Project description:Mek inhibitor is widely applied to maintain pluripotency, while prolonged Mek inhibition compromises the developmental potential of mouse embryonic stem cells (ESCs). To better understand the mechanism of Mek in pluripotency maintenance, we first demonstrated that Mek regulates gene expression at post-transcriptional steps. Consistently, many of the 66 Mek substrates identified by quantitative phosphoproteomic analysis are involved in RNA processing. We further confirmed that S563 of Dcp1a, a mRNA decapping cofactor and P-body component, is phosphorylated by Mek1. Dcp1a, as well as two other P-body components Edc4 and Dcp2, are required for the proper self-renewal and differentiation of ESCs, indicating the role of P-bodies in ESCs. Dephosphorylation of Dcp1a S563 facilitates both self-renewal and differentiation of ESCs, through promoting P-body formation and RNA storage. In summary, our study identified 66 Mek substrates supporting the Erk-independent function of Mek, and revealed that Dcp1a, phosphorylated by Mek, regulates ESC self-renewal and differentiation, through modulating P-body formation.

Project description:Mek inhibitor is widely applied to maintain pluripotency, while prolonged Mek inhibition compromises the developmental potential of mouse embryonic stem cells (ESCs). To better understand the mechanism of Mek in pluripotency maintenance, we first demonstrated that Mek regulates gene expression at post-transcriptional steps. Consistently, many of the 66 Mek substrates identified by quantitative phosphoproteomic analysis are involved in RNA processing. We further confirmed that S563 of Dcp1a, a mRNA decapping cofactor and P-body component, is phosphorylated by Mek1. Dcp1a, as well as two other P-body components Edc4 and Dcp2, are required for the proper self-renewal and differentiation of ESCs, indicating the role of P-bodies in ESCs. Dephosphorylation of Dcp1a S563 facilitates both self-renewal and differentiation of ESCs, through promoting P-body formation and RNA storage. In summary, our study identified 66 Mek substrates supporting the Erk-independent function of Mek, and revealed that Dcp1a, phosphorylated by Mek, regulates ESC self-renewal and differentiation, through modulating P-body formation.

Project description:Mek inhibitor is widely applied to maintain pluripotency, while prolonged Mek inhibition compromises the developmental potential of mouse embryonic stem cells (ESCs). To better understand the mechanism of Mek in pluripotency maintenance, we first demonstrated that Mek regulates gene expression at post-transcriptional steps. Consistently, many of the 66 Mek substrates identified by quantitative phosphoproteomic analysis are involved in RNA processing. We further confirmed that S563 of Dcp1a, a mRNA decapping cofactor and P-body component, is phosphorylated by Mek1. Dcp1a, as well as two other P-body components Edc4 and Dcp2, are required for the proper self-renewal and differentiation of ESCs, indicating the role of P-bodies in ESCs. Dephosphorylation of Dcp1a S563 facilitates both self-renewal and differentiation of ESCs, through promoting P-body formation and RNA storage. In summary, our study identified 66 Mek substrates supporting the Erk-independent function of Mek, and revealed that Dcp1a, phosphorylated by Mek, regulates ESC self-renewal and differentiation, through modulating P-body formation.

Project description:Little is known about how pro-obesity diets regulate tissue stem and progenitor cell function. Here we find that high fat diet (HFD)-induced obesity augments the numbers and function of Lgr5+ intestinal stem cells (ISCs) of the mammalian intestine. Like HFD, ex vivo treatment of intestinal organoid cultures with palmitic acid (PA), a constituent of the HFD, enhances the self-renewal potential of these organoid bodies. Mechanistically, HFD induces a robust peroxisome proliferator-activated receptor delta (PPAR-delta signature in intestinal stem and progenitor cells and pharmacologic activation of PPAR-delta recapitulates the effects that HFD has on these cells. Interestingly, HFD- and agonist-activated PPAR-delta signaling endows organoid-initiating capacity to non-stem cells and enforced PPAR-delta signaling permits these non-stem cells to form in vivo tumors upon loss of the tumor suppressor Apc. These findings highlight how diet-modulated PPAR-delta activation alters not only the function of intestinal stem and progenitor cells but also their capacity to initiate tumors. mRNA profiles of intestinal stem cells (GFP-Hi) and progenitors (GFP-Low) from WT or HFD fed mice were generated by deep sequencing using HiSeq 2000.

