Your search keyword '"Dufour, Catherine R."' showing total 6 results

1. Hepatocyte FBXW7-dependent activity of nutrient-sensing nuclear receptors controls systemic energy homeostasis and NASH progression in male mice.

Author

Xia, Hui, Dufour, Catherine R., Medkour, Younes, Scholtes, Charlotte, Chen, Yonghong, Guluzian, Christina, B'chir, Wafa, and Giguère, Vincent

Subjects

HOMEOSTASIS, FATTY liver, NUCLEAR receptors (Biochemistry), NON-alcoholic fatty liver disease, UBIQUITIN ligases, FATTY acid oxidation, ENERGY metabolism, LIVER cells, INTRAHEPATIC bile ducts

Abstract

Nonalcoholic steatohepatitis (NASH) is epidemiologically associated with obesity and diabetes and can lead to liver cirrhosis and hepatocellular carcinoma if left untreated. The intricate signaling pathways that orchestrate hepatocyte energy metabolism and cellular stress, intrahepatic cell crosstalk, as well as interplay between peripheral tissues remain elusive and are crucial for the development of anti-NASH therapies. Herein, we reveal E3 ligase FBXW7 as a key factor regulating hepatic catabolism, stress responses, systemic energy homeostasis, and NASH pathogenesis with attenuated FBXW7 expression as a feature of advanced NASH. Multiomics and pharmacological intervention showed that FBXW7 loss-of-function in hepatocytes disrupts a metabolic transcriptional axis conjointly controlled by the nutrient-sensing nuclear receptors ERRα and PPARα, resulting in suppression of fatty acid oxidation, elevated ER stress, apoptosis, immune infiltration, fibrogenesis, and ultimately NASH progression in male mice. These results provide the foundation for developing alternative strategies co-targeting ERRα and PPARα for the treatment of NASH. NASH, nonalcoholic steatohepatitis, a severe fatty liver disease with no cure, can manifest through loss-of-function of the E3 ligase FBXW7. Here, the authors show an underpinning of dysregulated ERRα and PPARα nuclear receptor activity, thus highlighting potential new avenues for antiNASH therapy. [ABSTRACT FROM AUTHOR]

Published

2023

2. Integrated multi-omics analysis of adverse cardiac remodeling and metabolic inflexibility upon ErbB2 and ERRα deficiency.

Author

Dufour, Catherine R., Xia, Hui, B'chir, Wafa, Perry, Marie-Claude, Kuzmanov, Uros, Gainullina, Anastasiia, Dejgaard, Kurt, Scholtes, Charlotte, Ouellet, Carlo, Zuo, Dongmei, Sanguin-Gendreau, Virginie, Guluzian, Christina, Smith, Harvey W., Muller, William J., Audet-Walsh, Etienne, Sergushichev, Alexey A., Emili, Andrew, and Giguère, Vincent

Subjects

*HER2 positive breast cancer, *HEART physiology, *BREAST cancer, *CARDIOVASCULAR diseases risk factors, *CANCER treatment

Abstract

Functional oncogenic links between ErbB2 and ERRα in HER2+ breast cancer patients support a therapeutic benefit of co-targeted therapies. However, ErbB2 and ERRα also play key roles in heart physiology, and this approach could pose a potential liability to cardiovascular health. Herein, using integrated phosphoproteomic, transcriptomic and metabolic profiling, we uncovered molecular mechanisms associated with the adverse remodeling of cardiac functions in mice with combined attenuation of ErbB2 and ERRα activity. Genetic disruption of both effectors results in profound effects on cardiomyocyte architecture, inflammatory response and metabolism, the latter leading to a decrease in fatty acyl-carnitine species further increasing the reliance on glucose as a metabolic fuel, a hallmark of failing hearts. Furthermore, integrated omics signatures of ERRα loss-of-function and doxorubicin treatment exhibit common features of chemotherapeutic cardiotoxicity. These findings thus reveal potential cardiovascular risks in discrete combination therapies in the treatment of breast and other cancers. Murine hearts deficient in ErbB2 and/or ERRα are used to profile the adverse cardiac remodeling associated with potential targeted breast cancer treatments by phosphoproteomic, transcriptomic and metabolomic profiling. [ABSTRACT FROM AUTHOR]

