Project description:Telomere dysfunction drives chromosomal instability (CIN) during the transition from benign adenoma to malignant adenocarcinoma. While CIN provides a mutator mechanism for cancer- relevant genomic events, its role in shaping tumor biology during carcinogenesis is not well understood. Here, we explored the molecular and biological impact of telomere dysfunction and associated CIN in vivo in a faithful model of CRC. In vivo lineage tracing revealed that CIN increased the rate of neoplastic cell clonal expansion through accelerated differentiation of neighboring stem cells, resulting in increased number of adenomas and decreased survival in CIN-high Apcmin mice. Mechanistically, CIN represses EZH2 leading to upregulation of secreted Wnt antagonists, which resulted in a growth advantage to CIN-high neoplastic cells. Correspondingly, pharmacological activation of intrinsic WNT signaling enhanced intestinal stem cells fitness, leading to reduced neoplastic cell clonal expansion and adenoma burden. Thus, the CIN-EZH2-WNT axis enhances intestinal cancer initiation in the nascent tumor microenvironment, providing a preventive strategy for patients harboring germline APC mutations.

Project description:Telomere dysfunction drives chromosomal instability (CIN) during the transition from benign adenoma to malignant adenocarcinoma. While CIN provides a mutator mechanism for cancer- relevant genomic events, its role in shaping tumor biology during carcinogenesis is not well understood. Here, we explored the molecular and biological impact of telomere dysfunction and associated CIN in vivo in a faithful model of CRC. In vivo lineage tracing revealed that CIN increased the rate of neoplastic cell clonal expansion through accelerated differentiation of neighboring stem cells, resulting in increased number of adenomas and decreased survival in CIN-high Apcmin mice. Mechanistically, CIN represses EZH2 leading to upregulation of secreted Wnt antagonists, which resulted in a growth advantage to CIN-high neoplastic cells. Correspondingly, pharmacological activation of intrinsic WNT signaling enhanced intestinal stem cells fitness, leading to reduced neoplastic cell clonal expansion and adenoma burden. Thus, the CIN-EZH2-WNT axis enhances intestinal cancer initiation in the nascent tumor microenvironment, providing a preventive strategy for patients harboring germline APC mutations.

Project description:Telomere dysfunction drives chromosomal instability (CIN) during the transition from benign adenoma to malignant adenocarcinoma. While CIN provides a mutator mechanism for cancer- relevant genomic events, its role in shaping tumor biology during carcinogenesis is not well understood. Here, we explored the molecular and biological impact of telomere dysfunction and associated CIN in vivo in a faithful model of CRC. In vivo lineage tracing revealed that CIN increased the rate of neoplastic cell clonal expansion through accelerated differentiation of neighboring stem cells, resulting in increased number of adenomas and decreased survival in CIN-high Apcmin mice. Mechanistically, CIN represses EZH2 leading to upregulation of secreted Wnt antagonists, which resulted in a growth advantage to CIN-high neoplastic cells. Correspondingly, pharmacological activation of intrinsic WNT signaling enhanced intestinal stem cells fitness, leading to reduced neoplastic cell clonal expansion and adenoma burden. Thus, the CIN-EZH2-WNT axis enhances intestinal cancer initiation in the nascent tumor microenvironment, providing a preventive strategy for patients harboring germline APC mutations.

Project description:We constructed AAV-vectors for systemic expression of a soluble RSPO1 protein in ApcMin/+ mice. We found that the RSPO1-Fc fusion protein suppresses the Wnt/ß-catenin signaling activity in intestinal adenomas and in adenoma-derived intestinal organoids ex vivo, but not in normal intestinal epithelial cells. In the Apc mutant cells, the RSPO1-Fc fusion protein activated the TGFß/SMAD signaling pathway to suppress several Wnt target genes and adenoma growth, which effect was rescued suppressed by the TGFß receptor kinase inhibitor SB-431542. Simultaneously, RSPO1-Fc induced proliferation of the normal intestinal stem cells, giving them a growth advantage over the mutant cells, which enabled the intestinal epithelium to eventually outgrow the adenoma cells. Prolonged systemic expression of AAV-RSPO1-Fc decreased significantly the number of the intestinal adenomas and improved the overall survival of ApcMin/+ mice. Thus RSPO1-Fc provides the normal intestinal epithelial cells a growth advantage when compared to the adenoma cells, which eventually leads to the extrusion of the adenomatous tissue. An attractive idea now is to exploit such differential response of normal vs. cancer cells in cancer therapy.

Project description:We constructed AAV-vectors for systemic expression of a soluble RSPO1 protein in ApcMin/+ mice. We found that the RSPO1-Fc fusion protein suppresses the Wnt/ß-catenin signaling activity in intestinal adenomas and in adenoma-derived intestinal organoids ex vivo, but not in normal intestinal epithelial cells. In the Apc mutant cells, the RSPO1-Fc fusion protein activated the TGFß/SMAD signaling pathway to suppress several Wnt target genes and adenoma growth, which effect was rescued suppressed by the TGFß receptor kinase inhibitor SB-431542. Simultaneously, RSPO1-Fc induced proliferation of the normal intestinal stem cells, giving them a growth advantage over the mutant cells, which enabled the intestinal epithelium to eventually outgrow the adenoma cells. Prolonged systemic expression of AAV-RSPO1-Fc decreased significantly the number of the intestinal adenomas and improved the overall survival of ApcMin/+ mice. Thus RSPO1-Fc provides the normal intestinal epithelial cells a growth advantage when compared to the adenoma cells, which eventually leads to the extrusion of the adenomatous tissue. An attractive idea now is to exploit such differential response of normal vs. cancer cells in cancer therapy.

