Project description:The significance of non-histone lysine methylation in cell biology and human disease is an emerging area of research exploration, and small molecule inhibitors that selectively and potently target “writers” and “erasers” of methyl-lysine, such as the protein lysine mono-methyltransferase SMYD2, are active areas of drug discovery. It is therefore essential to clarify the substrates of these enzymes in cellular contexts in order to advance and to correctly understand the cellular mechanism(s) of action of these targets. Here, using stable isotopic labelling of amino acids in cell culture (SILAC) coupled with immunoaffinity enrichment of mono-methyl-lysine (Kme1) peptides and mass spectrometry, we report the most comprehensive and large-scale proteomic study of protein mono-methylation, comprising a total of 1032 Kme1 sites identified in esophageal squamous cell carcinoma (ESCC) cells and 1861 Kme1 sites in ESCC cells overexpressing SMYD2. Among these sites was a subset of 35 robust Kme1 sites that were potently down-regulated by both shRNA-mediated knockdown of SMYD2 and LLY-507, a small molecule inhibitor of SMYD2. In addition, we report specific protein sequence motifs that were enriched in Kme1 sites and that were also directly regulated by endogenous SMYD2 activity, indicating that the diversity of SMYD2 substrate specificity of SMYD2 exceeds previous expectations. Furthermore, we reveal that BTF3 and PDAP1 are novel and direct substrates of SMYD2, as well as AHNAK and AHNAK2, two large and highly-repetitive proteins directly and extensively mono-methylated by SMYD2 at several lysine residues. Collectively, our findings provide novel quantitative and insights into the cellular activity and substrate recognition of SMYD2 as well as the global landscape and regulation of protein mono-methylation in cells.

Project description:Here, we characterize the methyl-lysine (meK) proteome of anucleate blood platelets. With high-resolution, multiplex mass spectrometry methods, we identify 190 mono-, di- and tri-meK modifications on 150 different platelet proteins, including 28 quantifiable meK modifications consistently present in platelets from multiple individuals. In addition to identifying meK modifications on calmodulin (CaM), GRP78 and EF1A1 that have been previously characterized in other cell types, we also uncover more novel modifications on numerous other cytosolic proteins. Together, our results and analyses support roles for lysine methylation in mediating cytoskeletal, translational, secretory and other cytosolic cellular processes.

Project description:Characterization of CHMP2B methylation by the lysine methyl transferase SMYD2 : identification of the lysine methylated by SMYD2

Project description:Publication title: Distinct DNA methylation patterns characterize differentiated human embryonic stem cells and developing human fetal liver To investigate the role of DNA methylation during human development, we developed Methyl-seq, a method that assays DNA methylation at more than 90,000 regions throughout the genome. Performing Methyl-seq on human embryonic stem cells (hESCs), their derivatives and human tissues allowed us to identify several trends during hESC and in vivo liver differentiation. First, differentiation results in DNA methylation changes at a minimal number of assayed regions, both in vitro and in vivo (2-11%). Second, in vitro hESC differentiation is characterized by both de novo methylation and demethylation, whereas in vivo fetal liver development is characterized predominantly by demethylation. Third, hESC differentiation is uniquely characterized by methylation changes specifically at H3K27me3-occupied regions, bivalent domains and low-density CpG promoters (LCPs) suggesting that these regions are more likely to be involved in transcriptional regulation during hESC differentiation. Although both H3K27me3-occupied domains and LCPs are also regions of high variability in DNA methylation state during human liver development, these regions become highly unmethylated, which is a distinct trend from that observed in hESCs. Taken together, our results indicate that hESC differentiation has a unique DNA methylation signature that may not be indicative of in vivo differentiation. Keywords: Methyl-seq, hESC differentiation For data usage terms and conditions, please refer to http://www.genome.gov/27528022 and http://www.genome.gov/Pages/Research/ENCODE/ENCODEDataReleasePolicyFinal2008.pdf High-throughput sequencing of ES cell lines, ES-derived cells, and fetal and normal livers (17 samples). Raw data: SRA008154 http://www.ncbi.nlm.nih.gov/sites/entrez?db=sra&cmd=search&term=SRA008154

Project description:Protein methylation is involved in different processes including gene expression regulation, epigenetics, and nucleotide metabolism. Identification of methylated proteins is difficult as methyl groups are small, and do not introduce significant changes in protein hydrophobicity or charge state. The most effective analytical method to date is relative enrichment by pan-specific antibodies and methylation specific binding domains. Here, we present a novel and unbiased chemical strategy to enrich and identify sites of lysine and arginine methylations. This approach makes use of the property that methylation does not alter the charge state of lysine and arginine. This approach revealed over 793 methylation events including 211 arginine and 585 lysine methylation sites in HEK 293 Cells. This strategy proves to be convenient, effective and versatile, with the potential of analyzing other PTMs on both lysine and arginine.

