Project description:Microenvironment has been suggested as an important factor contributing to how the colorectal cancer cells escape therapy, but the exact mechanism leading to chemoresistance remains elusive. Here, through modeling in vitro by cocultivation of patient-derived cancer associated fibroblasts (CAFs) with cancer stem cells (CSCs), we show that CAFs-secreted TGF-β2 is a key stromal factor that coordinates with hypoxia to promote CSC stemness and resistance to chemotherapy. GLI2, a key transcription factor of Hedgehog pathway, was identified as both necessary and sufficient in this process in which TGF-β and hypoxia-inducible factor (HIF-1α) synergize to directly induce GLI2 expression. Conversely, CSC-secreted TGF-β is also important to support the growth of CAFs but instead induce death of normal fibroblasts, suggesting a reciprocal mechanism to selectively support the CAF-CSC interaction. Small molecule inhibition of both TGF-β and GLI2 effectively reversed the chemoresistance. Finally, expression of TGFB2/HIF1A/GLI2 gene signature as a functional readout of this resistance pathway defines worse clinical outcomes and predicts patients relapse. Our observations uncover a key role of TGF-β/HIF-1α/GLI2 in microenvironment-mediated chemoresistance and reveal novel biomarker and targeting strategies to identify and treat the high risk CRC patients.

Project description:Ovarian cancer (OC) is the leading cause of death from gynecologic malignancies in the US. Ovarian cancer stem cells (OCSCs) have been shown to drive chemoresistance and tumor progression but the mechanism remains incompletely understood. Aldehyde Dehydrogenase 1A1 (ALDH1A1) is a robust marker for cancer stem cells in ovarian and other cancers. We demonstrate that ALDH1A1 inhibition suppresses stemness, chemoresistance and senescence in ovarian cancer.

Project description:By using a small molecule compound library targeting epigenetic enzymes we have identified BRD9 enzyme for eliminating CSCs. Genomic and proteomic studies revealed that BRD9/BAF complex regulates expression of stemness factors and chemoresistance by cooperating with TGFβ/Activin-SMAD2/3 signalling pathway. Chemical inhibition and genetic loss of function of BDR9 blocks the self-renewal of CSCs, reduces CSC invasiveness and resensitizes PDAC CSCs to conventional therapies. Analyses of chromatin architecture showed that BRD9 regulates the 3D chromatin looping between promoters and enhancers of stemness genes and EMT regulators in CSCs. BRD9 inhibition abrogated tumour formation in mice and eliminated CSCs in tumours from pancreatic cancer patients. Collectively, we uncovered BRD9 enzyme as an attractive therapeutic target for re-sensitizing and eliminating CSCs in pancreatic cancer patients.

Project description:Cancer stem cells (CSCs) drive tumor growth, metastasis, relapse, and chemoresistance. However, it’s unclear how lipid metabolism, especially sphingolipids metabolism, regulates CSCs and chemoresistance. In this study, we developed spontaneous tumor models expressing a Sox9-GFP transgenic reporter and demonstrated that cancer cells expressing high levels of SOX9 functioned as CSCs in both primary tumors and metastases. Transcriptomics analyses uncovered that SOX9high CSCs upregulate ABCA12 lipid transporter. Functionally, downregulation of ABCA12 impaired cancer stemness and chemoresistance of SOX9high cells. Through lipidomic analysis, we demonstrated that ABCA12 regulates SOX9 expression and cancer stemness by controlling ceramide abundance. Blocking ceramide hydrolysis using acid ceramidase inhibitor D-NMAPPD sensitized tumors to chemotherapy and prevented enrichment of SOX9high CSCs. These data suggest a potential strategy for targeting CSCs and overcoming chemoresistance. We further demonstrated that ceramide inhibits the YAP/TAZ signaling that is required for SOX9 expression in breast CSCs.

Project description:Activation of glycolytic genes by HIF-1 is considered critical for metabolic adaptation to hypoxia. We found that HIF-1 also actively suppresses glucose metabolism through the tricarboxylic acid cycle (TCA) by directly trans-activating the gene encoding pyruvate dehydrogenase kinase 1 (PDK1). PDK1 inactivates the TCA cycle enzyme, pyruvate dehydrogenase (PDH), which converts pyruvate to acetyl-CoA. Forced PDK1 expression in hypoxic HIF-1α-null cells increases ATP levels, attenuates hypoxic ROS generation and rescues these cells from hypoxia-induced apoptosis. These studies reveal a novel hypoxia-induced metabolic switch that shunts glucose metabolites from the mitochondria to glycolysis to maintain ATP production and to prevent toxic ROS production. Experiment Overall Design: We sought to determine by microarray analysis of gene expression the genes responsive to hypoxia using the human B lymphocyte cell line, P493-6. Hypoxia-responsive genes were globally assessed in cells incubated in 0.1% O2 for 29 hours at which the highest HIF-1 levels were obtained

Project description:Post-treatment recurrence remains a major clinical challenge in colorectal cancer (CRC), and increasing evidence suggests that Cancer Stem Cells (CSCs) may mediate this process due to their enhanced resistance to conventional therapeutics. We hypothesized that the Pregnane-X receptor (PXR) may drive the chemoresistance of colorectal CSCs.. shRNA-mediated PXR down-regulation was used to analyze the role of PXR on self-renewal in the colorectal cancer cell Line LS174T. Expression and activity of PXR were quantified under conditions that promote Cancer Stem Cells (CSCs) enrichment. Conversely, CSC characterization was performed in cells enriched along their PXR activity level.