Published

2022

3. Insulin action and resistance are dependent on a GSK3β-FBXW7-ERRα transcriptional axis.

Author

Xia, Hui, Scholtes, Charlotte, Dufour, Catherine R., Ouellet, Carlo, Ghahremani, Majid, and Giguère, Vincent

Subjects

INSULIN resistance, INSULIN sensitivity, INSULIN receptors, METABOLIC syndrome, GENETIC transcription regulation, ENERGY metabolism

Abstract

Insulin resistance, a harbinger of the metabolic syndrome, is a state of compromised hormonal response resulting from the dysregulation of a wide range of insulin-controlled cellular processes. However, how insulin affects cellular energy metabolism via long-term transcriptional regulation and whether boosting mitochondrial function alleviates insulin resistance remains to be elucidated. Herein we reveal that insulin directly enhances the activity of the nuclear receptor ERRα via a GSK3β/FBXW7 signaling axis. Liver-specific deletion of GSK3β or FBXW7 and mice harboring mutations of ERRα phosphosites (ERRα3SA) co-targeted by GSK3β/FBXW7 result in accumulated ERRα proteins that no longer respond to fluctuating insulin levels. ERRα3SA mice display reprogrammed liver and muscle transcriptomes, resulting in compromised energy homeostasis and reduced insulin sensitivity despite improved mitochondrial function. This crossroad of insulin signaling and transcriptional control by a nuclear receptor offers a framework to better understand the complex cellular processes contributing to the development of insulin resistance. The downstream mechanisms involved in insulin signaling and resistance remain incompletely understood. Here the authors report that insulin-dependent dephosphorylation stabilizes ERRα via the GSK3β/FBXW7 axis, and disruption of this post-translational mechanism results in insulin resistance in mice. [ABSTRACT FROM AUTHOR]

Published

2022

4. Loss of hepatic Flcn protects against fibrosis and inflammation by activating autophagy pathways.

Author

Paquette, Mathieu, Yan, Ming, Ramírez-Reyes, Josué M. J., El-Houjeiri, Leeanna, Biondini, Marco, Dufour, Catherine R., Jeong, Hyeonju, Pacis, Alain, Giguère, Vincent, Estall, Jennifer L., Siegel, Peter M., Audet-Walsh, Étienne, and Pause, Arnim

Subjects

NON-alcoholic fatty liver disease, FATTY liver, AUTOPHAGY, CHOLINE, LABORATORY mice, FIBROSIS, METHIONINE, LIPIDS

Abstract

Non-alcoholic fatty liver disease (NAFLD) is the most frequent liver disease worldwide and can progress to non-alcoholic steatohepatitis (NASH), which is characterized by triglyceride accumulation, inflammation, and fibrosis. No pharmacological agents are currently approved to treat these conditions, but it is clear now that modulation of lipid synthesis and autophagy are key biological mechanisms that could help reduce or prevent these liver diseases. The folliculin (FLCN) protein has been recently identified as a central regulatory node governing whole body energy homeostasis, and we hypothesized that FLCN regulates highly metabolic tissues like the liver. We thus generated a liver specific Flcn knockout mouse model to study its role in liver disease progression. Using the methionine- and choline-deficient diet to mimic liver fibrosis, we demonstrate that loss of Flcn reduced triglyceride accumulation, fibrosis, and inflammation in mice. In this aggressive liver disease setting, loss of Flcn led to activation of transcription factors TFEB and TFE3 to promote autophagy, promoting the degradation of intracellular lipid stores, ultimately resulting in reduced hepatocellular damage and inflammation. Hence, the activity of FLCN could be a promising target for small molecule drugs to treat liver fibrosis by specifically activating autophagy. Collectively, these results show an unexpected role for Flcn in fatty liver disease progression and highlight new potential treatment strategies. [ABSTRACT FROM AUTHOR]

