Project description:The epithelial-to-mesenchymal transition (EMT) and metastasis of the cancer cells are closely associated with epigenetic changes of chromatin and reprogramming of transcriptomes. The DNA methyltransferases DNMT3A and DNMT3B possess DNA demethylation/dehydroxymethylation activities. Here, we show, by a range of molecular/cellular approaches, that active DNA demethylation activity of DNMT3A is required for hypoxia-induced EMT of the primary colon carcinoma SW480 cells, its genome-wide DNA demethylation, and promoter DNA demethylation/transcriptional activation of the EMT genes TWIST1 and SNAIL1. DNMT3A also positively regulates hypoxia-induced TWIST1 activation in other types of cancer cells. Mechanistic analysis supports a regulatory model, in which hypoxia-induced H3K36me3 mark recruits DNMT3A to demethylate CpG in the hypoxia-responsive element (HRE), thereby facilitating HIF-1α binding and TWIST1 activation. This study demonstrates for the first time an in vivo functional role of the active DNA demethylation activity of DNMT3A and its potential as a novel therapeutic target of anti-cancer development.

Project description:During Epithelial-Mesenchymal Transition (EMT), apical-basal polarized epithelial cells are converted to front-to-back polarized mesenchymal cells that only form loose cell-cell adhesions. These phenotypic changes are accompanied by acquisition of increased motility and invasiveness. EMT programs are orchestrated by pleiotropic transcription factors (TFs), such as Twist1 and Snail1 and effect morphogenetic steps during embryogenesis, including mesoderm formation and neural crest migration. EMTs have also been implicated in the acquisition of aggressive traits by carcinoma cells, including the ability to complete several steps of the metastatic cascade as well as propagation of the tumor by single cells (clonogenicity), a defining trait of tumor-initiating or cancer stem cells. However, the molecular links between the expression of EMT-TFs, the process of EMT and acquisition of clonogenicity remain obscure. Using inducible Twist1 or Snail1 expressed in CD24-positive mammary epithelial cells, we show that clonal growth in anchorage independence and EMT are induced sequentially and independently: clonogenic potential is induced prior to EMT and requires transient TF-activity. By contrast, EMT depends on continuous TF-activation over a longer period. In 3D-collagen assays, continuous Twist1 activity suppresses colony formation, whereas transient activation induces highly invasive growth independently of EMT. In conclusion, our results demonstrate that transient Twist1 activation suffices to drive tumor progression of CD24-positive breast epithelial cells, assessed by invasive as well as anchorage-independent clonal growth, whereas chronic Twist1 exposure can suppress these traits of aggressive tumor cells. We performed gene expression microarray analysis on CD24high and CD24negative populations derived from HMLE-Twist1-ER or HMLE-Snail1-ER cell lines upon various culture conditions

Project description:During Epithelial-Mesenchymal Transition (EMT), apical-basal polarized epithelial cells are converted to front-to-back polarized mesenchymal cells that only form loose cell-cell adhesions. These phenotypic changes are accompanied by acquisition of increased motility and invasiveness. EMT programs are orchestrated by pleiotropic transcription factors (TFs), such as Twist1 and Snail1 and effect morphogenetic steps during embryogenesis, including mesoderm formation and neural crest migration. EMTs have also been implicated in the acquisition of aggressive traits by carcinoma cells, including the ability to complete several steps of the metastatic cascade as well as propagation of the tumor by single cells (clonogenicity), a defining trait of tumor-initiating or cancer stem cells. However, the molecular links between the expression of EMT-TFs, the process of EMT and acquisition of clonogenicity remain obscure. Using inducible Twist1 or Snail1 expressed in CD24-positive mammary epithelial cells, we show that clonal growth in anchorage independence and EMT are induced sequentially and independently: clonogenic potential is induced prior to EMT and requires transient TF-activity. By contrast, EMT depends on continuous TF-activation over a longer period. In 3D-collagen assays, continuous Twist1 activity suppresses colony formation, whereas transient activation induces highly invasive growth independently of EMT. In conclusion, our results demonstrate that transient Twist1 activation suffices to drive tumor progression of CD24-positive breast epithelial cells, assessed by invasive as well as anchorage-independent clonal growth, whereas chronic Twist1 exposure can suppress these traits of aggressive tumor cells.