Project description:Somatic mutations in APC or CTNNB1 genes lead to aberrant Wnt signaling and colorectal cancer (CRC) initiation and progression. Activation of Wnt pathway leads to the formation of beta-catenin-T-cell factor/Lymphoid enhancer binding factor 1 (Tcf/Lef1) complexes that activate transcription of oncogenic target genes. Lef1 is the only member of the Tcf gene family that is not expressed in the normal intestine, but is induced during intestinal tumorigenesis. Thus, we wanted to assess the role of Lef1 using genetic mouse models of intestinal adenomas and scRNA-seq technology. Tumorigenesis was initiated by inducing Apc mutation in Lgr5+ stem cells. Intestinal EpCAM+ epithelial cells of Lgr5-CreERT;Apc fl/fl (LApc) mouse and Lgr5-CreERT;Apc fl/fl; Lef1 fl/fl (LApcL) mouse were used to analyze the effects of Lef1 deletion in intestinal adenoma cells. We used WT mice as a control to distinguish adenoma cells.

Project description:The gut and liver have been recognized to mutually communicate through the biliary tract, portal vein and systemic circulation, but it remains unclear how this gut-liver axis regulates intestinal physiology. Through hepatectomy, transcriptomics and proteomics profiling, we identified pigment epithelium-derived factor (PEDF), as a liver-derived soluble Wnt inhibitor, that can restrain intestinal stem cells (ISC) hyperproliferation for gut homeostasis by competing with Wnt ligands and suppressing Wnt/beta-catenin signaling pathway. In turn, microbial danger signals from intestinal inflammation can be sensed by the liver to repress PEDF production via peroxisome proliferator-activated receptor-alpha (PPAR alpha), liberating ISC proliferation to accelerate tissue repair in the gut. Further, treatment of mice with fenofibrate, a clinical agent of PPARalpha agonist for hypolipidemia enhances the susceptibility of colitis via PEDF activity. Therefore, we identified a distinct role of PEDF to calibrate ISC expansion for intestinal homeostasis via reciprocal interactions between the gut and liver.

Project description:Constitutive activation of the Wnt pathway leads to adenoma formation, an obligatory step towards intestinal cancer. In view of the established role of Wnt in regulating stemness, we attempted the isolation of cancer stem cells (CSCs) from Apc- and Apc/KRAS-mutant intestinal tumours. Whereas CSCs are present in malignant Apc/KRAS–mutant carcinomas, they appear to be very rare (<10-6) in the benign Apc–mutant adenomas. In contrast, the Lin-CD24hiCD29+ subpopulation of adenocarcinoma cells appear to be enriched in CSCs with increased levels of active -catenin. Expression profiling analysis of the CSC-enriched subpopulation confirmed their enhanced Wnt activity and revealed additional differential expression of other signalling pathways, growth factor binding proteins, and extracellular matrix components. As expected, genes characteristic of the Paneth cell lineage (e.g. defensins) are co-expressed together with stem cell genes (e.g. Lgr5) within the CSC-enriched subpopulation. This is of interest as it may indicate a cancer stem cell niche role for tumor-derived Paneth-like cells, similar to their role in supporting Lgr5+ stem cells in the normal intestinal crypt. Overall, our results indicate that oncogenic KRAS activation in Apc-driven tumours results in the expansion of the CSCs compartment by increasing b-catenin intracellular stabilization. To identify molecular differences between stem-like and more differentiated (bulk) tumour cells from Apc1638N/+ and Apc1638N/+/KRASV12G intestinal adenomas and adenocarcinomas, we isolated total RNA from 104 Lin-CD24hiCD29+, Lin-CD24medCD29+/Lin-CD24loCD29+ and Lin- (bulk) tumour cells from 5 individual mice of each genotype (Apc1638N/+ and Apc1638N/+/KRASV12G). Total RNA samples were then employed to hybridize oligonucleotide microarrays (Affymetrix Mouse Genome 430A 2.0 Array) according to conventional protocols.

Project description:The APC (Adenomatous Polyposis Coli) gene encodes a large multidomain protein that plays an integral role in the Wnt/beta-catenin signaling pathway. The loss-of-function mutation in APC is considered the earliest genetic alteration in the course of adenoma-carcinoma sequence of colorectal cancer progression, and the resulting constitutive activation of Wnt/beta-catenin signaling is required for the maintenance of advanced colorectal cancer. In order to identify genes affected by loss of Apc function, we performed transcription profiling of mouse small intestinal tissues comparing polyps with normal mucosa of Apc+/Delta716 mice. We isolated total RNA from intestinal polyps and normal intestinal mucosa from 3 individual Apc+/Delta716 mice. Total RNA samples were then employed to perform microarray analysis (Agilent Whole Mouse Genome Microarray Ver. 2.0, 4x44K).

Project description:Polycomb-mediated gene repression plays an important role in adult stem cell maintenance. We knocked out (using the inducible AhCre-LoxP system) Polycomb genes Eed and Ezh2 in the intestine for 6 weeks, after which crypts - the small intestinal stem cell zone - were harvested and RNA sequenced. We found Wnt, Notch and cell cycle pathways to be affected in Eed knockout (KO) but not Ezh2 KO crypts. Direct targets of Eed were determined by comparing this data with ChIP-sequencing. Small intestinal crypt mRNA profiles of 6 weeks-induced 12 weeks old Eed KO, Ezh2 KO and WT mice (all triplicates) as well as 10 days-induced Eed KO and WT organoids (duplicates) were generated by RNA sequencing over two runs and using IlluminaHiseq2000 and Hiseq2500.