Project description:Posttranslational modification with small ubiquitin-like modifiers (SUMOs) alters the function of proteins involved in diverse cellular processes. SUMOs are conjugated to lysine residues in target proteins by SUMO-specific enzymes. Although proteomic studies have identified hundreds of sumoylated substrates, methods to identify the modified lysines on a proteome-wide scale are lacking. We developed a method that enabled large-scale identification of sumoylated lysines and involved the expression of polyhistidine (6His)–tagged SUMO2 with Thr90 mutated to Lys. Digestion of 6His-SUMO2(T90K)–modified proteins with an endoproteinase Lys-C produces a diGly remnant on SUMO2(T90K)-conjugated lysines, enabling a specific immunoprecipitation of modified peptides with diGly-Lys-specific antibody and producing a unique mass-to-charge signature. Mass spectrometry analysis of SUMO2-enriched peptides from human cell lysates revealed more than 1000 sumoylated lysines in 539 proteins, including many functionally related proteins involved in cell cycle, transcription, and DNA repair. Not only can this strategy be used to study the dynamics of sumoylation and other potentially similar posttranslational modifications, but also, these data provide an unprecedented resource for future research on the role of sumoylation in cellular physiology and disease.

Project description:In eukaryotes, the conjugation of proteins to the small ubiquitin-like modifier SUMO regulates numerous cellular functions. A proportion of SUMO conjugates are targeted for degradation by SUMO-targeted ubiquitin ligases (STUbLs) and it has been proposed that the ubiquitin-selective chaperone Cdc48/p97-Ufd1-Npl4 facilitates this process. However, the extent to which the two pathways overlap, and how the substrates are selected, remains unknown. Here, we address these questions in fission yeast through proteome-wide analyses of SUMO modification sites. We identify over a thousand sumoylated lysines in a total of 468 proteins and quantify changes occurring in the SUMO modification status when the STUbL or Ufd1 pathways are compromised by mutations. The data suggest the coordinated processing of several classes of SUMO conjugates, many dynamically associated with centromeres or telomeres. They provide new insights into subnuclear organization and chromosome biology, and, altogether, constitute an extensive resource for the molecular characterization of SUMO function and dynamics.

Project description:We have identified the plant biflavonoid hinokiflavone as an inhibitor of splicing in vitro and modulator of alternative splicing in cells. Chemical synthesis confirms hinokiflavone is the active molecule. Hinokiflavone inhibits splicing in vitro by blocking spliceosome assembly, preventing formation of the B complex. Cells treated with hinokiflavone show altered subnuclear organization specifically of splicing factors required for A complex formation, which relocalize together with SUMO1 and SUMO2 into enlarged nuclear speckles containing polyadenylated RNA. Hinokiflavone increases protein SUMOylation levels, both in in vitro splicing reactions and in cells. Hinokiflavone also inhibited a purified, E. coli expressed SUMO protease, SENP1, in vitro, indicating the increase in SUMOylated proteins results primarily from inhibition of de-SUMOylation. Using a quantitative proteomics assay we identified many SUMO2 sites whose levels increased in cells following hinokiflavone treatment, with the major targets including 6 proteins that are components of the U2 snRNP and required for A complex formation.

Project description:To identify sites of ubiquitination in Myc-6His-Tagged forms of RAD23A and UBQLN1 for wild-type and forms with some arginine residues mutated to lysines (see FASTA file for details).

Project description:The SUMO protease SENP6 disassembles SUMO chains and thus SENP6 depletion should lead to the extension of SUMO polymers on substrates. We have used a proteomic method to identify putative SENP6 substrates based on increased apparent molecular weight after SENP6 depletion. This method uses SDS-PAGE fractionation of 6His-SUMO2 purifications from cells and slicing of gels into multiple pieces before tryptic digestion and MS analysis. Gel slices are assigned an average Apparent MW based on molecular weight standards (run in a separate lane), and this information combined with protein intensities to give every protein an Apparent MW both in the presence of SENP6 and its ablation via SiRNA. The difference between the two values allows us to understand which proteins become more SUMOylated upon SENP6 knock-down.

Project description:Ligation is accomplished by a small set of SUMO E3 ligases, with the SAP-MIZ domain-containing (SIZ)-1 and METHYL METHANESULFONATE-SENSITIVE (MMS)-21 ligases having critical roles in stress protection and DNA endoreduplication, respectively. To help identify their corresponding Arabidopsis targets, we combined siz1 and mms21 mutants with proteomic analyses of SUMOylated proteins enriched using an engineered 6His-SUMO1. Through multiple datasets from seedlings grown at normal temperatures or exposed to heat stress, we identified over 1,000 SUMO targets, most of which are nuclear localized. Whereas no targets could be assigned to MMS21, suggesting that it modifies only one or a few low abundance proteins, numerous targets could be assigned to SIZ1, including major transcription factors, co-activators/repressors, and chromatin modifiers connected to abiotic and biotic stress defense, some of which associate into multi-subunit regulatory complexes.