Project description:Cell plasticity is emerging as a key regulator of tumor progression and metastasis. During carcinoma dissemination epithelial cells undergo epithelial to mesenchymal transition (EMT) processes characterized by the acquisition of migratory/invasive properties, while the reverse, mesenchymal to epithelial transition (MET) process, is also essential for metastasis outgrowth. Different transcription factors, called EMT-TFs, including Snail, bHLH and Zeb families are drivers of the EMT branch of epithelial plasticity, and can be post-transcriptionally downregulated by several miRNAs, as the miR-200 family. The specific or redundant role of different EMT-TFs and their functional interrelations are not fully understood. To study the interplay between different EMT-TFs, comprehensive gain and loss-of-function studies of Snail1, Snail2 and/or Zeb1 factors were performed in the prototypical MDCK cell model system. We here describe that Snail1 and Zeb1 are mutually required for EMT induction while continuous Snail1 and Snail2 expression, but not Zeb1, is needed for maintenance of the mesenchymal phenotype in MDCK cells. In this model system, EMT is coordinated by Snail1 and Zeb1 through transcriptional and epigenetic downregulation of the miR-200 family. Interestingly, Snail1 is involved in epigenetic CpG DNA methylation of the miR-200 loci, essential to maintain the mesenchymal phenotype. The present results thus define a novel functional interplay between Snail and Zeb EMT-TFs in miR200f regulation providing a molecular link to their previous involvement in the generation of EMT process in vivo. Expression analysis of MDCK over-expression EMT-TF Analysis of 7 overexpression MDCK cells each of them using biological rpelicates (MDCK-E47, Snail2, Snail1, Twist1, Tiwst2, Zeb1, Zeb2)

Project description:H3K36me3-coupled DNA Demethylation by DNMT3A Is Essential for Hypoxia-Induced EMT of Cancer Cells

Project description:H3K36me3-coupled DNA Demethylation by DNMT3A Is Essential for Hypoxia-Induced EMT of Cancer Cells [ChIP-Seq]

Project description:H3K36me3-coupled DNA Demethylation by DNMT3A Is Essential for Hypoxia-Induced EMT of Cancer Cells [Bisulfite Sequencing]

