Project description:SUMOylation is an essential protein modification that regulates numerous biological processes, but what constitutes its most critical functions in the cell remains unclear. Here, using genome-scale CRISPR-Cas9-based synthetic lethality screens, we show that the BLM-TOP3A-RMI1-RMI2 (BTRR)-PICH pathway, which resolves ultra-fine anaphase DNA bridges (UFBs) arising from catenated DNA structures, and NIP45 (NFATC2IP) display a synthetic lethal interaction in human cells and are essential for proliferation when SUMOylation is impaired. NIP45 and SUMOylation prevent excessive UFB formation that leads to extensive binucleation when BTRR-PICH-dependent UFB resolution is defective, by orchestrating an interphase pathway for converting DNA catenanes into DNA double-strand breaks that trigger G2 arrest via canonical ATM/ATR-dependent DNA damage signaling. NIP45 exerts its crucial function in this pathway by acting as a cofactor for specific SUMOylation processes that are at least in part targeted to the SLX4 multi-nuclease complex, which may facilitate nucleolytic DNA catenane resolution. Our findings establish an essential role of SUMO signaling in underpinning cell proliferation by counteracting the deleterious threat to faithful chromosome segregation posed by toxic DNA catenanes arising in virtually every cell cycle, via non-epistatic NIP45- and BTRR-PICH-dependent pathways.

Project description:The Protein Inhibitor of Activated STAT 1 (PIAS1) is an E3 SUMO ligase that plays important roles in various cellular pathways, including STAT signaling, p53 pathway, and the steroid hormone signaling pathway. PIAS1 can SUMOylate PML (at Lys-65 and Lys-160) and PML-RARα promoting their ubiquitin-mediated degradation. Increasing evidence shows that PIAS1 is overexpressed in various human malignancies, such as prostate and lung cancers. To understand the mechanism of action of PIAS1, we developed a quantitative SUMO proteomic approach to identify potential substrates of PIAS1 in a system-wide manner. Our analyses enabled the profiling of 983 SUMO sites on 544 proteins, of which 204 SUMO sites on 123 proteins were identified as putative PIAS1 substrates. These substrates were found to be involved in different cellular processes, including transcriptional regulation, DNA binding and cytoskeleton dynamics. Further functional studies on Vimentin (VIM), a type III intermediate filament protein involved in cytoskeleton organization and cell motility, revealed that PIAS1 exerts its effects on cell migration and cell invasion through the SUMOylation of VIM at Lys-439 and Lys-445 residues. VIM SUMOylation was necessary for its dynamic disassembly, and cells expressing a non-SUMOylatable VIM mutant showed reduced levels of proliferation and migration. Our approach not only provides a novel strategy for the identification of E3 SUMO ligase substrates, but also yields valuable biological insights into the unsuspected role of PIAS1 and VIM SUMOylation on cell motility.

Project description:Protein inhibitor of activated STAT (PIAS) are E3 SUMO ligases playing important roles in protein stability and signaling transduction pathways. PIAS proteins are overexpressed in the triple-negative breast cancer cell line MDA-MB-231, and PIAS knockout (KO) results in a reduction in cell proliferation and cell arrest in S phase. However, the molecular mechanisms underlying PIAS functions in cell proliferation and cell cycle remain largely unknown. Here, we used quantitative SUMO proteomics to explore the regulatory role of PIAS SUMO E3 ligases upon CRISPR/Cas9 KO of individual PIAS. A total of 1422 sites were identified, and around 10% of SUMO sites were regulated following KO of one or more PIAS genes. We identified protein substrates that were either specific to individual PIAS ligase or regulated by several PIAS ligases. Ki-67 and TOP2A, which are involved in cell proliferation and epithelial-to-mesenchymal transition, are SUMOylated at several lysine residues by all PIAS ligases, suggesting a level of redundancy between these proteins. Confocal microscopy and biochemical experiments revealed that SUMOylation regulated TOP2A protein stability, while this modification is involved in the recruitment of Ki-67 nucleolar proteins containing SUMO interacting motif. These results provide novel insights into both the redundant and specific regulatory mechanisms of cell proliferation and cell cycle mediated by PIAS SUMO E3 ligases.

