Project description:The annual ~36,000 prostate cancer (PCa) deaths represent a large clinical unmet need and a call for deeper understanding of PCa metastasis. Epithelial-mesenchymal-transition (EMT) has been used to model metastatic behaviors in numerous cancers including PCa. One hallmark of EMT is cell cycle suppression, but how EMT impacts PCa proliferation remains unclear primarily due to the lack of appropriate models. Methods: We transiently induced expression of Snail1 (SNAI1), an EMT driver expressed in PCa, at physiological levels in three PCa cells lines, C4-2B, 22Rv1, and DU145. We used RNA-seq, ChIP-Seq, bioinformatics, qRT-PCR, shRNA, and immunoblotting to identify mechanisms of Snail1-driven inhibition of proliferation. Results: Snail1 suppressed proliferation and the G2/M cell cycle progression, without affecting cell death. Mechanistically, Snail1 upregulated expression of CEBPg, ERG1, FOXO1, cyclin G1, p21, stress genes SESN3 and SOD3, apoptotic programmers Puma, Bax, and Noxa, and senescence-related laminB1, and downregulated Ki67, cyclins A2 and B2. ChIP-Seq data identified Snail1 direct binding to p21, cyclin B2 and G1, EGR1, and CEPBg promoters. EGR1 induced FOXO1 and EGR1 was required for Snail1-induced SOD3 and Puma, and suppression of Caspase 3 to prevent apoptosis. The EGR1/FOXO1 axis induced BAX, Noxa, and SESN3. CEBPg was required for Snail1 induction of Lamin B1 to block Snail1-induced senescence. Conclusions: We identified three new major downstream targets of Snail1 that improve our understanding of the role of EMT in limiting stress signaling, apoptosis, and senescence during cell cycle suppression to create a vulnerability for therapeutic targeting.

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:Although heterochromatin is enriched with repressive traits, it is also actively transcribed, giving rise to large amounts of non-coding RNAs. Although these RNAs are responsible for the formation and maintenance of heterochromatin, little is known about how their transcription is regulated. Here we show that the Snail1 transcription factor represses pericentromeric transcription, acting through the H3K4 deaminase LOXL2. Since Snail1 plays a key role in the epithelial to mesenchymal transition (EMT), we analyzed the regulation of mouse heterochromatin transcription in this process. At the onset of EMT, one of the major structural heterochromatin proteins, HP1a, is transiently released from heterochromatin foci in a Snail1/LOXL2–dependent manner during EMT, concomitantly with a down-regulation of major satellite transcription. Global transcriptome analysis indicated that ectopic expression of heterochromatin transcripts affects the transcription profile of EMT-related genes. Additionally, preventing the down-regulation of major satellite transcripts compromised the migratory and invasive behavior of mesenchymal cells. We propose that Snail1 regulates heterochromatin transcription through the histone-modifying enzyme, LOXL2, thus creating the favorable transcriptional state necessary for completing EMT. Keywords: Expression Profiling by array We analyzed 2 arrays from each condition: Control and Major treated 8 hours with TGFbeta

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

Project description:Although heterochromatin is enriched with repressive traits, it is also actively transcribed, giving rise to large amounts of non-coding RNAs. Although these RNAs are responsible for the formation and maintenance of heterochromatin, little is known about how their transcription is regulated. Here we show that the Snail1 transcription factor represses pericentromeric transcription, acting through the H3K4 deaminase LOXL2. Since Snail1 plays a key role in the epithelial to mesenchymal transition (EMT), we analyzed the regulation of mouse heterochromatin transcription in this process. At the onset of EMT, one of the major structural heterochromatin proteins, HP1a, is transiently released from heterochromatin foci in a Snail1/LOXL2–dependent manner during EMT, concomitantly with a down-regulation of major satellite transcription. Global transcriptome analysis indicated that ectopic expression of heterochromatin transcripts affects the transcription profile of EMT-related genes. Additionally, preventing the down-regulation of major satellite transcripts compromised the migratory and invasive behavior of mesenchymal cells. We propose that Snail1 regulates heterochromatin transcription through the histone-modifying enzyme, LOXL2, thus creating the favorable transcriptional state necessary for completing EMT. Keywords: Expression Profiling by array