Project description:Small ubiquitin-like modifiers (SUMOs) and ubiquitin are frequent post-translational modifications of proteins that play pivotal roles in all cellular processes. We previously reported mass spectrometry-based proteomics methods that enable profiling of lysines modified by endogenous SUMO or ubiquitin in an unbiased manner, without requiring genetic engineering. Here we investigated the applicability of precursor mass filtering enabled by MaxQuant.Live (MQL) to our SUMO and ubiquitin proteomics workflows, which efficiently avoided sequencing of precursors too small to be modified but otherwise indistinguishable by mass-to-charge ratio. Using peptide mass filtering, we achieved much higher precursor selectivity, ultimately resulting in up to 30% more SUMO and ubiquitin sites identified from replicate samples. Real-time ‘untargeting’ of unmodified peptides by MQL resulted in 90% SUMO-modified precursor selectivity from a 25% pure sample, demonstrating great applicability for digging deeper into ubiquitin-like modificomes. We adapted the mass filtering strategy to the new Exploris 480 mass spectrometer, achieving comparable gains in SUMO precursor selectivity and identification rates. Collectively, mass filtering via MQL significantly increased identification rates of SUMO- and ubiquitin-modified peptides from the exact same samples, without the requirement for prior knowledge or spectral libraries.

Project description:Small ubiquitin-like modifiers (SUMOs) are post-translational modifications (PTMs) that regulate nuclear cellular processes. Here we used an augmented K0–SUMO proteomics strategy to identify 40,765 SUMO acceptor sites and quantify their fractional contribution for 6,747 human proteins. Structural–predictive analyses revealed that lysines residing in disordered regions are preferentially targeted by SUMO, in notable contrast to other widespread lysine modifications. In our data set, we identified 807 SUMOylated peptides that were co-modified by phosphorylation, along with dozens of SUMOylated peptides that were co-modified by ubiquitylation, acetylation and methylation. Notably, 9% of the identified SUMOylome occurred proximal to phosphorylation, and numerous SUMOylation sites were found to be fully dependent on prior phosphorylation events. SUMO-proximal phosphorylation occurred primarily in a proline-directed manner, and inhibition of cyclin-dependent kinases dynamically affected co-modification. Collectively, we present a comprehensive analysis of the SUMOylated proteome, uncovering the structural preferences for SUMO and providing system-wide evidence for a remarkable degree of cross-talk between SUMOylation and other major PTMs. (part 2)

Project description:Small ubiquitin-like modifiers (SUMOs) are post-translational modifications (PTMs) that regulate nuclear cellular processes. Here we used an augmented K0–SUMO proteomics strategy to identify 40,765 SUMO acceptor sites and quantify their fractional contribution for 6,747 human proteins. Structural–predictive analyses revealed that lysines residing in disordered regions are preferentially targeted by SUMO, in notable contrast to other widespread lysine modifications. In our data set, we identified 807 SUMOylated peptides that were co-modified by phosphorylation, along with dozens of SUMOylated peptides that were co-modified by ubiquitylation, acetylation and methylation. Notably, 9% of the identified SUMOylome occurred proximal to phosphorylation, and numerous SUMOylation sites were found to be fully dependent on prior phosphorylation events. SUMO-proximal phosphorylation occurred primarily in a proline-directed manner, and inhibition of cyclin-dependent kinases dynamically affected co-modification. Collectively, we present a comprehensive analysis of the SUMOylated proteome, uncovering the structural preferences for SUMO and providing system-wide evidence for a remarkable degree of cross-talk between SUMOylation and other major PTMs. (part 1)

Project description:Small ubiquitin-like modifiers (SUMOs) are post-translational modifications that play crucial roles in most cellular processes. While methods exist to study exogenous SUMOylation, large-scale characterization of endogenous SUMO has remained technically daunting. Here, we describe a proteomics approach facilitating system-wide and in vivo identification of lysines modified by endogenous and native SUMO2/3. We identified 14,869 endogenous SUMO sites in human cells during heat stress and proteasomal inhibition, and mapped 1,963 SUMO sites across eight mouse tissues; brain, heart, kidney, lung, liver, muscle, spleen, and testis. Quantification of the SUMO equilibrium highlighted striking differences in SUMO metabolism, between cells and tissues. Targeting preferences of SUMO varied across different organ types, coinciding with markedly differential SUMOylation states of all enzymes involved in the SUMO conjugation cascade. Collectively, our systemic investigation details the SUMOylation architecture across species and organs and provides a resource of endogenous SUMOylation sites on factors important in organ-specific functions and disease.