Project description:Analysis of cysteine redox networks 0, 2, 5, 15, 30, and 60 minutes after stimulation with EGF in A431 cells using a new workflow 'OxRAC' optimized to assess dynamic redox regulation.

Project description:Aldolase contains eight free cysteine residues without disulfide formation in its native state, which makes it a suitable model to manipulate the oxidative modifications on cysteine. H2O2 was chosen to treat aldolase since the principle product between which is sulfenic acid.To assess the reduction of the newly formed sulfenic acids on aldolase by arsenite, a differential alkylation strategy was adapted.To further investigate the formation of other reversible cysteine oxidations such as disulfide on aldolase, arsenite was replaced by DTT in the differential alkylation method to reduce all the reversible cysteine oxidations.To further validate the selectivity of the reducing ability of arsenite on sulfenic acid but not other oxidative modifications especially disulfide, lysozyme was employed in the differential alkylation method. Lysozyme has 8 cysteine residues all bound into disulfide bonds, thereby was not treated with H2O2 to avoid further oxidation.

Project description:Cysteine oxidative modification of cellular proteins is crucial for many aspects of cardiac hypertrophy development. However, integrated dissection of multiple types of cysteine oxidation proteome in cardiac hypertrophy is currently missing. Here we developed a novel discovery platform encompassing a customized biotin switch-based quantitative proteomics pipeline and an advanced analytic workflow to comprehensively profile the landscape of cysteine oxidation in ISO-induced cardiac hypertrophy mouse model. Specifically, we identified a total of 3,717 proteins containing 6,837 oxidized cysteine sites by at least one of reversible cysteine oxidation, cysteine sulfinylation (CysSO2H), and cysteine sulfonylation (CysSO3H). Analyzing the hypertrophy signatures that are reproducibly discovered from computational workflow highlighted a group of fatty acid beta-oxidation enzymes with a continual decreased temporal pattern and a significant decreased abundance in reversible oxidation with no temporal or abundance change in total cysteine, revealing the oxidative regulatory map of fatty acid metabolism in cardiac hypertrophy, which is featured by an overall reduced oxidative metabolism. Our cysteine oxidation platform depicts a dynamic and integrated landscape of the cysteine oxidative proteome, extracted molecular signature, and provided mechanistic insights in cardiac hypertrophy.

Project description:Warfarin targets human vitamin K epoxide reductase (hVKOR), a redox enzyme in the membrane of endoplasmic reticulum (ER), to prevent the formation of blood clots. Although warfarin has been a popular medication since 1954, its mechanism of action is still unclear. A fundamental issue is the controversial orientation of transmembrane helices (TM) in hVKOR. Stable isotope-coded reagents were usedto label VKOR in free, mutated, and warfarin-binding states directly in the cellular environment, followed by LC-MS/MS bottom-up approach to investigate the warfarin binding mechanism.

Project description:We studied consequences of CLPP deletion to mitochondrial proteome and redox-proteome.

Project description:Streptococcus suis is a major pig pathogen as well as an emerging zoonotic pathogen. Previous work has demonstrated that the S. suis extracellular amylopullulanase enzyme (ApuA) that degrades {alpha}-glucans also functions as an adhesin for porcine epithelial cells. To identify the mechanisms linking carbohydrate metabolism and virulence, we first compared the transcriptome of S. suis in minimal medium supplemented with glucose to minimal medium containing a complex carbohydrate pullulan as a carbon source. The relative expression of eighteen virulence genes including suilysin and apuA was increased during growth in presence of pullulan, compared to growth in glucose. Increased virulence potential of S. suis grown in pullulan was demonstrated using hemolytic assays and increased adhesion and invasion of porcine epithelial cells in vitro. A metabolic map of S. suis was generated and combined with transcriptome data to visualize the metabolic adaption of S. suis during adhesion and invasion of the porcine epithelial cells representing an in vitro model of infection. The role of carbon catabolite control in virulence gene regulation was investigated and the molecular mechanism of transcriptional regulation was elucidated for apuA. We demonstrate that relief of CcpA repression is a crucial transcriptional control mechanism linking carbohydrate mechanism and virulence. The model for the transcriptional regulation of two important virulence factors apuA and suilysin was verified by qPCR analysis of gene expression in S. suis recovered from the organs and blood of infected pigs. Four-condition experiment (bacteria grown in THB or in CM supplemented with three different carbon sources), at two different timepoints (early exponential or late exponential growth phase). One replicate per array.

