Project description:Epithelial to Mesenchymal Transition (EMT) has been associated with cancer cell heterogeneity, plasticity and metastasis. It has been the subject of several modeling effort. This logical model of the EMT cellular network aims to assess microenvironmental signals controlling cancer-associated phenotypes amid the EMT continuum. Its outcomes relate to the qualitative degrees of cell adhesions by adherent junctions and focal adhesions, two features affected during EMT. Model attractors recover epithelial, mesenchymal and hybrid phenotypes, and simulations show that hybrid phenotypes may arise through independent molecular paths, involving stringent extrinsic signals. Of particular interest, model predictions and their experimental validations indicated that: 1) ECM stiffening is a prerequisite for cells overactivating FAK-SRC to upregulate SNAIL1 and acquire a mesenchymal phenotype, and 2) FAK-SRC inhibition of cell-cell contacts through the Receptor Protein Tyrosine Phosphates kappa leads to the acquisition of a full mesenchymal rather than a hybrid phenotype.

Project description:Epithelial-mesenchymal transition (EMT) is a continuum that includes epithelial, partial EMT (P-EMT) and mesenchymal states, each of which are associated with cancer progression, invasive capabilities and ultimately metastasis. We have employed a lineage traced sporadic model of pancreatic cancer to generate a murine organoid biobank from primary and secondary tumors, including sublines that have undergone P-EMT and complete EMT (C-EMT). Using an unbiased quantitative proteomics approach, we found that the morphology of the organoids could predict EMT state, with solid organoids associated with a C-EMT signature. We also observed that exogenous TGFb1 could induce a solid organoid morphology that was associated with changes in the S100 family of proteins and the formation of high-grade tumors. Our work reveals that S100A4 may represent a useful biomarker to predict EMT state, disease progression and outcome.

Project description:<p>The involvement of membrane-bound solute carriers (SLCs) in neoplastic&nbsp;transdifferentiation&nbsp;processes is poorly defined. Here, we examined changes in the SLC landscape during epithelial-mesenchymal transition (EMT) of pancreatic cancer cells. We show that two SLCs from the organic anion/cation transporter family, SLC22A10 and SLC22A15, favor EMT via&nbsp;interferon&nbsp;(IFN)&nbsp;α&nbsp;and γ signaling activation of receptor tyrosine kinase-like orphan receptor 1 (ROR1) expression. In addition, SLC22A10 and SLC22A15 allow tumor cell accumulation of&nbsp;glutathione&nbsp;to support EMT via the IFNα/γ-ROR1 axis. Moreover, a pan-SLC22A inhibitor lesinurad reduces EMT-induced metastasis and&nbsp;gemcitabine&nbsp;chemoresistance to prolong survival in mouse models of pancreatic cancer, thus identifying new vulnerabilities for human PDAC.</p>

Project description:Epithelial-mesenchymal transition (EMT) is a process by which epithelial cells lose cell-cell contact and gain cancer malignancy such as invasion, stemness, chemoresistance and metastasis. Reverse precess, mesenchymal-epithelial transition (MET) is also important for colonization. Extracellular vesicles (EVs) secreted from cancer cells are also important for cancer malignancy. To analyze RNAs from cells and EVs during EMT and MET, RNA sequencing was performed using E-cadherin-RFP/Py2T reporter system.

Project description:Quiescent cancer cells responsible for tumor chemoresistance and relapse have been identified in several tumors but in colorectal cancer (CRC) they remain largely undefined. By using a proliferation-sensitive dye, we isolated and characterized a rare subpopulation of cells from colorectal tumors which, upon gene expression, proteomic and functional studies, revealed combined features of stemness, drug resistance and epithelial-to-mesenchymal transition (EMT). Altogether, this work reveals a link between cell quiescence, EMT and therapy resistance relevant for targeting drug-resistant populations in CRC.

Project description:Numerous epithelial-to-mesenchymal transition (EMT)-promoting transcription factors have been implicated in tumorigenesis or metastasis, as well as chemoresistance of cancer. However, the underlying mechanism mediating these processes is unclear. Here we report that Foxq1, a forkhead box-containing transcription factor and EMT-inducing gene, promotes stemness traits and chemoresistance in mammary epithelial cells. We identify Twist1, Zeb2, and PDGFRM-NM-1 and M-NM-2 as Foxq1 downstream targets using an expression profiling assay. Further studies reveal that PDGFRM-NM-1 and M-NM-2 can be directly regulated by Foxq1, or indirectly through Twist1. Knockdown of both PDGFRM-NM-1 and M-NM-2 shows more significant effects on reversing Foxq1-promoted oncogenesis in vitro and in vivo than knockdown by either PDGFRM-NM-1 or M-NM-2 alone. PDGFRM-NM-2, but not PDGFRM-NM-1, shows potent effects in reversing Foxq1-promoted stemness traits. Moreover, pharmacological inhibition or gene silencing of PDGFRs sensitize mammary epithelial cells to chemotherapeutic agents in vitro and in vivo. These findings collectively indicate PDGFRs as critical mediators underlying breast cancer tumorigenesis and chemoresistance driven by EMT promoting genes, which have potential clinical implications for cancer therapy. The purpose of these experiments is to investigate the downstream targets of several transcriptional factors including Foxq1 and IRX5. Another purpose is to compare the expression pattern between basal-like breast cancer cells including MDA-MB231, SUM159 and SUM1315.

