Project description:β-catenin/Tcf7l2 dependent transcriptional regulation of GLUT1 gene expression by Zic family proteins in colon cancer

Project description:Unrestrained transcriptional activity of β-CATENIN and its binding partner TCF7L2 frequently underlies colorectal tumor initiation and is considered an obligatory oncogenic driver throughout intestinal carcinogenesis. Yet, the TCF7L2 gene carries inactivating mutations in about 10 % of colorectal tumors and is non-essential in colorectal cancer (CRC) cell lines. To determine whether CRC cells acquire TCF7L2-independence through cancer-specific compensation by other T-cell factor (TCF)/lymphoid enhancer‑binding factor (LEF) family members, or rather lose addiction to β-CATENIN/TCF7L2-driven gene expression altogether, we generated multiple CRC cell lines entirely negative for TCF/LEF or β-CATENIN expression. Viability of these cells demonstrates complete β‑CATENIN- and TCF/LEF-independence, albeit one β-CATENIN-deficient cell line eventually became senescent. Absence of TCF/LEF proteins and β-CATENIN consistently impaired CRC cell proliferation, reminiscent of mitogenic effects of WNT/β-CATENIN signaling in the healthy intestine. Despite this common phenotype, β-CATENIN-deficient cells exhibited highly cell-line-specific gene expression changes with little overlap between β-CATENIN- and TCF7L2-dependent transcriptomes. Apparently, β‑CATENIN and TCF7L2 control sizeable fractions of their target genes independently from each other. The observed divergence of β-CATENIN and TCF7L2 transcriptional programs, and the finding that neither β-CATENIN nor TCF/LEF activity is strictly required for CRC cell survival has important implications when evaluating these factors as potential drug targets.

Project description:Activation of Wnt/β-catenin signaling plays a central role in the development and progression of colorectal cancer (CRC). Previously, we demonstrated that the Wnt transcription factor, TCF7L2, was overexpressed in primary rectal cancers that were resistant to chemoradiotherapy (CRT), and that TCF7L2 functionally mediates resistance of CRC cells to CRT. However, it remained unclear whether the resistance was mediated by a TCF7L2 inherent mechanism or Wnt/β-catenin signaling in general. We now show that silencing of β-catenin resulted in sensitization of the CRC cell lines LS1034, SW480, and SW837 to CRT, demonstrating a relationship between Wnt/β-catenin signaling and CRT resistance. To investigate the potential role of Wnt/β-catenin signaling in controlling therapeutic responsiveness, non-tumorigenic RPE-1 cells were stimulated with Wnt-3a, a physiological ligand at the Frizzled receptor, which significantly increased resistance to CRT. This effect could be recapitulated by overexpression of mutated, undegradable β-catenin (S33Y). Again, this resulted in a significantly boosted resistance of RPE-1 cells to CRT, which was abrogated by siRNA-mediated silencing of β-catenin. Consistent with these findings, we observed higher expression levels of active (unphosphorylated) β-catenin as well as increased TCF/LEF reporter activity in SW1463 cells that evolved radiation-resistance due to repeated radiation-treatment. Global gene expression profiling identified several altered pathways associated with treatment response as a consequence of Wnt/β-catenin pathway activation, sheading new light on PPARD signaling as a possible mechanism of Wnt mediated resistance. Hence, synergistic pathway inhibition of either Wnt and/or one of the downstream-pathways may represent a promising strategy to increase therapeutic responsiveness to CRT.

