species (ROS)-induced nuclear translocation . These findings suggest that evolutionary acquisition of cysteines has contributed to functional divergence of FOXO paralogs.

Project description:Reduction-oxidation (redox) signaling, the translation of an oxidative intracellular environment into a cellular response, is mediated by the reversible oxidation of specific cysteine thiols. The latter results in disulfide formation between protein (hetero)dimers that alter protein function until the cellular redox has returned to the basal state. We have previously shown that this mechanism promotes the nuclear localization and activity of the FOXO4 transcription factor. Here, we present evidence that FOXO3 and FOXO4 have acquired paralog-specific cysteines throughout vertebrate evolution. Using a proteome-wide screen we identified previously unknown redox-dependent FOXO3 interaction partners. The nuclear import receptor IPO7 forms a disulfide-dependent heterodimer with FOXO3, but not with FOXO4, which is required for reactive oxygen species (ROS)-induced nuclear translocation . These findings suggest that evolutionary acquisition of cysteines has contributed to functional divergence of FOXO paralogs.

Project description:The redox-sensing MarR/DUF24-type repressor YodB controls expression of the azoreductase AzoR1 and the nitroreductase YodC that are involved in detoxification of quinones and diamide in Bacillus subtilis. In the present paper, we identified YodB and its paralog YvaP (CatR) as repressors of the yfiDE (catDE) operon encoding a catechol-2,3-dioxygenase that also contributes to quinone resistance. Inactivation of both paralogs, CatR and YodB, results in full derepression of catDE transcription. DNA-binding assays and promoter mutagenesis studies showed that CatR protects two inverted repeats with the consensus sequence TTAC-N5-GTAA overlapping the -35 promoter region (BS1) and the transcriptional start site (BS2). The BS1 operator was required for binding of YodB in vitro. CatR and YodB share the conserved N-terminal Cys residue that is essential for redox-sensing of CatR in vivo as shown by Cys-to-Ser mutagenesis. Our data suggest that CatR is modified by intermolecular disulfide formation in response to diamide and quinones in vitro and in vivo. Redox-regulation of CatR occurs independently of YodB and no protein interaction was detected between CatR and YodB in vivo using protein-crosslinking and mass spectrometry.