Project description:Post-translational modification by SUMO is a key regulator of cell identity. In mouse embryonic fibroblasts (MEFs), SUMO impedes reprogramming to pluripotency, while in embryonic stem cells (ESCs), it represses the emergence of totipotent-like cells, suggesting that SUMO targets distinct substrates to preserve somatic and pluripotent states. Using MS-based proteomics, we show that the composition of endogenous SUMOylomes differs dramatically between MEFs and ESCs. In MEFs, SUMO2/3 targets proteins associated with canonical SUMO functions, such as splicing, and transcriptional regulators driving somatic enhancer selection. In contrast, in ESCs, SUMO2/3 primarily modifies highly interconnected repressive chromatin complexes, thereby preventing chromatin opening and transitioning to totipotent-like states. We also characterize several SUMO-modified pluripotency factors and show that SUMOylation of Dppa2 and Dppa4 impedes the conversion to 2-cell-embryo-like states. Altogether, we propose that rewiring the repertoire of SUMO target networks is a major driver of cell fate decision during embryonic development.

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:Meiosis, a reductional cell division, relies on precise initiation, maturation and resolution of crossovers (COs)-connections between homologs chromosomes-to ensure their accurate segregation during metaphase I. This process is finely regulated in eukaryotes by the interplay of RING-E3 ligases such as Rnf212 and Hei10 in mammals. In this study, we functionally characterized a novel RNF212B E3 ligase. RNF212B co-localizes and interacts with RNF212 forming numerous small foci at zygotene. These consolidate into larger foci at mature COs, colocalizing with Hei10 and MLH1 at pachytene on a synapsis-dependent and DSB-independent manner. Moreover, Rnf212b interacts with pro-COs proteins such as Tex11, MSH4 and RPA and other recombination proteins. Genetically, RNF212B foci depend on the presence of RNF212 and MSH4 but not on Hei10 and CNTD1. Rnf212b-deficient and -enzymatic-dead mutant mice exhibit modest synapsis defects a reduction in pro-CO factors (MSH4, TEX11, RPA, MZIP2) and a complete loss of MLH1-staining of COs, resulting in metaphase I with most univalents. Double mutants for RNF212b and RNF212 exhibit an identical phenotype, while double heterozygous demonstrate a dosage-dependent reduction in the number of COs relative to the single mutant, indicating a functional interplay between both paralogs. SUMOylome analysis of testis from Rnf212b mutants and pull-down analysis of Sumo- and Ubiquitin-tagged Hela cells, suggest that RNf212B is a novel E3 ligase with Ubiquitin activity, serving as a crucial factor for CO designation and maturation. This pathway holds physiological significance, with RNF212B and RNF212 genetic variants substantially contributing to the natural variation in genome-wide recombination rates in humans and mammals.

Project description:Tight control of gene expression networks involved in adipose tissue formation and plasticity is required to adapt to energy needs and environmental cues. However, little is known about the mechanisms that orchestrate the dramatic transcriptional changes leading to adipocyte differentiation. We investigated the regulation of nascent transcription by SUMO during adipocyte differentiation using SLAMseq and ChIPseq. We discovered that SUMO has a dual function in differentiation; it supports the initial downregulation of pre-adipocyte-specific genes, while it promotes the establishment of the mature adipocyte transcriptional program. By characterizing SUMOylome dynamics in differentiating adipocytes by mass spectrometry, we found that SUMOylation of specific transcription factors like PPARG/RXR and chromatin modifiers promotes the transcription of adipogenic genes. Our data demonstrate that the sumoylation pathway helps coordinates the rewiring of transcriptional networks required for formation of functional adipocytes.

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.

Project description:We recently identified the DNA repair complex XPC-RAD23B-CETN2 as a stem cell coactivator (SCC) required for OCT4 and SOX2 transcriptional activation. Here we investigate genome-wide the role of SCC in murine ESCs by mapping regions bound by its RAD23B subunit in wild type and Xpc-/- ESCs, and analyzing transcriptional profiles of SCC-depleted ESCs. RAD23B ChIP-seq in wild type murine ESCs was performed in two replicates; normal IgG were used as controls. RAD23B ChIP-seq in Xpc-/- mESCs was compared to normal IgG. Antibodies to immunoprecipitate RAD23B were raised in guinea pigs against the 108-177 peptide of murine RAD23B protein (NP_033037). Anti-sera were affinity-purified. For RNA-seq, we compared wild type JM8.N4 cells with either Rad23b-/- cells, Rad23b-/-Xpc KD1 or Rad23b-/-Xpc KD2 cells. Xpc was knocked down with two independent shRNAs (KD1 and KD2).