Project description:Epithelial-mesenchymal transition (EMT) is a pivotal process in development and disease. In carcinogenesis, various signaling pathways are known to trigger EMT by inducing the expression of EMT transcription factors (EMT-TFs) like SNAIL1, ultimately promoting invasion, metastasis and chemoresistance. However, how EMT is executed downstream of EMT-TFs is incompletely understood. Here, using human colorectal cancer (CRC) and mammary cell line models of EMT, we demonstrate that SNAIL1 critically relies on bone morphogenetic protein (BMP) signaling for EMT execution. This activity requires the transcription factor SMAD4 common to BMP/TGFβ pathways, but is TGFβ signaling-independent. Further, we define a signature of BMP-dependent genes in the EMT-transcriptome which orchestrate EMT-induced invasiveness, and are found to be regulated in human CRC transcriptomes and during EMT in vivo. Collectively, our findings substantially augment the knowledge of mechanistic routes whereby EMT can be effectuated, which is relevant for the conceptual understanding and therapeutic targeting of EMT processes. To identify BMP-dependent genes regulated during EMT, LS174T cells overexpressing Snail1-HA in a doxycycline (Dox)-inducible manner were treated with Dox and inhibitors of BMP signaling (LDN193189/mNoggin) or DMSO as control for different periods of time.

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.

Project description:Snail1 transcriptional factor is essential for triggering epithelial-to-mesenchymal transition (EMT) and inducing tumor cell invasion. We report here that Snail1 plays also a key role in tumor associated fibroblasts since is necessary for enhancement by these cells on epithelial cells tumor invasion. Snail1 expression in fibroblast requires signals derived from tumor cells such as TGF-b; reciprocally, in fibroblasts Snail1 organizes a complex program that favors collective invasion of epithelial cells at least in part by the secretion of diffusible signaling molecules, such as prostaglandin E2. The capability of human or murine tumor-derived cancer associated fibroblasts to promote tumor invasion is associated to Snail1 expression and obliterated by Snail1 depletion. In vivo experiments show that tumor cells co-transplanted with Snail1 depleted fibroblasts show lower invasion than those xenografted with control fibroblasts. Finally Snail1 depletion in mice prevents the formation of breast tumors and decreased their invasion. Therefore, these results demonstrate that the role of Snail1 in tumor invasion is not limited to its effect in EMT but dependent on its expression in stromal fibroblasts where it orchestrates its activation and the crosstalk with epithelial cells.

Project description:Snail1 transcriptional factor is essential for triggering epithelial-to-mesenchymal transition (EMT) and inducing tumor cell invasion. We report here that Snail1 plays also a key role in tumor associated fibroblasts since is necessary for enhancement by these cells on epithelial cells tumor invasion. Snail1 expression in fibroblast requires signals derived from tumor cells such as TGF-b; reciprocally, in fibroblasts Snail1 organizes a complex program that favors collective invasion of epithelial cells at least in part by the secretion of diffusible signaling molecules, such as prostaglandin E2. The capability of human or murine tumor-derived cancer associated fibroblasts to promote tumor invasion is associated to Snail1 expression and obliterated by Snail1 depletion. In vivo experiments show that tumor cells co-transplanted with Snail1 depleted fibroblasts show lower invasion than those xenografted with control fibroblasts. Finally Snail1 depletion in mice prevents the formation of breast tumors and decreased their invasion. Therefore, these results demonstrate that the role of Snail1 in tumor invasion is not limited to its effect in EMT but dependent on its expression in stromal fibroblasts where it orchestrates its activation and the crosstalk with epithelial cells.

Project description:p53 is a transcription factor that plays a critical role in cancer prevention. However, the mechanisms by which p53 exerts its tumor-suppressive function is still unclear. While PUMA/BBC3 and NOXA/PMAIP1 are known to be important in p53-dependent apoptosis, and p21/CDKN1A is crucial for p53-dependent cell-cycle arrest, we demonstrate that zebrafish lacking puma, noxa, and p21 do not show a predisposition to cancer. This suggests that additional p53 transcriptional targets are sufficient for its tumor suppressive function. Contrary to the prevailing belief that p21 is the key regulator of p53-dependent cell-cycle arrest, we provide evidence that p53 can still induce cell-cycle arrest in the absence of p21, following DNA damage or loss of mdm2 (p53 activation in the absence of stress). This implies the involvement of other p53 transcriptional targets in mediating p53-dependent cell-cycle arrest. Since p53 tumor suppression is conserved across multiple vertebrate species, we conducted a cross-species comparative analysis of p53-dependent transcriptional profiles to identify a conserved set of 136 p53-upregulated transcripts. Our analysis stresses the importance of ortholog to paralog analysis across species, since in many cases the paralog but not ortholog in differing species is p53 dependent. Additionally, we performed a CRISPR/Cas9 G0 “crispant” screen in a genetic background lacking mdm2, puma, noxa, and p21 to identify key components involved in p53-dependent cell-cycle arrest. Our findings revealed that ccng1, fbxw7, and foxo3b play an important role in this process.