Published

2021

5. Targeting EZH2 reactivates a breast cancer subtype-specific anti-metastatic transcriptional program.

Author

Hirukawa, Alison, Smith, Harvey W., Dongmei Zuo, Dufour, Catherine R., Savage, Paul, Bertos, Nicholas, Johnson, Radia M., Tung Bui, Bourque, Guillaume, Basik, Mark, Giguère, Vincent, Park, Morag, and Muller, William J.

Subjects

BREAST cancer, EPIGENOMICS, POST-translational modification, CANCER invasiveness

Abstract

Emerging evidence has illustrated the importance of epigenomic reprogramming in cancer, with altered post-translational modifications of histones contributing to pathogenesis. However, the contributions of histone modifiers to breast cancer progression are unclear, and how these processes vary between molecular subtypes has yet to be adequately addressed. Here we report that genetic or pharmacological targeting of the epigenetic modifier Ezh2 dramatically hinders metastatic behaviour in both a mouse model of breast cancer and patient-derived xenografts reflective of the Luminal B subtype. We further define a subtype-specific molecular mechanism whereby EZH2 maintains H3K27me3-mediated repression of the FOXC1 gene, thereby inactivating a FOXC1-driven, anti-invasive transcriptional program. We demonstrate that higher FOXC1 is predictive of favourable outcome specifically in Luminal B breast cancer patients and establish the use of EZH2 methyltransferase inhibitors as a viable strategy to block metastasis in Luminal B breast cancer, where options for targeted therapy are limited. [ABSTRACT FROM AUTHOR]

Published

2018

6. An ErbB2/c-Src axis links bioenergetics with PRC2 translation to drive epigenetic reprogramming and mammary tumorigenesis.

Author

Smith, Harvey W., Hirukawa, Alison, Sanguin-Gendreau, Virginie, Nandi, Ipshita, Dufour, Catherine R., Zuo, Dongmei, Tandoc, Kristofferson, Leibovitch, Matthew, Singh, Salendra, Rennhack, Jonathan P., Swiatnicki, Matthew, Lavoie, Cynthia, Papavasiliou, Vasilios, Temps, Carolin, Carragher, Neil O., Unciti-Broceta, Asier, Savage, Paul, Basik, Mark, van Hoef, Vincent, and Larsson, Ola

Abstract

Dysregulation of histone modifications promotes carcinogenesis by altering transcription. Breast cancers frequently overexpress the histone methyltransferase EZH2, the catalytic subunit of Polycomb Repressor Complex 2 (PRC2). However, the role of EZH2 in this setting is unclear due to the context-dependent functions of PRC2 and the heterogeneity of breast cancer. Moreover, the mechanisms underlying PRC2 overexpression in cancer are obscure. Here, using multiple models of breast cancer driven by the oncogene ErbB2, we show that the tyrosine kinase c-Src links energy sufficiency with PRC2 overexpression via control of mRNA translation. By stimulating mitochondrial ATP production, c-Src suppresses energy stress, permitting sustained activation of the mammalian/mechanistic target of rapamycin complex 1 (mTORC1), which increases the translation of mRNAs encoding the PRC2 subunits Ezh2 and Suz12. We show that Ezh2 overexpression and activity are pivotal in ErbB2-mediated mammary tumourigenesis. These results reveal the hitherto unknown c-Src/mTORC1/PRC2 axis, which is essential for ErbB2-driven carcinogenesis. Polycomb Repressor Complex 2 (PRC2) is frequently up-regulated in cancers. Here, the authors show that the tyrosine kinase c-Src stimulates mitochondrial function to signal energy sufficiency to mTORC1, increasing translation of the PRC2 subunits EZH2 and SUZ12 to support ErbB2-dependent tumours. [ABSTRACT FROM AUTHOR]

Published

2019