Project description:Chromatin modifications have been implicated in the self-renewal and differentiation of embryonic stem cells (ESCs). However, the function of histone variant H2A.Z in ESCs remains unclear. We show that H2A.Z is highly enriched at promoters and enhancers and is required for both efficient self-renewal and differentiation of murine ESCs. H2A.Z deposition leads to an abnormal nucleosome structure, decreased nucleosome occupancy and increased chromatin accessibility. In self-renewing ESCs, knockdown of H2A.Z compromises OCT4 binding to its target genes and leads to decreased binding of MLL complexes to active genes and of PRC2 complex to repressed genes in self-renewal of ESCs. During differentiation of ESCs, inhibition of H2A.Z also compromises RA-induced RARα binding, activation of differentiation markers and the repression of pluripotency genes. We propose that H2A.Z mediates such contrasting activities by acting as a 'general facilitator' that generates access for a variety of complexes both activating and repressive. ChIP-Seq in murine embryonic stem (mES) cells for H2A.Z and acetylated H2A.Z. ChIP-Seq of H3K4me3, H3K27me3, RbBP5, SUZ12 and OCT4 for mES cells of both H2A.Z RNAi knockdown and shLuc control. ChIP-Seq of RARalpha in H2A.Z knockdown (withdraw of LIF and exposure to RA for 3h) and control cells. MNase-Seq and chromatin accessibility assay using Benzonase digestion followed by next-generation sequencing for mES cells of both H2A.Z RNAi knockdown and shLuc control. ChIP-Seq of H2A.Z and H3K4me3 for mES cells of both MLL4 RNAi knockdown and shLuc control. RNA-Seq for mES cells of H2A.Z knockdown and shluc control. RNA-Seq for embryonic bodies derived from mES cells (H2A.Z knockdown and shLuc control) at day 3 and day 7.

Project description:Post-translational modification by SUMO is a key regulator of cell identity. In mouse embryonic fibroblasts (MEFs), SUMO impedes reprogramming to pluripotency, while in embryonic stem cells (ESCs), it represses the emergence of totipotent-like cells, suggesting that SUMO targets distinct substrates to preserve somatic and pluripotent states. Using MS-based proteomics, we show that the composition of endogenous SUMOylomes differs dramatically between MEFs and ESCs. In MEFs, SUMO2/3 targets proteins associated with canonical SUMO functions, such as splicing, and transcriptional regulators driving somatic enhancer selection. In contrast, in ESCs, SUMO2/3 primarily modifies highly interconnected repressive chromatin complexes, thereby preventing chromatin opening and transitioning to totipotent-like states. We also characterize several SUMO-modified pluripotency factors and show that SUMOylation of Dppa2 and Dppa4 impedes the conversion to 2-cell-embryo-like states. Altogether, we propose that rewiring the repertoire of SUMO target networks is a major driver of cell fate decision during embryonic development.

Project description:In mammals, many germline genes are repressed by epigenetic mechanisms to prevent their illegitimate expression in embryonic and somatic cells. To advance our understanding of the complete mechanisms restricting the expression of germline genes in mammals, we analyzed the chromatin signature of germline genes and performed a genome-wide CRISPR-Cas9 knock-out screen for genes involved in germline gene repression using a reporter system in which GFP is under the control of the epigenetically repressed Dazl germline promoter in mouse embryonic stem cells (ESCs). We showed that the repression of germline genes mainly depends on the polycomb complex PRC1.6 and DNA methylation, which function additively in mouse ESCs. Furthermore, we identified and validated several novel genes involved in the repression of germline genes, and characterized three of them: Usp7, Shfm1 (also known as Sem1) and Erh. Inactivation of Usp7, Shfm1 or Erh led to the upregulation of germline genes, as well as retrotransposons for Shfm1, in mouse ESCs. Functionally, Usp7 acts at two levels: firstly it associates with PRC1.6 components and represses germline genes independently of DNA methylation, and secondly it facilitates DNA methylation deposition at germline genes for long term repression. In summary, our study provides a global view of the epigenetic mechanisms and novel factors required for silencing germline genes in embryonic cells.

Project description:The ground state of pluripotency is defined as a minimal unrestricted state as present in the Inner Cell Mass (ICM). Mouse embryonic stem cells (ESCs) grown in a defined serum-free medium with two kinase inhibitors (‘2i’) reflect this state, whereas ESCs grown in the presence of serum (‘serum’) share more similarities with post implantation epiblast cells. Pluripotency results from an intricate interplay between cytoplasmic, nuclear and chromatin-associated proteins. Therefore, quantitative information on the (sub)cellular proteome is essential to gain insight in the molecular mechanisms driving different pluripotent states. Here, we describe a full SILAC workflow and quality controls for proteomic comparison of 2i and serum ESCs. We demonstrate that this workflow is applicable for subcellular proteomics of the cytoplasm, nuclear and chromatin. The obtained quantitative information revealed increased levels of naïve pluripotency factors on the chromatin of 2i ESCs. Further, we demonstrate that these pluripotent states are supported by distinct metabolic programs, which include upregulation of free radical buffering by the glutathione pathway in 2i ESCs. Through induction of intracellular radicals, we show that the altered metabolic environment renders 2i ESCs less sensitive to oxidative stress. Altogether, this work provides novel insights into the proteome landscape underlying ground state pluripotency.