Project description:The transcription factor TCF7L2 is indispensable for intestinal tissue homeostasis where it transmits mitogenic Wnt/β-Catenin signals in stem and progenitor cells, from which intestinal tumors arise. Yet, TCF7L2 belongs to the most frequently mutated genes in colorectal cancer (CRC), and growth inhibitory functions of TCF7L2 were proposed. This apparent paradox calls for a clarification of the role of TCF7L2 in colorectal carcinogenesis. Here, we investigated TCF7L2 dependence/independence of CRC cells, and the cellular and molecular consequences of TCF7L2 loss-of-function. By genome editing we readily achieved complete TCF7L2 inactivation in several CRC cell lines without loss of viability, showing that CRC cells have widely lost the strict requirement for TCF7L2. Albeit phenotypic changes manifested in a cell-line-specific fashion, TCF7L2-negative cells exhibited morphological changes, enhanced migration and invasion, and augmented collagen adhesion. Additionally, TCF7L2 deficiency led to reduced proliferation, reminiscent of the physiological role of TCF7L2. To provide a molecular framework for the observed phenotypic changes, we performed global transcriptome profiling. This identified gene-regulatory networks in which TCF7L2 positively regulates the proto-oncogene MYC, while repressing the cell cycle inhibitors CDKN2C/CDKN2D. TCF7L2 also suppresses the pro-metastatic transcription factor RUNX2 and several integrin genes, which is consistent with increased motility and collagen adhesion of TCF7L2-deficient cells. Altogether, we conclude that the proliferation-stimulating activity of TCF7L2 persists in CRC cells. Additionally, TCF7L2 acts as invasion suppressor. Despite its negative impact on cell cycle progression, TCF7L2 loss-of-function may thereby increase malignancy, which could explain why TCF7L2 is mutated in a sizeable fraction of colorectal tumors.

Project description:Activation of the evolutionarily conserved, developmental Wnt pathway has been reported during maladaptive cardiac remodeling. Although the function of Wnt-transcriptional activation in development is well described, the consequences of Wnt pathway activation, as well as its cardiac-specific regulatory role in the adult heart, is largely unknown. We show that β-catenin and Transcription factor 7-like 2 (TCF7L2), the main nuclear components of the Wnt-transcriptional cascade, and their transcriptional activity are increased upon pathological remodeling in both murine and human hearts. To understand the consequences of increased Wnt signaling pathway activity, we utilized an in vivo mouse model in which β-catenin is acutely stabilized in adult cardiomyocytes (CM), leading to increased ventricular TCF7L2 expression and activation of its target genes. Mice with stabilized β-catenin displayed cardiac hypertrophy, increased mortality, reduced cardiac function and altered calcium homeostasis, similar to experimentally induced hypertrophy. Moreover, we observed a re-activation of Wnt-dependent developmental gene programs including activation of the Wnt/β-catenin-independent pathway, increased CM cell cycling with poly-nucleation and cytoskeletal disorganization, underscoring a central role in adult tissue remodeling. By integrating transcriptome analyses and genome-wide occupancy (ChIP-seq) of the endogenous ventricular TCF7L2, we show that upon aberrant Wnt activation, TCF7L2 induces context and Wnt-specific gene regulation in pathological remodeling. Interestingly, β-catenin stabilized ventricles showed increased histone H3 lysine 27 acetylation (H3K27ac) and TCF7L2 recruitment to novel disease-associated gene-specific enhancers. Importantly, using integrative motif analyses and experimental evidences, our data uncovered a role for GATA4 as a cardiogenic regulator of TCF7L2/β-catenin complex and established a paradigm for cell-specific effects of Wnt signaling. Altogether, our studies unraveled the nuclear Wnt-TCF7L2-associated chromatin landscape and its role in adult tissue remodeling leading to heart failure.

Project description:Background: The Ras pathway genes KRAS, BRAF or ERBBs have somatic mutations in ~60% of human colorectal carcinomas. At present, it is unknown whether the remaining cases lack mutations activating the Ras pathway, or whether they have acquired mutations in genes hitherto not known to belong to the pathway. Methods: To address the second possibility, and extend the compendium of Ras pathway genes, we used genome-wide transposon mutagenesis of two human colorectal cancer cell systems deprived of their activating KRAS or BRAF allele to identify genes enabling growth in low glucose, a Ras pathway phenotype, when targeted. Results: Of the 163 recurrently targeted genes in the two different genetic backgrounds, one third were known cancer genes and one-fifth had links to the EGFR/Ras/MAPK pathway. When compared to cancer genome sequencing datasets, 9 genes also mutated in human colorectal cancers were identified. Among these, stable knock-down of FOXO3, NCOA3, and TCF7L2 restored growth in low glucose but reduced MEK/MAPK phosphorylation, reduced anchorage-independent growth, and modulated expressions of GLUT1 and Ras pathway related proteins. Knock-down of NCOA3 and FOXO3 significantly decreased the sensitivity to cetuximab of KRAS mutant but not wild-type cells. Conclusions: This work establishes a proof-of-concept that human cell based genome-wide forward genetic screens can assign genes to pathways with clinical importance in human colorectal cancer.

