Project description:Protein cysteinyl residues are the mediators of hydrogen peroxide (H2O2)-dependent redox signaling. However, site-specific mapping of the selectivity and dynamics of these redox reactions in cells poses a major analytical challenge. Here we describe a chemoproteomic platform to systematically and quantitatively analyze the reactivity of thousands of cysteines toward H2O2 in human cells. We identified >900 H2O2-sensitive cysteines, which are defined as the H2O2-dependent redoxome. Although redox sites associated with antioxidative and metabolic functions are consistent, most of the H2O2-dependent redoxome varies dramatically between different cells. Structural analyses reveal that H2O2-sensitive cysteines are less conserved than their redox-insensitive counterparts and display distinct sequence motifs, structural features, and potential for crosstalk with lysine modifications. Notably, our chemoproteomic platform also provides an opportunity to predict oxidation-triggered protein conformational changes. The data are freely accessible as a resource at http://redox.ncpsb.org/OXID/.

Project description:Protein cysteinyl residues are the mediators of hydrogen peroxide (H2O2)-dependent redox signaling. However, site-specific mapping of the selectivity and dynamics of these redox reactions in cells poses a major analytical challenge. Here we describe a chemoproteomic platform to systematically and quantitatively analyze the reactivity of thousands of cysteines toward H2O2 in human cells. We identified >900 H2O2-sensitive cysteines, which are defined as the H2O2-dependent redoxome. Although redox sites associated with antioxidative and metabolic functions are consistent, most of the H2O2-dependent redoxome varies dramatically between different cells. Structural analyses reveal that H2O2-sensitive cysteines are less conserved than their redox-insensitive counterparts and display distinct sequence motifs, structural features, and potential for crosstalk with lysine modifications. Notably, our chemoproteomic platform also provides an opportunity to predict oxidation-triggered protein conformational changes. The data are freely accessible as a resource at http://redox.ncpsb.org/OXID/.

Project description:The purpose of this study was to identify downstream gene targets regulated by Neuropeptide S Receptor 1 (NPSR1) upon NPS stimulation. To do this we used human epithelial kidney (HEK)-293H cell lines stable transfected with NPSR1-A and stimulated with NPS for 6 hours. Two controls were used: NPS stimulated HEK-293H cells and unstimulated NPSR1-A cells.

Project description:Data sets are used for benchmarking, pChem, a modification-centric, blind-search tool to provide a streamlined pipeline for unbiased assessing of the performance of chemoproteomic probes. The IPM-based QTRP (quantitative thiol reactivity profiling) data sets were recorded on different LC-MS/MS instruments from three vendors. IPM is a clickable thiol reactive reagent with the iodoacetamide warhead.

Project description:Inhalation of the amibient air polution ozone causes lung inflammation and can suppress host defense mechanisms, including impairing macrophage phagocytosis. Ozone reacts with cholesterol in the lung to form oxysterols, like secosterol A and secosterol B, which can form covalent adducts on cellular proteins. How oxysterol-protein adduction modifies the function of lung macrophages is unknown. Herein, we used a preoteomic screen to identify lung macrophage proteins that fomr adducts with ozone-derived oxysterols. Analysis show that the phagocytic receptor CD206 and CD64 formed adducts with secosterol A. Adduction of these receptors with ozone-derived oxysterols impaired ligand binding and corresponded with reduced macrophage phagocytosis. This work suggests a novle mechanism for the suppression of macrophage phagocytosis following ozone exposure through the generation of oxysterols and the formation of oxysterol-protein adducts on phagocytic receptors.

Project description:Data sets are used for benchmarking, pChem, a modification-centric, blind-search tool to provide a streamlined pipeline for unbiased assessing of the performance of chemoproteomic probes. Data were produced from the IPM-based QTRP (quantitative thiol reactivity profiling) applications in various species, including Arabidopsis thaliana, Escherichia coli, Homo sapiens, Rattus norvegicus, Drosophila melanogaster, Caenorhabditis elegans, Psedomonas syringae, and Mus musculus. IPM is a clickable thiol reactive reagent with the iodoacetamide warhead.

