Project description:Steady-state levels of SUMO post-translational modifications are determined by the balance between sumoylation and desumoylation machineries. Eukaryotic cells can modulate cellular levels of SUMO conjugation by regulating the enzymes involved in these processes. In budding yeast, for example, heat shock induces a global increase in SUMO conjugation, at least in part by triggering the degradation of the major SUMO protease, Ulp1. ChIP-seq analyses by our group and others have identified hundreds of sites across the yeast genome that contain sumoylated proteins, including the promoter regions of 265 protein-coding genes, consistent with a role for sumoylation in regulating transcription widely. Paradoxically, despite the overall increase in SUMO conjugation upon heat shock, chromatin-associated sumoylation decreases at most of these loci when temperatures rise. Here, we show that a similar pattern is observed in a strain expressing a partially defective form of Ulp1, which exhibits constitutively elevated SUMO conjugation yet reduced sumoylation at sites across the genome. One possible explanation is that reduced Ulp1 activity, whether through heat shock-mediated degradation or mutation, indeed elevates sumoylation of chromatin-bound proteins, but this then promotes their rapid dissociation from chromatin. This model aligns with our previous findings that sumoylation triggers the release of the Gcn4 and Sko1 transcription factors from their genomic binding sites.

Project description:Many transcription-related proteins are known to be modified by SUMO post-translational modification in yeast, plants, humans and other eukaryotes. We are interested in understanding how cells use sumoylation to regulate transcription of specific genes and globally. To explore this, we carried out ChIP-seq analysis to determine how genomic levels of RNA polymerase II (RNAPII) change when cellular levels of sumoylation are greatly reduced in budding yeast. Compared to wild-type yeast, RNAP occupancy in the sumoylation-deficient ubc9-6 strain was significantly altered for hundreds of genes. Among the genes with the most elevated levels of RNAPII are those involved in translation and ribosome biogenesis, including most ribosomal protein genes. On the other hand, many genes involved in small molecule and amino acid metabolism and biosynthesis showed reduced RNAPII levels in ubc9-6. Exposure of yeast to heat shock is known to cause a widespread change to RNAPII occupancy across the genome. To examine whether cellular sumoylation plays a role in this process, RNAPII ChIP-seq was performed in wild-type and ubc9-6 strains after a brief heat shock. Strikingly, the sumoylation deficient strain showed a far more dramatic redistribution of RNAPII across the genome, with significantly more genes showing a heat-shock induced increase or decrease in RNAPII occupancy. These results imply that cellular sumoylation levels have a significant impact on the regulation of transcription genome-wide, and that normal sumoylation levels are needed to restrain the vast redistribution of RNAPII that occurs in response to heat shock.

Project description:SUMOylation is a reversible post-translational modification regulating all nuclear processes. Identification of SUMOylation sites by mass spectrometry has been hampered by bulky tryptic fragments, which thus far necessitated the use of mutated SUMO. Here, we present a dataset generated through a SUMO-specific protease-based methodology which circumvents this problem, dubbed Protease-Reliant Identification of SUMO Modification (PRISM). PRISM allows for detection of SUMOylated proteins as well as identification of specific sites of SUMOylation while using wild-type SUMO. The method is generic and could be widely applied to study lysine post-translational modifications. PRISM was employed in combination with high-resolution mass spectrometry to identify SUMOylation sites from HeLa cells under standard growth conditions and in response to heat shock. 751 wild-type SUMOylation sites on endogenous proteins were identified, including 200 dynamic SUMO sites in response to heat shock. Thus, we have developed the first method capable of quantitatively studying wild-type mammalian SUMO at the site-specific and system-wide level.

Project description:SUMOylation is a reversible post-translational modification regulating all nuclear processes. Identification of SUMOylation sites by mass spectrometry has been hampered by bulky tryptic fragments, which thus far necessitated the use of mutated SUMO. Here, we present a dataset generated through a SUMO-specific protease-based methodology which circumvents this problem, dubbed Protease-Reliant Identification of SUMO Modification (PRISM). PRISM allows for detection of SUMOylated proteins as well as identification of specific sites of SUMOylation while using wild-type SUMO. The method is generic and could be widely applied to study lysine post-translational modifications. PRISM was employed in combination with high-resolution mass spectrometry to identify SUMOylation sites from HeLa cells under standard growth conditions and in response to heat shock. 751 wild-type SUMOylation sites on endogenous proteins were identified, including 200 dynamic SUMO sites in response to heat shock. Thus, we have developed the first method capable of quantitatively studying wild-type mammalian SUMO at the site-specific and system-wide level.