Project description:Transcriptome analysis by single cell sequencing provides valuable information on intratumor heterogeneity and developmental stages of acute myeloid leukemia (AML) as well as interactions of tumor cells with the microenvironment. However, it has been hardly applied to the subgroup of cases with translocations of the mixed lineage leukemia (MLL) gene for which the enhancer of mRNA decapping 4 (EDC4) gene was recently identified as a novel fusion partner (MLL-EDC4). Here, we compared different MLL translocation by single cell RNA sequencing of cells derived from peripheral blood. The AML MLL-EDC4 patient almost exclusively showed a transcriptional profile of hematopoietic progenitor cells while leukemic cells while the MLLT3-MLL and MLL-ELL fusions exhibited a more differentiated phenotype. The MLL-EDC4 progenitor state was characterized by the upregulation of key transcriptional regulators in AML (RUNX1, SOX4, HOPX), target genes of MYC and interferon signaling as well as other genes known to play a critical role in hematopoiesis or leukemic stem cell activation (CDK6, FLT3, NPM1). In addition, we detected an enrichment of a normal and putatively immunosuppressive monocyte population in the patient with MLL-EDC4. Thus, the MLL-EDC4 translocation was associated with unique transcriptional and microenvironmental features.

Project description:Processing bodies (P-bodies) are the membraneless organelles that play a critical role in RNA storage and degradation. P-body abnormalities contribute to diseases and developmental disorders, however, the dynamics of RNA components of P-bodies in human embryonic stem cells during maintenance and differentiation remain elusive. Here, we captured P-bodies during human embryonic stem cells(hESCs) to mesodermal differentiation using flow cytometry, and revealing unique transcriptomic features to other organelles and characterized by lower GC content and reduced M6A modifications. Genes enriched in P-body are cell-specific, mainly associated with translation regulation and the cytoskeleton, long non-coding RNAs in P-body tend to interact with RNAs, whereas cytoplasmic genes are conserved and essential for fundamental processes, and cytoplasmic lncRNAs mostly interact with proteins. During hESC to mesodermal differentiation, both the number of P-bodies and enriched genes were significantly reduced. In addition, P-bodies selectively attracted specific transposable elements in hESCs. Perturbation of P-body gene expression or overexpression of P-body core protein LSM14A could disrupt hESC differentiation but not maintenance. In conclusion, our data elucidate the dynamics of P-body during the differentiation of hESCs to the mesodermal lineage and support the link between P-body and stem cell pluripotency.

Project description:The small intestine is responsible for nutrient absorption and it is one of the most important interfaces between the environment and our body. During aging, changes in the structure of the epithelium lead to food malabsorption and reduced barrier function thus increasing disease risk in aging. The molecular drivers of these alterations remain poorly understood. Here, we compared the proteomes of small intestinal crypts from mice across different anatomical regions and age groups. We found that aging alters epithelial immune responses, metabolic networks and stem cell proliferation, and it is accompanied by a region-dependent skewing in the cellular composition of the intestinal epithelium. Of note, a short period of dietary restriction followed by re-feeding partially restores the epithelium to a youthful state by promoting the differentiation of intestinal stem cells (ISCs) towards the secretory lineage. Using in vitro and in vivo studies, we identify Hmgcs2 (3-hydroxy-3-methylglutaryl-CoA synthetase 2) – the rate limiting enzyme in the synthesis of ketone bodies – as a modulator of ISCs differentiation, which responds to dietary changes. This study provides an atlas of age-dependent proteome changes in defined regions of the intestinal epithelium and characterizes how young and old mice adapt to drastic changes of diet, such as dietary restriction and re-feeding.