Project description:Recent fate mapping studies concluded that EMT is not required for metastasis of carcinomas. Here we challenge this conclusion by showing that it failed to account for possible crosstalk between EMT and non-EMT cells that promotes dissemination of non-EMT cells. In breast cancer models, EMT cells induce increased metastasis of weakly metastatic, non-EMT tumor cells in a paracrine manner in part by non-cell autonomous activation of the GLI transcription factor. Treatment with GANT61, a GLI1/2 inhibitor, but not with IPI-926, a Smoothened inhibitor, blocks this effect, and inhibits growth in PDX models. In human breast tumors, the EMT-TFs strongly correlate with activated Hedgehog/GLI signaling, but not with the Hh ligands. Our findings indicate that EMT contributes to metastasis in part via non-cell autonomous effects that activate the Hh pathway. While all Hh inhibitors may act against tumors with canonical Hh/GLI signaling, only GLI inhibitors would act against EMT-induced GLI activation. In recent years, immunohistochemical analyses and multiplex high-throughput single cell sequencing of human tumor cells have shown that tumors are composed of diverse cell subpopulations containing different driver mutations, gene and protein expression profiles, growth rates, and responses to chemotherapeutics. Such heterogeneity is exacerbated by cellular plasticity, where some cells may undergo oncogenic epithelial-to-mesenchymal transition (EMT), resulting in loss of cell-cell adhesion and polarity, reduced epithelial and elevated mesenchymal protein expression, increased migration and invasion, and enhanced dissemination from the primary tumor. Because metastases in patients appear epithelial, the reverse process, mesenchymal-to-epithelial transition (MET), may occur to allow tumor cell colonization in secondary metastatic sites, establishing cellular plasticity as an important aspect of tumor progression. However, the role of EMT in carcinoma metastasis is controversial. Recent lineage tracing studies argue against the requirement of EMT for metastasis, as reporter-tagged cells that underwent a previous EMT were not found at the secondary site. However, these studies did not address the potential cooperation between EMT and non-EMT cells during the metastatic process, as EMT cancer cells may enable non-EMT cells to gain access to the secondary site, leading to macrometastatic growth. Thus, metastasis can be influenced by intratumoral heterogeneity: where a small proportion of primary tumor cells that have undergone an EMT may influence neighboring, non-EMT tumor cells. Twist1, Snail1, and Six1 are EMT-inducing transcription factors (EMT-TFs) that have all been associated with breast cancer metastasis. All three EMT-TFs regulate critical developmental processes such as cell survival, migration and invasion; in part by influencing EMT. In addition, they are downregulated post-embryogenesis, but re-expressed in various cancers where they cell autonomously induce EMT, resulting in increased percentages of tumor initiating cells (TICs) and enhanced metastasis. In carcinomas, Twist1 and Snail1 transcriptionally repress E-Cadherin (E- Cad) and upregulate mesenchymal genes. Similarly, Six1 overexpression induces EMT by regulating E-Cad localization and altering other EMT markers. During development and cancer, EMT-TFs act in concert with several signaling networks including TGFβ, Wnt, and Hedghog (Hh). The Hedgehog (Hh) signaling pathway is a prominent regulator of embryonic development, where Hh ligands function as morphogens to control numerous developmental processes. Interestingly, in Drosophila eye development, hh is a direct target of sine oculis (the homolog of Six1) and Six1 regulates Hh/GLI signaling during lung development and in fibroblasts. Additionally, Twist1 and Hh/GLI signaling are intimately linked during development, and recently Twist1 and Snail1 were associated with the Hh pathway in TICs. In mammals, canonical activation of Hh/GLI signaling involves binding of one the Hh ligands such as(either, Desert (DHH), Indian (IHH), or Sonic Hedgehog (SHH) to Patched-1 (PTCH1) or Patched-2 (PTCH2) receptors, relieving the inhibitory activity of PTCH on Smoothened (SMO). When inhibition is relieved, levels of the transcriptional activator forms of one or more GLI transcription factors (GLI1, 2, or 3) increase in the nucleus, resulting in activation of Hh target genes 12. Non-canonical activation of the GLI TFs can occur in a Hh- or SMO-independent manner via secreted factors like TGF-β19. Importantly, autocrine and paracrine Hh-mediated crosstalk between tumor cells and the tumor microenvironment 20 results in increased proliferation, stem cell self-renewal and metastasis in various cancers 21. In basal cell carcinoma (BCC) and medulloblastoma, activated Hh signaling is often due to mutations in pathway components such as PTCH and SMO, while in other tumor types including breast, mutations are not observed at high frequency. Instead there is evidence for Hh ligand-dependent pathway hyperactivity. Because numerous studies link Hh signaling to progression in multiple tumor types, derivatives of cyclopamine (e.g. GDC-0449 and IPI926), a naturally occurring plant-derived steroidal alkaloid which targets SMO, are in clinical trials for select patients with BCC and medulloblastoma with promising efficacy. However, these inhibitors have not shown promise in breast cancer despite evidence for activation of this pathway. Herein, we demonstrate that EMT-TFs Twist1, Snail1 and Six1 influence neighboring carcinoma cells in a non-cell autonomous manner, by increasing EMT features and aggressive properties of cells not expressing these TFs. Six1 is a key mediator of the non-cell autonomous effects downstream of Twist1 and Snail1, and can induce metastasis of non-Six1, non-EMT cells. All three EMT-TFs function non-cell autonomously by activation of GLI-mediated transcription in non-EMT cells, but employ different mechanisms of pathway activation, some of which are Hh ligand and SMO-independent. We find that pharmacological inhibition of GLI, but not SMO, in the non-EMT cells efficiently inhibits the non-cell autonomous phenotypes imparted by all three EMT-TFs. Importantly, we demonstrate that in selected patient derived breast cancer xenograft (PDX) models endogenously expressing high levels of these EMT-TFs (but not Hh ligands), GANT61 (a GLI1/2 inhibitor) inhibits tumor growth whereas IPI926 (a SMO inhibitor) did not. Our data suggest that upstream SMO inhibitors may not prove efficacious in tumors where a proportion of cells activate GLI-TF via EMT-TFs, and instead argue that inhibitors directly targeting GLI may be more effective.