Project description:Epithelial-mesenchymal transition (EMT) is a diverse and dynamic biological process which is involved in cancer progression. It is important for carcinoma cells during invasion and metastasis. EMT has been in the spotlight for cancer cells to disseminate to distant organs by gaining partial EMT phenotype. Cancer cells with partial EMT are believed to be more cancerogenic/invasive than cells that have undergone complete EMT. The proteomic changes that occur following EMT in breast epithelial cells and how these relate to changes in cellular metabolism are incompletely understood. To study metabolic reprogramming in different mesenchymal states, we analyzed proteomic changes following EMT in the breast epithelial cell model D492, with single-shot LFQ supported by SILAC proteomic approach. The D492 EMT cell model contains three isogenic cell lines: epithelial D492 cells, mesenchymal D492M cells, and partial mesenchymal, HER2 overexpressing, tumorigenic D492HER2 cells. Proteomic analysis positioned the D492 and D492M cells as basal-like while D492HER2 as claudin-low. Further comparison of the non-tumorigenic D492 and D492M cells to tumorigenic D492HER2 differentiated the metabolic EMT markers of migration from those of invasion. Among these were markers of glycan metabolism. We identified glutamine-fructose-6-phosphate transaminase [isomerizing] 2 (GFPT2) as the top dysregulated enzyme in glycan metabolism and found increased GFPT2 expression was a characteristic of claudin-low breast cancer. siRNA knockdown of GFPT2 influenced both cell growth and invasion in vitro and was accompanied by lowered flux through the hexosamine biosynthesis pathway (HBP). Knockdown of GFPT2 decreased cystathionine and sulfide:quinone oxidoreductase (SQOR) in the transsulfuration pathway which regulates H2S production and mitochondrial homeostasis. Moreover, GFPT2 expression was regulated by the level of reduced glutathione (GSH) and suppressed by the oxidative stress regulator, GSK3-β. Our results demonstrate that GFPT2 is a marker for oxidative stress. It is upregulated and controls growth and invasion in the D492 EMT model and is associated with claudin-low and poor prognosis in breast cancer.

Project description:Epithelial-mesenchymal transition (EMT) is a diverse and dynamic biological process which is involved in cancer progression. It is important for carcinoma cells during invasion and metastasis. EMT has been in the spotlight for cancer cells to disseminate to distant organs by gaining partial EMT phenotype. Cancer cells with partial EMT are believed to be more cancerogenic/invasive than cells that have undergone complete EMT. The proteomic changes that occur following EMT in breast epithelial cells and how these relate to changes in cellular metabolism are incompletely understood. To study metabolic reprogramming in different mesenchymal states, we analyzed proteomic changes following EMT in the breast epithelial cell model D492, with single-shot LFQ supported by SILAC proteomic approach. The D492 EMT cell model contains three isogenic cell lines: epithelial D492 cells, mesenchymal D492M cells, and partial mesenchymal, HER2 overexpressing, tumorigenic D492HER2 cells. Proteomic analysis positioned the D492 and D492M cells as basal-like while D492HER2 as claudin-low. Further comparison of the non-tumorigenic D492 and D492M cells to tumorigenic D492HER2 differentiated the metabolic EMT markers of migration from those of invasion. Among these were markers of glycan metabolism. We identified glutamine-fructose-6-phosphate transaminase [isomerizing] 2 (GFPT2) as the top dysregulated enzyme in glycan metabolism and found increased GFPT2 expression was a characteristic of claudin-low breast cancer. siRNA knockdown of GFPT2 influenced both cell growth and invasion in vitro and was accompanied by lowered flux through the hexosamine biosynthesis pathway (HBP). Knockdown of GFPT2 decreased cystathionine and sulfide:quinone oxidoreductase (SQOR) in the transsulfuration pathway which regulates H2S production and mitochondrial homeostasis. Moreover, GFPT2 expression was regulated by the level of reduced glutathione (GSH) and suppressed by the oxidative stress regulator, GSK3-β. Our results demonstrate that GFPT2 is a marker for oxidative stress. It is upregulated and controls growth and invasion in the D492 EMT model and is associated with claudin-low and poor prognosis in breast cancer.

Project description:Numerous epithelial-to-mesenchymal transition (EMT)-promoting transcription factors have been implicated in tumorigenesis or metastasis, as well as chemoresistance of cancer. However, the underlying mechanism mediating these processes is unclear. Here we report that Foxq1, a forkhead box-containing transcription factor and EMT-inducing gene, promotes stemness traits and chemoresistance in mammary epithelial cells. We identify Twist1, Zeb2, and PDGFRα and β as Foxq1 downstream targets using an expression profiling assay. Further studies reveal that PDGFRα and β can be directly regulated by Foxq1, or indirectly through Twist1. Knockdown of both PDGFRα and β shows more significant effects on reversing Foxq1-promoted oncogenesis in vitro and in vivo than knockdown by either PDGFRα or β alone. PDGFRβ, but not PDGFRα, shows potent effects in reversing Foxq1-promoted stemness traits. Moreover, pharmacological inhibition or gene silencing of PDGFRs sensitize mammary epithelial cells to chemotherapeutic agents in vitro and in vivo. These findings collectively indicate PDGFRs as critical mediators underlying breast cancer tumorigenesis and chemoresistance driven by EMT promoting genes, which have potential clinical implications for cancer therapy.

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.