Project description:Promising activity of BET protein inhibitors (BETis) is compromised by adaptive or innate resistance in AML. Here, modeling of BETi- persister/resistance (BETi-P/R) in human post-MPN secondary AML (sAML) cells demonstrated accessible and active chromatin in specific super-enhancers/enhancers, which was associated with increased levels of nuclear β-catenin, TCF7L2, JMJD6, and c-Myc in BETi-P/R sAML cells. Following BETi treatment, c-Myc levels were rapidly restored in BETi-P/R sAML cells. CRISPR/Cas9-mediated knockout of TCF7L2 or JMJD6 reversed BETi-P/R, whereas ectopic overexpression conferred BETi-P/R in sAML cells; confirming the mechanistic role of the β-catenin-TCF7L2- JMJD6-MYC axis in BETi-resistance. Patient-derived, post-MPN, CD34+ sAML blasts exhibiting relative resistance to BETi, as compared to sensitive sAML blasts, displayed higher mRNA and protein expressions of TCF7L2, JMJD6 and c-Myc, and following BETi washout exhibited rapid restoration of c-Myc and JMJD6. CRISPR/Cas9 knockout of TCF7L2 and JMJD6 depleted their levels, inducing loss of viability of the sAML blasts. Disruption of co-localization of nuclear β-catenin with TBL1 and TCF7L2 by the small molecule inhibitor BC2059 combined with depletion of BRD4 by BET-PROTAC reduced c-Myc levels and exerted synergistic lethality in BETi-P/R sAML cells. This combination also reduced leukemia burden and improved survival of mice engrafted with BETi-P/R sAML cells or with patient-derived AML blasts innately resistant to BETi. Therefore, multi- targeted disruption of β-catenin-TCF7L2-JMJD6-MYC axis overcomes adaptive and innate BETi-resistance, exhibiting pre-clinical efficacy against human post-MPN sAML cells.

Project description:Promising activity of BET protein inhibitors (BETis) is compromised by adaptive or innate resistance in AML. Here, modeling of BETi- persister/resistance (BETi-P/R) in human post-MPN secondary AML (sAML) cells demonstrated accessible and active chromatin in specific super-enhancers/enhancers, which was associated with increased levels of nuclear β-catenin, TCF7L2, JMJD6, and c-Myc in BETi-P/R sAML cells. Following BETi treatment, c-Myc levels were rapidly restored in BETi-P/R sAML cells. CRISPR/Cas9-mediated knockout of TCF7L2 or JMJD6 reversed BETi-P/R, whereas ectopic overexpression conferred BETi-P/R in sAML cells; confirming the mechanistic role of the β-catenin-TCF7L2- JMJD6-MYC axis in BETi-resistance. Patient-derived, post-MPN, CD34+ sAML blasts exhibiting relative resistance to BETi, as compared to sensitive sAML blasts, displayed higher mRNA and protein expressions of TCF7L2, JMJD6 and c-Myc, and following BETi washout exhibited rapid restoration of c-Myc and JMJD6. CRISPR/Cas9 knockout of TCF7L2 and JMJD6 depleted their levels, inducing loss of viability of the sAML blasts. Disruption of co-localization of nuclear β-catenin with TBL1 and TCF7L2 by the small molecule inhibitor BC2059 combined with depletion of BRD4 by BET-PROTAC reduced c-Myc levels and exerted synergistic lethality in BETi-P/R sAML cells. This combination also reduced leukemia burden and improved survival of mice engrafted with BETi-P/R sAML cells or with patient-derived AML blasts innately resistant to BETi. Therefore, multi- targeted disruption of β-catenin-TCF7L2-JMJD6-MYC axis overcomes adaptive and innate BETi-resistance, exhibiting pre-clinical efficacy against human post-MPN sAML cells.