Project description:Many oncogenic transcription factors (TFs) are considered to be undruggable due to their reliance on large protein-protein and protein-DNA interfaces. TFs like hypoxia-inducible factors (HIFs) and X-box binding protein 1 (XBP1) are induced by hypoxia and other stressors in solid tumors and bind to UPRE/HRE motifs to control oncogenic gene programs. Here, we report a strategy to create synthetic transcriptional repressors (STRs) that mimic the bZIP domain of XBP1 and recognize the UPRE/HRE motif. A lead molecule, STR22, binds UPRE/HRE DNA sequences with high fidelity and competes with both TFs in cells. Under hypoxia, STR22 globally suppresses HIF1a binding to HRE-containing promoters/enhancers, inhibits hypoxia-induced gene expression and blocks pro-tumorigenic phenotypes in TNBC cells. In vivo, intratumoral and systemic STR22 treatment inhibited hypoxia-dependent gene expression, primary tumor growth and metastasis of TNBC tumors. These data validate a novel strategy to target the tumor hypoxia response through coordinated inhibition of TF-DNA binding.

Project description:At the molecular level, epithelial-to-mesenchymal transition (EMT) necessitates extensive transcriptional reprogramming which is orchestrated by a small group of gene regulatory proteins. The transcription factor SNAIL1 is a zinc-finger DNA-binding protein and well-known master regulator of EMT. However, knowledge of its immediate target genes is incomplete. Here, we performed ChIP-seq to chart genome-wide SNAIL1 chromosomal binding sites and to identify genes directly regulated by SNAIL1. For this we used the colorectal adenocarcinoma cell line LS174T which was engineered to express hemagglutinin epitope-tagged murine SNAIL1 in a doxycycline inducible fashion. In total, 1501 SNAIL1-HA ChIP-seq peaks were mapped which were linked to 1307 genes based on nearest neighbor relationships. The vast majority of SNAIL1-HA binding events occurred within 1 kb upstream of transcriptional start sites (44%), and in intergenic regions and promoter-distal introns (46%). De novo motif deduction showed that nearly all ChIP-seq peak regions harbored at least one sequence element corresponding to the cognate SNAIL1 DNA-recognition motif 5’-CAGGTG-3’. SNAIL1-HA ChIP-seq peaks included previously determined SNAIL1 binding sites at the FOXA1, EPHB3, ITGB4 and CLDN3 genes, thus validating the ChIP-Seq results. When comparing the genomic distribution of SNAIL1-HA to that of the intestinal stem cell (ISC) transcription factors ASCL2 and TCF7L2, we observed a significant overlap. Furthermore, SNAIL1-HA ChIP-seq peaks are associated with a substantial fraction of ISC signature genes. In two colorectal cancer cell lines, we verified that SNAIL1 decreases ISC marker expression. Likewise, SNAIL1-HA was found to occupy multiple regulatory elements at the proto-oncogene MYB, and the long non-coding RNA (lncRNA) WiNTRLINC1, a recently described regulator of ASCL2. Occupancy of the MYB and WiNTRLINC1 regulatory elements by SNAIL1-HA correlated with the downregulation of the two genes. We propose that SNAIL1-mediated repression of MYB and ISC markers like WiNTRLINC1 contributes to the decrease in proliferation known to be associated with EMT, while simultaneously abrogating stemness features of colorectal cancer cells.