Project description:Little is known about how pro-obesity diets regulate tissue stem and progenitor cell function. Here we find that high fat diet (HFD)-induced obesity augments the numbers and function of Lgr5+ intestinal stem cells (ISCs) of the mammalian intestine. Like HFD, ex vivo treatment of intestinal organoid cultures with palmitic acid (PA), a constituent of the HFD, enhances the self-renewal potential of these organoid bodies. Mechanistically, HFD induces a robust peroxisome proliferator-activated receptor delta (PPAR-delta signature in intestinal stem and progenitor cells and pharmacologic activation of PPAR-delta recapitulates the effects that HFD has on these cells. Interestingly, HFD- and agonist-activated PPAR-delta signaling endows organoid-initiating capacity to non-stem cells and enforced PPAR-delta signaling permits these non-stem cells to form in vivo tumors upon loss of the tumor suppressor Apc. These findings highlight how diet-modulated PPAR-delta activation alters not only the function of intestinal stem and progenitor cells but also their capacity to initiate tumors.

Project description:To define target genes of the intestine-restricted transcription factor (TF) CDX2 in intestinal stem cells, we performed chromatin immunoprecipitation coupled with high-throughput sequencing (ChIP-Seq). We used RNA-sequencing to profile gene expression changes during cell differentiation from mouse intestinal stem cells to mature villus cells, as well as genes perturbed in intestinal stem cells upon loss of Cdx2. We find thousands of genes that change in expression during cell differentiation, including known stem cell and mature markers. Upon loss of Cdx2, hundreds of genes are up and down-regulated in intestinal stem cells, some of which are also bound by CDX2 nearby and constitute candidate direct target genes. CDX2 ChIP-Seq analysis of isolated mouse intestinal stem cells. RNA seq analysis of control mouse villus cells, control intestinal stem cells and Cdx2-deleted intestinal stem cells.

Project description:The overall description of the project: Epithelial-mesenchymal transition (EMT) is a fundamental cellular process frequently hijacked by cancer cells to promote tumor progression, especially metastasis formation. Molecularly, EMT is orchestrated by various molecular networks acting at different layers of gene regulation. Compared to transcriptional regulation that has been extensively studied in the context of EMT, post-transcriptional mechanisms remain relatively underexplored. Here, by taking advantage of pooled CRISPR screen, we analyzed the influence of 1547 RNA binding proteins (RBPs) on cell motility and identified multiple core P-body (PB) components as negative modulators of cancer cell migration. Further experiments demonstrated that depletion of the PB via silencing DDX6 or EDC4 could activate hallmarks of EMT thereby enhancing cell migration in vitro as well as metastasis formation in vivo. Integrative multi-omics analysis revealed that the PB could repress the translation of its target genes, including an EMT-driver gene, HMGA2. Furthermore, we demonstrated that endoplasmic reticulum (ER) stress is an intrinsic signal that can induce PB disassembly and translational derepression of HMGA2. Finally, we used mouse genetics to demonstrate that knockout of Ddx6 resulted in EMT-related defects in embryonic development. Taken together, our study has put forward a novel function of the PB as an EMT regulator in both pathological and physiological conditions. The description of the MS part: Recent studies have suggested that the PB is mainly involved in translational regulation. Therefore, we performed mass spectrometry analysis on DDX6- and EDC4-KO clones and parental cells to measure changes at the protein level upon PB perturbation. After filtering and normalization, 3,762 and 3,000 peptides corresponding to 3,721 and 2,991 proteins were identified in DDX6- and EDC4-KO cells, respectively, and their abundance was then compared to parental HCT116 cells. A good correlation between two independent gene KO clones was observed in terms of protein level changes. In total, DDX6-KO induced up- and down-regulation of 230 and 291 proteins, respectively, while EDC4-KO induced up- and down-regulation of 73 and 22 proteins, respectively. To assess whether the PB mainly contributes to the RNA degradation or translational repression of its mRNA targets in HCT116 cells, we compared the RNA level and translation efficiency changes of DDX6-bound genes with other genes upon PB loss. As a result, both DDX6 and EDC4 KO led to a lower RNA, but higher translational efficiency of DDX6-bound genes compared to other unbound genes, suggesting PBs mainly function as a translational repressor of stored mRNAs in HCT116 cells.