Project description:Promising activity of BET protein inhibitors (BETis) is compromised by adaptive or innate resistance in AML. Here, modeling of BETi- persister/resistance (BETi-P/R) in human post-MPN secondary AML (sAML) cells demonstrated accessible and active chromatin in specific super-enhancers/enhancers, which was associated with increased levels of nuclear β-catenin, TCF7L2, JMJD6, and c-Myc in BETi-P/R sAML cells. Following BETi treatment, c-Myc levels were rapidly restored in BETi-P/R sAML cells. CRISPR/Cas9-mediated knockout of TCF7L2 or JMJD6 reversed BETi-P/R, whereas ectopic overexpression conferred BETi-P/R in sAML cells; confirming the mechanistic role of the β-catenin-TCF7L2- JMJD6-MYC axis in BETi-resistance. Patient-derived, post-MPN, CD34+ sAML blasts exhibiting relative resistance to BETi, as compared to sensitive sAML blasts, displayed higher mRNA and protein expressions of TCF7L2, JMJD6 and c-Myc, and following BETi washout exhibited rapid restoration of c-Myc and JMJD6. CRISPR/Cas9 knockout of TCF7L2 and JMJD6 depleted their levels, inducing loss of viability of the sAML blasts. Disruption of co-localization of nuclear β-catenin with TBL1 and TCF7L2 by the small molecule inhibitor BC2059 combined with depletion of BRD4 by BET-PROTAC reduced c-Myc levels and exerted synergistic lethality in BETi-P/R sAML cells. This combination also reduced leukemia burden and improved survival of mice engrafted with BETi-P/R sAML cells or with patient-derived AML blasts innately resistant to BETi. Therefore, multi- targeted disruption of β-catenin-TCF7L2-JMJD6-MYC axis overcomes adaptive and innate BETi-resistance, exhibiting pre-clinical efficacy against human post-MPN sAML cells.

Project description:TCF7L2 is one of the strongest type 2 diabetes (T2DM) candidate genes to emerge from GWAS studies, but the mechanisms by which it regulates the pathways which are important in the pathogenesis of type 2 diabetes are unknown. Previous in vitro and in vivo studies have focused on the link between TCF7L2 and insulin secretion as an explanation for the association between TCF7L2 and T2DM. However, TCF7L2 and the Wnt/β-catenin pathway are important for metabolic zonation in the liver. This raises the interesting possibility that TCF7L2 may influence glucose homeostasis by regulating hepatic glucose production (HGP). To examine this question, we utilized the H4IIE cell as a model of HGP. Inhibition of HGP in H4IIE cells from lactate and pyruvate was highly sensitive to physiological concentrations of insulin and metformin. Silencing of TCF7L2 protein expression induced a 5-fold increase in basal HGP (P<0.0001), and this was accompanied by marked increase in the expression of several key gluconeogenic genes. FBPase, PEPCK and G6Pase mRNA were up-regulated 2.5-fold (P<0.0001), 1.4-fold (P<0.01) and 2.3-fold (P<0.0001), respectively, compared to scramble siRNA. Compared to their respective baseline values, insulin and metformin suppressed HGP equally in the scramble and TCF7L2 siRNA cells, but HGP remained elevated in TCF7L2 silenced cells due to the increased baseline HGP. Using chromatin immunoprecipitation sequencing (ChIP-Seq), we investigated the direct transcriptional targets of TCF7L2 in hepatocytes. A total of 2119 ChIP peaks were detected, of which 36% were located inside gene boundaries and, overall, a total of 65% of all binding events were within 50 Kb of a gene. De novo motif analysis revealed remarkable conservation of the long and short TCF7L2 consensus binding sites in the rat hepatocytes. Pathway analysis showed that the top two disease categories over-represented in our dataset were “non-insulin dependent diabetes” (155 genes; P = 1.63 x 10-10) and “diabetes mellitus” (245 genes; P = 7.4 x 10-12). Inspection of genes in these categories revealed that TCF7L2 directly binds to multiple genes important in the regulation of glucose metabolism in the liver, including PEPCK, FBP1, IRS1, IRS2, AKT2 ADIPOR1, PDK4 and CPT1A. Our findings suggest a novel mechanism for the regulation of HGP by TCF7L2, and provide a possible explanation for the association of TCF7L2 polymorphisms with the incidence of T2DM. two samples: TCF7L2 ChIP-Seq and Input DNA