β-catenin-activated hepatocellular carcinomas are addicted to fatty acids

Autoantibody against β1-adrenoceptor promotes the differentiation of natural regulatory T cells from activated CD4+ T cells by up-regulating AMPK-mediated fatty acid oxidation

Therapeutic adoptive transfer of natural regulatory T cells (nTreg, CD4⁺ CD25⁺ Foxp3⁺ T cells) or in vivo selective expansion of nTreg cells has been demonstrated to improve the cardiac function in various cardiovascular disease models. The differentiation of nTreg cells is mediated by catecholamines via β₁-adrenergic receptor (β₁-AR) activation. Autoantibody against β₁-adrenoceptor (β₁-AA) as a β₁-AR agonist is closely associated with the occurrence and deterioration of cardiac dysfunction. However, whether β₁-AA has any impact on nTreg cells has not been reported. The aim of the present study was intended to assess the potential impact of β₁-AA on nTreg cell differentiation and explore the underlying mechanism. It was found that the expression of multiple proteins involved in nTreg cell differentiation, immunosuppressive function, and migration was up-regulated in mice after β₁-AA administration, suggesting that β₁-AA may promote nTreg cell activation. In vitro, β₁-AA promoted nTreg cell differentiation by up-regulating mitochondrial fatty acid oxidation (FAO) in activated CD4⁺ T cells via AMP-activated protein kinase (AMPK) activation and mitochondrial membrane potential reduction. In addition, the AMPK agonist facilitated β₁-AA-mediated FAO and nTreg cell differentiation. To further confirm the role of AMPK in β₁-AA-mediated nTreg cell differentiation, β₁-AA was acted on the CD4⁺ T cells isolated from AMPK-deficient (AMPK^−/−) mice. The result showed that the effect of β₁-AA on nTreg cell differentiation was attenuated markedly after AMPK knockout. In conclusion, AMPK-mediated metabolic regulation targeting for nTreg cell restoration may be a promising therapeutic target for β₁-AA-positive patients with cardiac dysfunction.

Lipid Metabolic Reprogramming in Hepatocellular Carcinoma

Metabolic reprogramming for adaptation to the local environment has been recognized as a hallmark of cancer. Although alterations in fatty acid (FA) metabolism in cancer cells have received less attention compared to other metabolic alterations such as glucose or glutamine metabolism, recent studies have uncovered the importance of lipid metabolic reprogramming in carcinogenesis. Obesity and nonalcoholic steatohepatitis (NASH) are well-known risk factors of hepatocellular carcinoma (HCC), and individuals with these conditions exhibit an increased intake of dietary FAs accompanied by enhanced lipolysis of visceral adipose tissue due to insulin resistance, resulting in enormous exogenous FA supplies to hepatocytes via the portal vein and lymph vessels. This “lipid-rich condition” is highly characteristic of obesity- and NASH-driven HCC. Although the way in which HCC cells adapt to such a condition and exploit it to aid their progression is not understood, we recently obtained new insights into this mechanism through lipid metabolic reprogramming. In addition, accumulating evidence supports the importance of lipid metabolic reprogramming in various situations of hepatocarcinogenesis. Thus, in this review, we discuss the latest findings regarding the role of FA metabolism pathways in hepatocarcinogenesis, focusing on obesity- and NASH-driven lipid metabolic reprogramming.

Dimensions of hepatocellular carcinoma phenotypic diversity

Hepatocellular carcinoma (HCC) is the 3^rd leading cause of cancer-related death worldwide. More than 80% of HCCs arise within chronic liver disease resulting from viral hepatitis, alcohol, hemochromatosis, obesity and metabolic syndrome or genotoxins. Projections based on Western lifestyle and its metabolic consequences anticipate a further increase in incidence, despite recent breakthroughs in the management of viral hepatitis. HCCs display high heterogeneity of molecular phenotypes, which challenges clinical management. However, emerging molecular classifications of HCCs have not yet formed a unified corpus translatable to the clinical practice. Thus, patient management is currently based upon tumor number, size, vascular invasion, performance status and functional liver reserve. Nonetheless, an impressive body of molecular evidence emerged within the last 20 years and is becoming increasingly available to medical practitioners and researchers in the form of repositories. Therefore, the aim this work is to review molecular data underlying HCC classifications and to organize this corpus into the major dimensions explaining HCC phenotypic diversity. Major efforts have been recently made worldwide toward a unifying “clinically-friendly” molecular landscape. As a result, a consensus emerges on three major dimensions explaining the HCC heterogeneity. In the first dimension, tumor cell proliferation and differentiation enabled allocation of HCCs to two major classes presenting profoundly different clinical aggressiveness. In the second dimension, HCC microenvironment and tumor immunity underlie recent therapeutic breakthroughs prolonging patients’ survival. In the third dimension, metabolic reprogramming, with the recent emergence of subclass-specific metabolic profiles, may lead to adaptive and combined therapeutic approaches. Therefore, here we review recent molecular evidence, their impact on tumor histopathological features and clinical behavior and highlight the remaining challenges to translate our cognitive corpus into patient diagnosis and allocation to therapeutic options.

The macroenviromental control of cancer metabolism by p62

Metabolic reprogramming is a hallmark of cancer, but most studies focus on the molecular alterations in cancer cells and much less is known on the role of cancer metabolism, from a holistic perspective, for tumor initiation and progression. Increasing epidemiological evidence highlights the tremendous impact that cancer progression has on the host metabolism, especially in cachexia. However, how this benefits the tumor still is not completely understood. Here we review current studies on fatty acid oxidation in tumor cells as a potential therapeutic target in cancer, and how the redistribution of lipids from fat reservoirs to the cancer cell in the micro- and macro-environment impacts tumorigenesis by helping the tumor fulfill its energetic demands at the expense of fat. In this context, we also discuss the critical role of the signaling adaptor p62/Sequestosome 1(SQSTM1) in adipocytes in mediating tumor-induced fat reprograming and the feedback of adipose tissue on tumor aggressiveness via osteopontin and its potential implications in obesity-promoted cancer and fat cachexia. Collectively these studies highlight the importance of the symbiotic collaboration between adipose tissue and tumor to modulate the cancer metabolic fitness.

Même l’effet Warburg est oxydable

Au cours du développement tumoral, les cellules malignes reprogramment leur métabolisme pour répondre à la demande en biosynthèses conditionnant l’augmentation de leur biomasse et pour s’adapter aux propriétés de leur microenvironnement. Les avancées récentes de la recherche ont révélé l’étonnante flexibilité des cellules cancéreuses qui alternent entre un métabolisme glycolytique aérobie (appelé effet Warburg) et un métabolisme oxydatif en fonction de leurs conditions de développement, une plasticité métabolique requérant une mutualisation de leurs ressources énergétiques. Dans cette revue, nous présentons ces nouvelles découvertes et discutons d’un modèle décrivant la tumeur comme un écosystème métabolique évolutif tout en insistant sur les applications thérapeutiques qui en découlent.