UNLABELLED: β-catenin signaling can be both a physiological and oncogenic pathway in the liver. It controls compartmentalized gene expression, allowing the liver to ensure its essential metabolic function. It is activated by mutations in 20%-40% of hepatocellular carcinomas (HCCs) with specific metabolic features. We decipher the molecular determinants of β-catenin-dependent zonal transcription using mice with β-catenin-activated or -inactivated hepatocytes, characterizing in vivo their chromatin occupancy by T-cell factor (Tcf)-4 and β-catenin, transcriptome, and metabolome. We find that Tcf-4 DNA bindings depend on β-catenin. Tcf-4/β-catenin binds Wnt-responsive elements preferentially around β-catenin-induced genes. In contrast, genes repressed by β-catenin bind Tcf-4 on hepatocyte nuclear factor 4 (Hnf-4)-responsive elements. β-Catenin, Tcf-4, and Hnf-4α interact, dictating β-catenin transcription, which is antagonistic to that elicited by Hnf-4α. Finally, we find the drug/bile metabolism pathway to be the one most heavily targeted by β-catenin, partly through xenobiotic nuclear receptors. CONCLUSIONS: β-catenin patterns the zonal liver together with Tcf-4, Hnf-4α, and xenobiotic nuclear receptors. This network represses lipid metabolism and exacerbates glutamine, drug, and bile metabolism, mirroring HCCs with β-catenin mutational activation.
UNLABELLED: β-catenin signaling can be both a physiological and oncogenic pathway in the liver. It controls compartmentalized gene expression, allowing the liver to ensure its essential metabolic function. It is activated by mutations in 20%-40% of hepatocellular carcinomas (HCCs) with specific metabolic features. We decipher the molecular determinants of β-catenin-dependent zonal transcription using mice with β-catenin-activated or -inactivated hepatocytes, characterizing in vivo their chromatin occupancy by T-cell factor (Tcf)-4 and β-catenin, transcriptome, and metabolome. We find that Tcf-4 DNA bindings depend on β-catenin. Tcf-4/β-catenin binds Wnt-responsive elements preferentially around β-catenin-induced genes. In contrast, genes repressed by β-catenin bind Tcf-4 on hepatocyte nuclear factor 4 (Hnf-4)-responsive elements. β-Catenin, Tcf-4, and Hnf-4α interact, dictating β-catenin transcription, which is antagonistic to that elicited by Hnf-4α. Finally, we find the drug/bile metabolism pathway to be the one most heavily targeted by β-catenin, partly through xenobiotic nuclear receptors. CONCLUSIONS: β-catenin patterns the zonal liver together with Tcf-4, Hnf-4α, and xenobiotic nuclear receptors. This network represses lipid metabolism and exacerbates glutamine, drug, and bile metabolism, mirroring HCCs with β-catenin mutational activation.
Authors: Weiqi Zhang; Jennifer Meyfeldt; Huabo Wang; Sucheta Kulkarni; Jie Lu; Jordan A Mandel; Brady Marburger; Ying Liu; Joanna E Gorka; Sarangarajan Ranganathan; Edward V Prochownik Journal: J Biol Chem Date: 2019-10-09 Impact factor: 5.157
Authors: Linh M Vuong; Karthikeyani Chellappa; Joseph M Dhahbi; Jonathan R Deans; Bin Fang; Eugene Bolotin; Nina V Titova; Nate P Hoverter; Stephen R Spindler; Marian L Waterman; Frances M Sladek Journal: Mol Cell Biol Date: 2015-08-03 Impact factor: 4.272