Project description:Data sets are used for benchmarking, pChem, a modification-centric, blind-search tool to provide a streamlined pipeline for unbiased assessing of the performance of chemoproteomic probes. Data were produced from the IPM-based QTRP (quantitative thiol reactivity profiling) experiments where light and heavy IPM-tagged samples mixed in different ratios (L/H = 1:10, 1:5, 1:2, 1:1, 2:1, 5:1 and 10:1). IPM is a clickable thiol reactive reagent with the iodoacetamide warhead.

Project description:Data sets are used for benchmarking, pChem, a modification-centric, blind-search tool to provide a streamlined pipeline for unbiased assessing of the performance of chemoproteomic probes. Data were produced from the IPM-based QTRP (quantitative thiol reactivity profiling) applications in various species, incData sets are used for benchmarking, pChem, a modification-centric, blind-search tool to provide a streamlined pipeline for unbiased assessing of the performance of chemoproteomic probes. Data were produced from the lysinome profiling experiments using amine-reactive probes as indicated, including STP and NHS, both with a clickable alkyne handle.

Project description:Higher order chromatin structure establishes domains that organize the genome and coordinate gene expression. However, the molecular mechanisms controlling transcription of individual loci within a topological domain (TAD) are not fully understood. The cystic fibrosis transmembrane conductance regulator (CFTR) gene provides a paradigm for investigating these mechanisms. CFTR occupies a TAD bordered by CTCF/cohesin binding sites within which are cell-type-selective cis-regulatory elements for the locus. We showed previously that intronic and extragenic enhancers, when occupied by specific transcription factors, are recruited to the CFTR promoter by a looping mechanism to drive gene expression. Here we use a combination of CRISPR/Cas9 editing of cis-regulatory elements and siRNA-mediated depletion of architectural proteins to determine the relative contribution of structural elements and enhancers to the higher order structure and expression of the CFTR locus. We found the boundaries of the CFTR TAD are conserved among diverse cell types and are dependent on CTCF and cohesin complex. Removal of an upstream CTCF-binding insulator alters the interaction profile, but has little effect on CFTR expression. Within the TAD, intronic enhancers recruit cell-type selective transcription factors and deletion of a pivotal enhancer element dramatically decreases CFTR expression, but has minor effect on its 3D structure. Examination of open chromatin region in Caco2 (colorectal adenocarcinoma cells), HBE (primary human bronchial epithelial cells), and primary adult human epididymis cells

Project description:Ozone (O3) is a prevalent air pollutant that causes lung inflammation following exposure. Previous studies demonstrate that O3 oxidizes lipids, such as cholesterol, in the airway to produce oxidized cholesterol products (oxysterols), such as secosterol-A (secoA), which form covalent linkages preferentially with lysine residues and consequently modify protein function. The breadth of proteins modified by this oxysterol as well as the biological consequences in the lung are unknown. Using an alkynyl-tagged form of secosterol-A and shotgun proteomics, we identified NLR Family Pyrin Domain Containing 2 (NLRP2) to be adducted at lysine (K1019) in the terminal leucine-rich-repeat, a known regulatory region for NLR proteins. We characterized NLRP2 expression in airway epithelial cells and used CRISPR-Cas9 knockout and shRNA knockdown of NLRP2 for analysis of inflammasome complex activity and pro-inflammatory mediator production following O3 exposure. We observed an increase in caspase-1 activity in response to O3, which was not altered by knocked down NLRP2 expression. O3-induced pro-inflammatory gene expression for CXCL1, CXCL2, and IL8 was further enhanced in NLRP2 knockout cells. Together, our findings uncover NLRP2 as a highly abundant, key component of pro-inflammatory signaling pathways in airway epithelial cells and formation of oxysterol-NLRP2 adduct as a novel mediator of O3-induced inflammation.