Project description:Protein methylation has been implicated in many important biological contexts including signaling, metabolism, and transcriptional control. Despite the importance of this post- translational modification, the global analysis of protein methylation by mass spectrometry-based proteomics has not been extensively studied due to the lack of robust, well-characterized techniques for methyl-peptidemethyl peptide enrichment. Here, to better investigate protein methylation, we optimized and compared two methods for methyl-peptidemethyl peptide enrichment: immunoaffinity purification (IAP) and high pH strong cation exchange (SCX). Comparison of these methods revealed that they are largely orthogonal for monomethyl arginine (MMA), suggesting that the usage of both techniques is required to provide a global view of protein methylation. Using both IAP and SCX, we investigated changes in protein methylation downstream of protein arginine methyltransferase 1 (PRMT1). Together, these techniques allowed us to quantify over ~1,000 arginine methylation sites on 407 proteins. Of these methylation sites, PRMT1 knockdown resulted in significant changes to 110 arginine methylation sites on 59 proteins. In contrast, zero lysine methylation sites were significantly changed upon PRMT1 knockdown. In PRMT1 knockdown cells, 24 MMA sites exhibited both significant downregulation (ie, putative PRMT1-mediated MMA targets) and 63 significant upregulation (ie, putative PRMT1-mediated ADMA targets). PRMT1 knockdown induced significant changes in asymmetric dimethyl arginine (ADMA), consistent with being PRMT1 targets. Additionally, We also observed that PRMT1 knockdown induced significant increases in symmetric dimethyl arginine (SDMA) methylation, suggesting that loss of PRMT1 activity allows scavenging of PRMT1 substrates by Type II PRMTs. Analysis of the subcellular localization and protein function of the significantly changing methyl-proteins revealed that the majority of PRMT1 substrates are localized to the nucleus and involved in RNA and DNA binding. Taken together, our results suggest that deep protein methylation profiling by mass spectrometry requires orthogonal enrichment techniques, identify novel PRMT1 methylation targets, and highlight in order to understand the dynamic interplay between methyltransferases in mammalian cells.

Project description:Histone lysine methylation is an important post-translational modifications (PTMs) that plays critical roles in numerous biological processes with abnormal histone lysine methylation having been associated with developmental defects and human diseases. The primary amine of all lysine residues can be mono-, di-, or trimethylated and the extent of methylation at a single site is shown to inspire unique protein function. Moreover, histone lysine methylation can activate or repress transcription depending on which sites are modified and to what degree. Therefore, a comprehensive stoichiometric analysis of histone lysine methylation is necessary to fully elucidate its function. As histones are lysine-rich and highly-hydrophilic proteins (Figure S1), trypsin digestion of histones results in small, hydrophilic peptides which often suffer from substantial losses during sample preparation, and are difficult to detect in conventional reversed phase LC-MS. Additionally, trypsin fails to cleave histone proteins when lysine residues are methylated, resulting in inaccurate estimations of site occupancy and methylation extent. Previously, lysine propionylation labeling has been developed to overcome this drawback and facilitate quantitative analysis of PTMs that frequently occur on the lysine residue of histones. However, propionylation labeling of unmodified and monomethylated lysine residues causes a mismatch in hydrophobicity and charge state between labeled and unlabeled di-/trimethylated peptides. This mismatch forces retention time and signal intensity differences that inspire inaccurate quantitation and miscalculation of site occupancy. In this work, we developed a method that facilitates blocking of free lysine groups and discrimination of native lysine methylation, enables accurate calculation of the histone lysine methylation stoichiometry.