Project description:Ovarian cancer (OC) displays the highest mortality among gynecological tumors, mainly due to early peritoneal dissemination, the high frequency of tumor relapse following primary debulking and the development of chemoresistance. All these events are thought to be initiated and sustained by a subpopulation of neoplastic cells, termed ovarian cancer stem cells (OCSC), that are endowed with self-renewing and tumor-initiating properties. This implies that interfering with OCSC function should offer novel therapeutic perspectives to defeat OC progression. To this aim, a better understanding of the molecular and functional makeup of OCSC in clinically relevant model systems is essential. We have profiled the transcriptome of OCSC vs. their bulk cell counterpart from a panel of patient-derived OC cell cultures. This revealed that Matrix Gla Protein (MGP), classically known as a calcification-preventing factor in cartilage and blood vessels, is markedly enriched in OCSC. Functional assays showed that MGP confers several stemness-associated traits to OC cells, including a transcriptional reprogramming. Patient-derived organotypic cultures pointed to the peritoneal microenvironment as a major inducer of MGP expression in OC cells. Furthermore, MGP was found to be necessary and sufficient for tumor initiation in OC mouse models, by shortening tumor latency and increasing dramatically the frequency of tumor-initiating cells. Mechanistically, MGP-driven OC stemness was mediated by the stimulation of Hedgehog signaling, in particular through the induction of the Hedgehog effector GLI1, thus highlighting a novel MGP/Hedgehog pathway axis in OCSC. Finally, MGP expression was found to correlate with poor prognosis in OC patients, and was increased in tumor tissue after chemotherapy, supporting the clinical relevance of our findings. Thus, MGP is a novel driver in OCSC pathophysiology, with a major role in stemness and in tumor initiation.

Project description:Most studies of cancer stem cells (CSC) involve the inoculation of cells from human tumors into immunosuppressed mice, preventing an assessment on the immunologic interactions and effects of CSCs. In this study, the investigators examined the vaccination effects produced by CSC-enriched populations from histologically distinct murine tumors after their inoculation into different syngeneic immunocompetent hosts. Enriched CSCs were immunogenic and more effective as an antigen source than unselected tumor cells in inducing protective antitumor immunity.Immune sera from CSC-vaccinated hosts contained high levels of IgG which bound to CSCs, resulting in CSC lysis in the presence of complement.CTLs generated from peripheral blood mononuclear cells or splenocytes harvested from CSC-vaccinated hosts were capable of killing CSCs in vitro. Mechanistic investigations established that CSC-primed antibodies and T cells were capable of selective targeting CSCs and conferring anti-tumor immunity.

Project description:To prove that hypoxia generates Cancer stem cells (CSCs) from non-CSCs, we needed to separate out already existing tumorigenic cells from the cell population. To identify CSCs, we used ES cell-specific cell surface antigens (SSEA-1, -3, -4, and Tra1-81) on the assumption that the immature cell fraction would be rich in CSCs. We analyzed the expression levels of such embryonic antigens and stemness genes in cells exposed to hypoxia. iPS (253G1), SSEA-1 positive-N417 3 of SSEA-1/3 double negative-N417, each condition is represented by 3 biological replicates

Project description:Background: Identification and purification of cancer stem cells (CSCs) lead to new therapeutic targets; however, there has been no study to identify and isolated pancreatic neuroendocrine tumor (pNET) CSC. Therefore the clinical significance and its target remain unknown. This study aimed to identify pNET CSCs and characterize therapeutic candidate for pNET CSCs. Methods: We isolated CSCs sorting by ALDH activity in pNET surgical section and cell lines. We verified whether these cells have the property of stemness in vivo and in vitro. Additionally in order to acquire CSC gene profile, genome-wide gene expression profiles were investigated using a microarray technique. Results: ALDHhigh cells, but not control bulk cells, formed spheres, proliferated in hypoxia as well as normoxia and promoted cell motility, which are features of CSCs. Injection of as few as 10 ALDHhigh cells led to subcutaneous tumor formation, and 105 ALDHhigh cells established metastases but not control bulk cells in mice. Comprehensive gene expression analysis revealed that genes associated with mesenchymal stem cell, including CD73, and epithelial-mesenchymal transition (EMT) were overexpressed in ALDHhigh cells. APCP, which is CD73 inhibitor, inhibited sphere formation and cell motility in ALDHhigh cells in vitro, and tumor growth inhibition were observed in ALDHhigh cells in vivo. Conclusions: We identified ALDHhigh cells of pNET and elucidated that they have stemness property. Furthermore we identified CD73 as a target of ALDHhigh cells. CD73 is a promising novel target of pNET CSCs.