Project description:S-glutathionylation is an important post-translational modification (PTM) process that targets the protein cysteine thiol by the addition of glutathione (GSH). This modification can prevent proteolysis from over-oxidation of protein cysteine residue during the condition of oxidative or nitrosative stress. Recent studies suggest that protein S-glutathionylation plays an essential role in control of cell-signaling pathways by affecting the protein function in bacteria and even humans. In this study, we investigated the impacts of S-glutathionylation on physiological regulation within Streptococcus mutans, the primary etiological agent of human dental caries. To determine S-glutathionylated proteins in bacteria, the Cys-reactive isobaric reagents iodoTMT (iodoacetyl Tandem Mass Tag) were used to label the S-glutathionylated Cys sites and anti-TMT antibody conjugated resins were used to enrich the modified peptides. Proteome profiling identified a total of 357 glutathionylated cysteines sites on 239 proteins. Functional enrichment analysis indicated that these S-glutathionylated proteins were involved in diverse important biological processes, such as pyruvate metabolism and glycolysis

Project description:Cardiomyocytes proteins were investigated for their glutathionylation in response to hydrogen peroxide generated from glucose oxidase and using a clickable glutathione derivative. After exposure, or not, to hydrogen peroxide the glutathionylated proteins were enriched and LC-MS/MS analyses was performed.

Project description:Ischemia or ischemic reperfusion is well-known for its contribution to heart diseases. During ischemia and reperfusion, a flux of nutrients and oxygen to cardiomyocytes is altered, which causes a burst of ROS from mitochondria and other enzymes. Elevated levels of ROS can cause oxidative modifications of cardiac proteins, such as protein glutathionylation. Despite previous extensive studies, proteomic identification of glutathionylated proteins in cardiomyocytes under altered levels of nutrients and oxygen has been relatively limited. We have applied our clickable glutathione approach to HL-1 cardiomyocyte cell line under metabolic alterations of glucose, oxygen, and fatty acids to detect and identify proteins undergoing glutathionylation.

Project description:Cysteine modifications have been widely detected among different protein in different species. Here, we examined protein glutathionylation in HeLa cells under both untreated and diamide-treated conditions. A strategy using resin-assisted enrichment of glutathionylated proteins or peptides after biotin-switch is commonly used for detection of glutathionylation and other reversible cysteine modifications, and was also applied in this study. Using these strategies we identified a large number of glutathionylated protein with modification sites under both untreated and diamide-treated conditions.

Project description:We investigated the role of protein arginine methyltransferase 5 (PRMT5) in leukemia patient cells with inversion of chromosome 3. This rearrangement leads to overexpression of the proto-oncogene EVI1 (ecotropic virus integration site 1). To further investigate the mechanism of PRMT5 dependency in these cells, we performed transcriptome and splicing analyses.

Project description:Glutathionylation is an important post-translational modification and developing tools to identify which cysteine residues on proteins are glutathionylated in response to different physiological conditions is necessary. This project utilizes an approach consisting of azido-glutathione, a single purified protein, and an oxidant to form disulfide bonds between the azide modified glutathione and the cysteine residues of the protein. After this the reaction is quenched with iodoacetamide, subjected to a click reaction with a chemically cleavable alkyne conjugated biotin, and digested with trypsin. These peptide fragments are eluted from streptavidin beads and subjected to LC-MS/MS to determine which cysteine residues are glutathionylated in-vitro.

Project description:Identification of cysteines with high oxidation susceptibility is important for understanding redox-mediated biological processes associated with health and disease. We developed a chemical proteomic strategy that helps find cysteines with high susceptibility to S-glutathionylation. Our strategy is based on the isotopically labelled clickable glutathione derivatives that can quantify relative levels of glutathionylated and reduced forms (SSG vs. SH) of cysteines in mass spectrometry, which is named 'Clickable Glutathione-based Isotope-coded Affinity-Tag (G-ICAT).' The G-ICAT approach was applied to the mouse C2C12 cell line upon addition of hydrogen peroxide, finding 1,518 glutathionylated cysteines and their relative levels of SSG over SH upon adding hydron peroxide. This chemical proteomic strategy will significantly contribute to identifying functional cysteines regulated by glutathionylation in redox signaling.

Project description:Investigated protein glutathionylation in HL-1 cardiomyocyte cells in response to hydrogen peroxide using a clickable glutathione approach. After exposure, or not, to hydrogen peroxide the glutathionylated proteins with heavy or light azido glutathione were enriched and subjected to LC-MS/MS analysis followed by quantification.

Project description:PRMT5 is a methyltransferase that catalyzes symmetric dimethylation of arginine residues in histones (H4R3, H3R8, H3R2, and H2AR3) to regulate transcription of target genes. While PRMT5 is generally considered an epigenetic repressor, recent evidence from our lab and others demonstrate that PRMT5 also functions as an epigenetic activator. Although in vitro biochemical studies suggest that the PRMT5 interacting proteins methylosome protein 50 (MEP50) and methylosome subunit pICln enhance PRMT5 enzymatic activity, how these interacting proteins cooperate with PRMT5 to regulate gene transcription in vivo remains to be elucidated. Here we perform RNA-seq analysis of prostate cancer cells 22Rv1 with knockdown of PRMT5, MEP50, and pICln, in order to elucidate how these proteins control transcriptome.

Project description:Protein Arginine MethylTransferase 5 (PRMT5) is known to mediate epigenetic control on chromatin and to functionally regulate components of the splicing machinery. In this study we show that selective deletion of PRMT5 in different organs leads to cell cycle arrest and apoptosis. At the molecular level, PRMT5 depletion results in reduced methylation of Sm proteins, aberrant constitutive splicing and in the Alternative Splicing (AS) of specific mRNAs. We identify Mdm4 as one of these mRNAs, which due to its weak 5’-Donor site, acts as a sensor of splicing defects and transduces the signal to activate the p53 response, providing a mechanistic explanation of the phenotype observed in PRMT5 conditional knockout mice. Our data demonstrate a key role of PRMT5, together with p53, as guardians of the transcriptome. This will have fundamental implications in our understanding of PRMT5 activity, both in physiological conditions, as well as pathological conditions, including cancer and neurological diseases. Total RNA was extracted from control and Prmt5 depleted Neural Stem/Progenitors Cells (NPCs) and Mouse Embryonic Fibroblasts (MEFs). Prmt5 depleted cells were treated with 4-OHT 24 hours before splitting to induce PRMT5 knockout and final libraries were sequenced in triplicates on Illumina HiSeq 2000.