Project description:Heat shock induces rapid modification of proteins with SUMO2/3. This study concentrated in charaterizing how these changes are reflected on SUMOylation of chromatin bound proteins, trancsription, and chromatin binding of SUMO ligase PIAS1.

Project description:The role of stress-induced increases in SUMO2/3 conjugation during the Heat Shock Response (HSR) has remained enigmatic. We investigated SUMO signal transduction at the proteomic and functional level during the HSR in the context of cells depleted of proteostasis network components via chronic Heat Shock Factor 1 inhibition versus cells with normal pro-teostasis networks. In the recovery phase post-heat shock, SUMO2/3 conjugation remained high for a prolonged time in cells lacking sufficient chaperones. Similar results were obtained upon inhibiting HSP90, indicating that increased chaperone activity during the HSR is critical for the recovery of SUMO2/3 levels post-heat shock. Proteasome inhibition during the re-covery phase likewise prolonged SUMO2/3 conjugation, indicating that stress-induced SU-MO2/3 targets are subsequently degraded by the ubiquitin-proteasome system. Functionally, we show that SUMOylation profoundly enhances solubility of target proteins upon heat shock in vitro. Collectively, our results implicate SUMO2/3 as a rapid response factor protecting the proteome from aggregation upon proteotoxic stress.

Project description:SUMOylation is a reversible post-translational modification essential for genome stability. Using high-resolution mass spectrometry, we have studied global SUMOylation in mammalian cells and in a site-specific manner, identifying a total of over 4,300 SUMOylation sites in over 1,600 proteins. Moreover, for the first time in excess of 1,000 SUMOylation sites were identified under standard growth conditions. SUMOylation dynamics were quantitatively studied in response to SUMO protease inhibition, proteasome inhibition and heat shock.

Project description:We profiled SUMO1 and SUMO2 modified proteins in distal convoluted tubule (mpkDCT) as a precursor to targeted approaches to assess SUMO function. SUMO levels in cells following heat shock and treatment with deSUMOylation inhibitors were assessed.

Project description:We profiled SUMO1 and SUMO2 modified proteins in cortical collecting duct (mpkCCD) as a precursor to targeted approaches to assess SUMO function. SUMO levels in cells following heat shock and treatment with deSUMOylation inhibitors were assessed.

Project description:Heat shock induces rapid modification of proteins with SUMO2/3. This study concentrated in charaterizing how these changes are reflected on SUMOylation of chromatin bound proteins, trancsription, and chromatin binding of SUMO ligase PIAS1. Comparison of chromatin SUMO2/3 modification pattern in non-stressed and heat shocked K562 and VCaP cells. All samples were done as biological replicates. In K562 cells, SUMO2/3 ChIP-seq was done in non-stressed (37C) and heat shocked (30min at 43C) cells. The effect of heat shock factor 1 (HSF1) to chromatin SUMOylation in HS was studied in HSF1 silenced (shHSF1) K562 cells (non-stressed vs. heat shocked) using scramble shRNA transfected cells as control (shSCR). SUMO2/3, SUMO ligase PIAS1,and RNA polymerase II binding in HS (30 min at 43C) and recovery from HS (1h at 37C after HS) was studied using ChIP-seq. Effect of PIAS1 for chromatin SUMOylation was studied in PIAS1 silenced (siRNA for PIAS1, siPIAS1) cells (non-stressed or heat shocked) using non-targeting siRNA transfected cells as a control (siNON). Effect of SUMOylation to chromatin binding of RNA polymerase II was studied in UBE2I silenced (siRNA for UBE2I) and control (non-targeting siRNA transfected, siNON) VCaP cells (non-stressed or heat shocked). Effect of transtription inhibition for chromatin SUMOylation was studied in TRP (triptolide; 1 micromolar, 3h) and DRB (5,6-Dichlorobenzimidazole 1-beta-D-ribofuranosidase; 100 micromolar, 3h) treated VCaP cells. GRO-seq was used to determine HS-induced changes in nascent transcription in K562 cells.