Project description:Loss of nutrient supply elicits alterations of the SUMO proteome and sumoylation is crucial to various cellular processes including transcription. However, the physiological significance of sumoylation of transcriptional regulators is unclear. To begin clarifying this, we mapped the SUMO proteome under nitrogen-limiting conditions in Saccharomyces cerevisiae. Interestingly, several RNA polymerase III (RNAPIII) components are major SUMO targets under normal growth conditions, including Rpc53, Rpc82, and Ret1, and nutrient starvation results in rapid desumoylation of these proteins. These findings are supported by ChIP-seq experiments that show that SUMO is highly enriched at tDNA genes. Furthermore, RNA-seq experiments revealed that preventing sumoylation results in significantly decreased tRNA transcription. TORC1 inhibition resulted in the same effect, and our data indicate that the SUMO and TORC1 pathways are both required for robust tDNA expression. Importantly, tRNA transcription was strongly reduced in cells expressing a non-sumoylatable Rpc82-4KR mutant, which correlated with a misassembled RNAPIII transcriptional complex. Our data suggest that in addition to TORC1 activity, sumoylation of RNAPIII is key to reaching full translational capacity under optimal growth conditions.

Project description:Despite the pleiotropic role of SUMOylation, this pathway mainly functions to repress innate immunity in myeloid cells. Inactivating SUMOylation triggers a potent basal type I interferon (IFN1) response, amplified and coupled with an inflammatory response upon stimulation. These findings transposed to pre-clinical models with the demonstration that SUMOylation inhibitors (SUMOi) activate antitumor immunity in an IFN1-dependent manner. Yet, how SUMOylation represses immune signaling remains largely unknown. We identified murine MORC3, a critical transcriptional repressor of the IFNB1 gene, as the top SUMO2/3 substrate in myeloid cells. We show that, in human monocytes, SUMO functions to repress basal IFNB1 in cis through an atypical/repeated MORC3-regulated element (MRE) concentrating/homing multiple PU.1 binding motifs. Inhibiting SUMOylation induces a 3D genome reorganization centered on the MRE, which, in turn, acquires both insulator and PU.1-driven enhancer activities, together with loss of H3.3 and H3K9me3 repressive marks and increased PU-1 binding. Paradoxically, MORC3, that binds PU.1, is massively recruited, yet unable to repress the MRE. Finally, we show that both MORC3 ATPase cycle and SUMOylation are critical for full MORC3 repressive activity. Our study identifies an unconventional mechanism in which SUMO, in concert with MORC3, orchestrates a metastable H3.3/H3K9me3 heterochromatin state on a multi-PU.1 binding platform element to shutdown unscheduled myeloid-specific IFN1 response.

Project description:Despite the pleiotropic role of SUMOylation, this pathway mainly functions to repress innate immunity in myeloid cells. Inactivating SUMOylation triggers a potent basal type I interferon (IFN1) response, amplified and coupled with an inflammatory response upon stimulation. These findings transposed to pre-clinical models with the demonstration that SUMOylation inhibitors (SUMOi) activate antitumor immunity in an IFN1-dependent manner. Yet, how SUMOylation represses immune signaling remains largely unknown. We identified murine MORC3, a critical transcriptional repressor of the IFNB1 gene, as the top SUMO2/3 substrate in myeloid cells. We show that, in human monocytes, SUMO functions to repress basal IFNB1 in cis through an atypical/repeated MORC3-regulated element (MRE) concentrating/homing multiple PU.1 binding motifs. Inhibiting SUMOylation induces a 3D genome reorganization centered on the MRE, which, in turn, acquires both insulator and PU.1-driven enhancer activities, together with loss of H3.3 and H3K9me3 repressive marks and increased PU-1 binding. Paradoxically, MORC3, that binds PU.1, is massively recruited, yet unable to repress the MRE. Finally, we show that both MORC3 ATPase cycle and SUMOylation are critical for full MORC3 repressive activity. Our study identifies an unconventional mechanism in which SUMO, in concert with MORC3, orchestrates a metastable H3.3/H3K9me3 heterochromatin state on a multi-PU.1 binding platform element to shutdown unscheduled myeloid-specific IFN1 response.