Project description:Reactive oxygen species (ROS) can modulate protein function through cysteine oxidation. Identifying targets of ROS can provide insight into uncharacterized ROS-regulated pathways. Several redox-proteomic workflows, such as OxICAT, exist to identify sites of cysteine oxidation. However, determining ROS targets localized within subcellular compartments and ROS hotspots remains challenging with existing workflows. Here, we present a chemoproteomic platform, PL-OxICAT, which combines proximity labeling (PL) with OxICAT to monitor localized cysteine oxidation events. We show that TurboID-based PL-OxICAT can monitor cysteine oxidation events within subcellular compartments such as the mitochondrial matrix and intermembrane space. Furthermore, we use APEX-based PL-OxICAT to monitor oxidation events within ROS hotspots by using endogenous ROS as the source of peroxide for APEX activation. Together, these platforms further hone our ability to monitor cysteine oxidation events within specific subcellular locations and ROS hotspots and provide a deeper understanding of the protein targets of endogenous and exogenous ROS.

Project description:Thioredoxin/glutathione reductase (TGR, TXNRD3) is a selenoprotein composed of thioredoxin reductase and glutaredoxin domains; the function of this enzyme remains unknown. This NADPH-dependent thiol oxidoreductase evolved by gene duplication within the Txnrd family, is expressed in the testes and can reduce both thioredoxin and glutathione in vitro. To characterize the function of TXNRD3 in vivo, we generated a strain of mice with the deletion of Txnrd3 gene. We show that Txnrd3 knockout mice are viable and without discernable gross phenotypes, but TXNRD3 deficiency leads to fertility impairment in male mice. Txnrd3 knockout animals exhibit a lower fertilization rate in vitro, a sperm movement phenotype and an altered redox status of thiols. Proteomic analyses revealed a broad range of substrates reduced by TXNRD3 during sperm maturation, presumably as a part of quality control. The results show that TXNRD3 plays a critical role in male reproduction via the thiol redox control of spermatogenesis.

Project description:We have analyzed six different extracelular vesicles isolation protocols from plasma of patients coinfected with human immunodeficiency virus and hepatitis C virus (HIV/HCV). In addition, two different RNA isolation kit were used for each protocol, one phenol-based and another pehenol-free kit. Same library kit was used for all samples. Small RNA, including miRNAs, piwiRNA, and sncRNAs were detected.

Project description:Multiple Sulfatase Deficiency (MSD) is a fatal, inherited lysosomal storage disorder characterised by reduced activities of all cellular sulfatases in patients. Sulfatases require a unique post-translational modification of an active site cysteine to formylglycine that is catalysed by the Formylglycine Generating Enzyme (FGE). FGE mutations leading to MSD affect the intracellular protein stability that determines residual enzyme activity and defines disease severity in MSD patients. Here, we show that Protein Disulfide Isomerase (PDI) plays a pivotal role in the recognition and quality control of MSD-causing FGE variants. Overexpression of PDI reduces the residual activity of unstable FGE variants, whereas inhibition of PDI function rescues the residual activity of sulfatases in MSD fibroblasts. Analysing a covalent complex consisting of PDI and a FGE variant by LC-MALDI mass spectrometry allowed to determine the molecular signature for FGE recognition by PDI. Our findings highlight the role of PDI as a disease modifier in MSD, which may be relevant also for other ER-associated protein folding pathologies.