Project description:Publication title: Distinct DNA methylation patterns characterize differentiated human embryonic stem cells and developing human fetal liver; To investigate the role of DNA methylation during human development, we developed Methyl-seq, a method that assays DNA methylation at more than 90,000 regions throughout the genome. Performing Methyl-seq on human embryonic stem cells (hESCs), their derivatives and human tissues allowed us to identify several trends during hESC and in vivo liver differentiation. First, differentiation results in DNA methylation changes at a minimal number of assayed regions, both in vitro and in vivo (2-11%). Second, in vitro hESC differentiation is characterized by both de novo methylation and demethylation, whereas in vivo fetal liver development is characterized predominantly by demethylation. Third, hESC differentiation is uniquely characterized by methylation changes specifically at H3K27me3-occupied regions, bivalent domains and low-density CpG promoters (LCPs) suggesting that these regions are more likely to be involved in transcriptional regulation during hESC differentiation. Although both H3K27me3-occupied domains and LCPs are also regions of high variability in DNA methylation state during human liver development, these regions become highly unmethylated, which is a distinct trend from that observed in hESCs. Taken together, our results indicate that hESC differentiation has a unique DNA methylation signature that may not be indicative of in vivo differentiation. Experiment Overall Design: lumina gene expression beadchips of human ES cell lines, ES-derived cells, and normal liver (15 samples). High-throughput sequencing of ES cell lines, ES-derived cells, and fetal and normal livers (17 samples). Raw data: SRA008154 http://www.ncbi.nlm.nih.gov/sites/entrez?db=sra&cmd=search&term=SRA008154

Project description:SILAC labeled HT-1080 cell lysate (K0R0 and K8R10) were treated with active or catalytic inactive SETMAR methyltransferase enzyme. Samples were combined and proteins modified by methyl-lysine enriched by 3xMBT. Quantitative comparison identified candidate proteins with increase methylation following incubation with SETMAR.

Project description:The covalent attachment of methyl groups to the side-chain of arginine residues is known to play essential roles in regulation of transcription, protein function and RNA metabolism. The specific N-methylation of arginine residues is catalyzed by a small family of gene products known as protein arginine methyltransferases; however, very little is known about which arginine residues become methylated on target substrates. Here we describe an unbiased methodology that combines single-step immunoenrichment of methylated peptides with high-resolution mass spectrometry to identify endogenous arginine mono-methylation (MMA) sites. We thereby identify 1,027 site-specific MMA sites on 494 human proteins, discovering numerous novel mono-methylation targets and confirming the majority of currently known MMA substrates. Nuclear RNA-binding proteins involved in RNA processing, RNA localization, transcription, and chromatin remodeling are prominently found modified with MMA. Despite this, MMA sites prominently are located outside RNA-binding domains as compared to the proteome-wide distribution of arginine residues. Quantification of arginine methylation in cells treated with Actinomycin D uncovers strong site-specific regulation of MMA sites during transcriptional arrest. Interestingly, several MMA sites are down-regulated after a few hours of under transcriptional arrest. In contrast, the corresponding di-methylation or protein expression level is not altered in expression, confirming that MMA sites contain regulated functions on their own. Collectively, we present a site-specific MMA dataset in human cells and demonstrate for the first time that MMA is a dynamic post-translational modification regulated during transcriptional arrest by a hitherto uncharacterized arginine demethylase. Data analysis: All raw data analysis was performed with MaxQuant software suite version 1.2.6.20 supported by the Andromeda search engine. Data was searched against a concatenated target/decoy (forward and reversed) version of the UniProtKB Human database encompassing 71,434 protein entries. Mass tolerance for searches was set to maximum 7 ppm for peptide masses and 20 ppm for HCD fragment ion masses. Data was searched with carbamidomethylation as a fixed modification and protein N-terminal acetylation, methionine oxidation and mono-methylation on lysine and arginine as variable modifications. A maximum of three mis-cleavages was allowed while requiring strict trypsin specificity, and only peptides with a minimum sequence length of seven were considered for further data analysis. Peptide assignments were statistically evaluated in a Bayesian model on the basis of sequence length and Andromeda score. Only peptides and proteins with a false discovery rate (FDR) of less than 1% were accepted, estimated on the basis of the number of accepted reverse hits. Protein sequences of common contaminants such as human keratins and proteases used were added to the database.