Project description:Despite the pleiotropic role of SUMOylation, this pathway mainly functions to repress innate immunity in myeloid cells. Inactivating SUMOylation triggers a potent basal type I interferon (IFN1) response, amplified and coupled with an inflammatory response upon stimulation. These findings transposed to pre-clinical models with the demonstration that SUMOylation inhibitors (SUMOi) activate antitumor immunity in an IFN1-dependent manner. Yet, how SUMOylation represses immune signaling remains largely unknown. We identified murine MORC3, a critical transcriptional repressor of the IFNB1 gene, as the top SUMO2/3 substrate in myeloid cells. We show that, in human monocytes, SUMO functions to repress basal IFNB1 in cis through an atypical/repeated MORC3-regulated element (MRE) concentrating/homing multiple PU.1 binding motifs. Inhibiting SUMOylation induces a 3D genome reorganization centered on the MRE, which, in turn, acquires both insulator and PU.1-driven enhancer activities, together with loss of H3.3 and H3K9me3 repressive marks and increased PU-1 binding. Paradoxically, MORC3, that binds PU.1, is massively recruited, yet unable to repress the MRE. Finally, we show that both MORC3 ATPase cycle and SUMOylation are critical for full MORC3 repressive activity. Our study identifies an unconventional mechanism in which SUMO, in concert with MORC3, orchestrates a metastable H3.3/H3K9me3 heterochromatin state on a multi-PU.1 binding platform element to shutdown unscheduled myeloid-specific IFN1 response.

Project description:Recent advances in synthetic mammalian embryo models have opened new avenues to understand the complex events controlling lineage specification and morphogenetic processes occurring during peri-implantation and early organogenesis. Two main strategies have been developed to build embryo-like structures (ELSs): by assembling extraembryonic and embryonic stem cells (ESCs) or by subjecting ESCs to various morphogens. Here, we show that mouse ESCs solely exposed to chemical inhibition of SUMOylation, a post-translational modification which acts as a general chromatin barrier to cell fate transitions, generates ELSs comprising both anterior neural and trunk-associated regions. HypoSUMOylation-instructed ESCs first give rise to adherent spheroids which, once in suspension, self-organize into gastrulating structures containing cell types spatially and functionally related to embryonic and extraembryonic compartments. Alternatively, spheroids cultured in an optimized droplet-microfluidic device form elongated structures that undergo axial organization reminiscent of natural embryo morphogenesis. Single-cell RNA-sequencing further revealed a variety of cellular lineages including properly positioned anterior neuronal cell types, Schwann cell precursors and paraxial mesoderm segmented into somite-like structures. Mechanistically, transient SUMOylation suppression gradually increases DNA methylation genome-wide and repressive marks deposition at Nanog, enhancing ESC plasticity. Our approach provides a proof of principle for a potential strategy to study early embryogenesis by targeting molecular roadblocks of cell fate change to shape multicellular architecture.

Project description:SUMO1 CHIP-seq experiment was performed in untreated hiPSC line - ChiPS4, to determine the exact locations of chromatin bound SUMO1 in these cells, thus providing information about the landscape of SUMOylation of protein targets on chromatin in human pluripotent cells and as such allowing for investigation of the role of SUMO1 in regulation of chromatin state.

Project description:PU.1 is a prototype master transcription factor (TF) of hematopoietic cell differentiation with diverse roles in different lineages. Analysis of its genome-wide binding pattern across PU.1 expressing cell types revealed manifold cell type-specific binding patterns. They are not consistent with the epigenetic and chromatin constraints to PU.1 binding observed in vitro, suggesting that PU.1 requires auxiliary factors to access DNA in vivo. Using a model of transient mRNA expression we show that PU.1 induction leads to the extensive remodeling of chromatin, redistribution of partner transcription factors and rapid initiation of a myeloid gene expression program in heterologous cell types. By probing PU.1 mutants for defects in chromatin access and screening for PU.1 proximal proteins in vivo, we found that its N-terminal acidic domain was required for the recruitment of SWI/SNF remodeling complexes, de novo chromatin access and stable binding as well as the redistribution of partner TFs.