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 presence of redox-active molecules containing catenated sulfur atoms (supersulfide) in living organisms has led to a review of the concepts of redox biology and its translational strategy. Glutathione (GSH) is the body’s primary detoxifier and antioxidant, and its oxidized form (GSSG) has been considered as a marker of oxidative status. However, we report that GSSG, but not reduced GSH, prevents ischemic supersulfide catabolism-associated heart failure in mice by electrophilic modification of dynamin-related protein (Drp1). In healthy exercised hearts, the redox-sensitive Cys644 of Drp1 is highly S-glutathionylated. Nearly 40 % of Cys644 is normally polysulfidated, and Cys644 S-glutathionylation is resistant to Drp1 depolysulfidation-dependent mitochondrial hyperfission and myocardial dysfunction caused by hypoxic or environmental chemical stress. MD simulation of Drp1 structure and site-directed mutagenetic analysis reveals a functional interaction between Cys644 and a critical phosphorylation site Ser637, through Glu640. Bulky modification at Cys644 via polysulfidation or S-glutathionylation reduces Drp1 activity by disrupting Ser637-Glu640-Cys644 interaction. Disruption of Cys644 S-glutathionylation nullifies the cardioprotective effect of GSSG against heart failure after myocardial infarction. Our findings suggest a novel therapeutic potential of polysulfur-based Cys bulking on Drp1 for ischemic heart disease.

Project description:To understand cellular mechanisms of stress management, omics data constitute a powerful resource. However, the availability of absolute quantitative data on protein abundances is still a serious limiting factor. This knowledge gap increments especially when protein abundances need to be compared across different cell compartments. In the present study, we aimed to provide deeper insights in the proteomic responses of the model Gram-positive bacterium Bacillus subtilis to disulfide stress. For this purpose, proteome-wide absolute abundances were determined with focus on different subcellular locations (cytosol and membrane) and the extracellular medium, and these were combined with redox state determination. To achieve the quantification of secreted proteins in the culture medium, a simple and straightforward protocol for the absolute quantification of extracellular proteins in bacteria was developed. Extracellular proteins, which are highly diluted in the medium, were concentrated using StrataClean beads together with a set of standard proteins that were used to determine the extent of the concentration step. The resulting dataset offers new insights into the protein abundances in different subcellular compartments and the extracellular medium, as well as a proteome-wide redox-state determination. Altogether, our study provides a quantitative understanding of disulfide stress management, protein production and secretion in B. subtilis.

Project description:We developed a mass spectrometry (MS)-based quantitative approach using a set of novel iodoacetyl-based cysteine-reactive isobaric tags (iodoTMT) endowed with unique irreversible Cys-reactivities to differentially quantify the multiple redox-modified forms of a Cys site in the original cellular context. The established method was than applied to map global Cys-redoxomic regulation in NO-mediated ischemic cardioprotection. Upon cell lysis, iodoacetamide was first added to the cell lysates to block free thiols. Reversible Cys modifications were then selectively reduced and labeled by different isobaric sets of iodoTMT. After tryptic digestion, the iodoTMT-labeled peptides were immuno-enriched, and analyzed by LTQ-Orbitrap Velos (Thermo Fisher Scientific) coupled with nanoACQUITY (Waters). All MS and MS/MS raw data were processed with Proteome Discoverer version 1.3 (Thermo Fisher Scientific), and the peptides were identified from the MS/MS spectra searched against the UniProtKB/Swiss-Prot database using the Mascot 2.3.02 (Matrix Science) with the following constraints: only tryptic peptides with up to two missed cleavage sites; taxonomy: Rattus; and mass accuracy of 10 ppm for the parent ion and 0.05 Da for the fragment ions. iodoTMT labeled (C), carbamidomethyl (C), deamidation (NQ), oxidation (M), and acetyl (protein N-term) were specified as dynamic modifications. False discovery rates were calculated by target-decoy strategy with or without using Mascot Percolator. All peptide hits were filtered with a 1% FDR cutoff.

Project description:The Rv2745c (clgR) gene encodes a Clp protease gene regulator that is induced in response to a variety of stress conditions and potentially plays a role in Mtb pathogenesis. The isogenic Mtb:ΔRv2745c mutant is significantly more sensitive to in vitro redox stress generated by diamide, relative to wild-type Mtb, implicating a role for ClgR in the management of intraphagosomal redox stress. Redox stress led to dysregulation of the σH regulon in the isogenic mutant, Mtb:ΔRv2745c. Induction of clgR in Mtb and Mtb:ΔRv2745c (comp) did not lead to Clp protease induction, indicating that clgR has additional functions that need to be elucidated. Disruption of genes involved in sulfate assimilation also occurred in the knock out, implicating clgR as a possible regulator of downstream signaling cascades that facilitate Mtb survival. At different time points, (30, 60 and 90 mins, t=30, t=60 and t=90) following the addition of diamide to M. tuberculosis CDC1551 cultures, RNA was extracted and labeled with Cy5. RNA was also extracted from pre-diamide addition (t=0) time points and labeled with Cy3. These samples were cohybridized on M. tuberculosis CDC1551 whole genome microarrays using biological triplicate samples (i.e. samples derived from three distinct cultures and treatments) and thus three unique datasets were generated for each of the three time points for Mtb. Similar experiments were performed for an isogenic Rv2745c (clgR) mutant in Mtb CDC1551 which was generated by allelic exchange and a complemented strain which was generated by trans-complementation of Rv2745c in the attB locus of the mutant strain, thus restoring the wild type regulation of Rv2745c.

Project description:In the site of infection, the human fungal pathogen Aspergillus fumigatus faces dynamic changes in oxygen concentrations. The ability to survive in severely hypoxic environments during host invasion is one of important virulence traits of A. fumigatus. Therefore, investigation of hypoxia adaptation mechanisms of this pathogen may suggest potential targets for the development of antifungal therapies. Currently, an increasing number of reports has demonstrated that elevated production of intracellular reactive oxygen species (ROS) under low oxygen conditions plays a regulatory role in modulating cellular responses for adaptation to hypoxia. Our results confirmed raised amounts of intracellular ROS in A. fumigatus exposed to decreased oxygen levels. Moreover, nuclear accumulation of the oxidative stress response transcriptional factor AfYap1 was observed after two hours of low oxygen cultivation. For further analysis, we applied iodo-TMT labeling of redox-sensitive cysteine residues to identify proteins, which get reversibly oxidized and therefore regulated by hypoxic ROS after shifting oxygen content in the culture from 21% to 0.2%. For instance, proteins with important roles in maintaining redox balance and protein folding were modified after one hour of hypoxic cultivation. Redox proteomic investigation also revealed that a mitochondrial protein, designated as Coa6, was regulated by hypoxic ROS. A homologous protein in Saccharomyces cerevisiae was shown to be important for a respiratory chain complex IV assembly. Deletion of the gene encoding this protein in A. fumigatus resulted in complete absence of hypoxic growth, suggesting the significance of complex IV during adaptation of A. fumigatus to oxygen limiting conditions.

Project description:The transcriptional regulator Spx plays a key role in maintaining the redox homeostasis of Bacillus subtilis cells exposed to disulfide stress. Defects in Spx were previously shown to lead to differential expression of numerous genes but direct and indirect regulatory effects could not be distinguished. Wild-type strain and spx mutant cells exposed or not to diamide stress were subjected to tiling array gene expression analysis. To distinguish direct and indirect effects, the genomic sites bound by the Spx-RNAP complex were mapped using a chromatine immunoprecipitation approach. This allowed the identification of 144 transcription units comprising 275 genes under direct Spx regulation. This data set contains 4 samples. Immunoprecipitated (IP) DNA from Bacillus subtilis Bas044 strain (BSB1, a tryptophan-prototrophic derivative 168 strain expressing a SPA-tagged Spx protein) were extracted from bacterial cultures in absence or presence of diamide. IP and whole cell extract DNA were hybridized on tiling array to generate ChIP-on-chip profiles. Two biological replicates were analyzed.

Project description:Foetal and adult hematopoietic stem and progenitor cells (HSPCs) are characterized by distinct redox homeostasis that may influence their differential cellular behaviour in normal and malignant haematopoiesis. In this work, we have applied a quantitative mass spectrometry-based redox proteomic approach to comprehensively describe reversible cysteine modifications in primary mouse foetal and adult HSPCs. We defined the redox state of 4455 cysteines in foetal and adult HSPCs and demonstrated a higher susceptibility to oxidation of protein thiols in foetal HSPCs. Our data identified ontogenically active redox switches in proteins with a pronounced role in metabolism and protein homeostasis. Additional redox proteomic analysis identified redox switches acting in mitochondrial respiration as well as protein homeostasis to be triggered during onset of MLL-ENL leukemogenesis in foetal HSPCs. Our data has demonstrated that redox signalling contributes to the regulation of fundamental processes of developmental haematopoiesis and has pinpointed potential targetable redox-sensitive proteins in in utero-initiated MLL-rearranged leukaemia.

Project description:Reactive protein cysteine thiolates are instrumental in redox regulation. Aging associated to oxidative stress, can impair redox signaling by damaging essential cysteine thiolates. Our initial study found that cardiac-specific overexpression of catalase, can protect from oxidative stress and delay cardiac aging in mice. The Project aimed to investigate differential reversible cysteine thiol oxidation in cardiac proteome of wild type and Cat transgenic (Tg) mice, using “Tandem Mass Tag” (TMT) labeling strategy and mass spectrometry. Our results show globally decreased cysteine thiol occupancy in cardiac proteins in Cat Tg mice. The majority of proteins with differentially modified thiols may be involved in pathways of aging and cardiac disease including cellular stress response, proteostasis and apoptosis. Overexpressed catalase may modulate these protein cysteine thiol oxidations resulting in delayed cardiac aging and related pathologies.

Project description:By means of large-scale redox proteomics, we studied reversible cysteine modification during the response to short-term salt stress in Brassica napus. We applied an iodoacetyl tandem mass tags (iodoTMT)-based proteomic approach to analyze the redox proteome of Brassica napus seedlings under control and salt-stressed conditions. We identified 1,821 sulfenylated sites in 912 proteins from all samples. A great number of sulfenylated proteins were predicted to localize to chloroplasts and cytoplasm and GO enrichment analysis of differentially sulfenylated proteins revealed that metabolic processes such as photosynthesis and glycolysis are enriched and enzymes are overrepresented. Redox-sensitive sites in two enzymes were validated in vitro on recombinant proteins and they might affect the enzyme activity. This targeted approach contributes to the identification of the sulfenylated sites and proteins in Brassica napus subjected to salt stress and our study will improve our understanding of the molecular mechanisms underlying the redox regulation in response to salt stress.