Inhibition of mitochondrial dynamics preferentially targets pancreatic cancer cells with enhanced tumorigenic and invasive potential

Pancreatic ductal adenocarcinoma (PDAC) is one of the deadliest tumors, partly due to its intrinsic aggressiveness, metastatic potential, and chemoresistance of the contained cancer stem cells (CSCs). Pancreatic CSCs strongly rely on mitochondrial metabolism to maintain their stemness, therefore representing a putative target for their elimination. Since mitochondrial homeostasis de-pends on the tightly controlled balance between fusion and fission processes, namely mitochondrial dynamics, we aim to study this mechanism in the context of stemness. In human PDAC tissues, the mitochondrial fission gene DNM1L (DRP1) was overexpressed and positively correlated with the stemness signature. Moreover, we observe that primary human CSCs display smaller mitochondria and a higher DRP1/MFN2 expression ratio, indicating the activation of the mitochondrial fission. In-terestingly, treatment with the DRP1 inhibitor mDivi-1 induced dose-dependent apoptosis, especially in CD133+ CSCs, due to the accumulation of dysfunctional mitochondria and the subsequent energy crisis in this subpopulation. Mechanistically, mDivi-1 inhibited stemness-related features, such as self-renewal, tumorigenicity, and invasiveness and chemosensitized the cells to the cytotoxic effects of Gemcitabine. In summary, mitochondrial fission is an essential process for pancreatic CSCs and represents an attractive target for designing novel multimodal treatments that will more efficiently eliminate cells with high tumorigenic potentialThis research was funded by the Pancreatic Cancer Research Fund, 2015 Award Round (P.S., C.H.); the European Community’s Seventh Framework Programme (FP7/2007-2013) under grant agreement n 602783 (CAM-PaC) (C.H.), theWorldwide Cancer Research Charity together with Fundación Científica Asociación Española contra el Cáncer (FCAECC) (19-0250) (P.S.); A Fero Foundation grant and a Coordinated grant (GC16173694BARB) from the Fundación Asociación Española Contra el Cáncer (AECC) (B.S.J.); and the Instituto de Salud Carlos III through the Miguel Servet Program (CP16/00121) and Fondo de Investigaciones Sanitarias (PI17/00082) (both co-financed by European funds (FSE: “El FSE invierte en tu futuro” and FEDER: “Una manera de hacer Europa,” respectively) (P.S.

Regulation of hepatic cardiolipin metabolism by TNFα: Implication in cancer cachexia

International audienceCardiolipin (CL) content accumulation leads to an increase in energy wasting in liver mitochondria in a rat model of cancer cachexia in which tumor necrosis factor alpha (TNFα) is highly expressed. In this study we investigated the mechanisms involved in liver mitochondria CL accumulation in cancer cachexia and examined if TNFα was involved in this process leading to mitochondrial bioenergetics alterations. We studied gene, protein expression and activity of the main enzymes involved in CL metabolism in liver mitochondria from a rat model of cancer cachexia and in HepaRG hepatocyte-like cells exposed to 20 ng/ml of TNFα for 12 h. Phosphatidylglycerolphosphate synthase (PGPS) gene expression was increased 2.3-fold (p < 0.02) and cardiolipin synthase (CLS) activity decreased 44% (p < 0.03) in cachectic rat livers compared to controls. CL remodeling enzymes monolysocardiolipin acyltransferase (MLCL AT-1) activity and tafazzin (TAZ) gene expression were increased 30% (p < 0.01) and 50% (p < 0.02), respectively, in cachectic rat livers compared to controls. Incubation of hepatocytes with TNFα increased CL content 15% (p < 0.05), mitochondrial oxygen consumption 33% (p < 0.05), PGPS gene expression 44% (p < 0.05) and MLCL AT-1 activity 20% (p < 0.05) compared to controls. These above findings strongly suggest that in cancer cachexia, TNFα induces a higher energy wasting in liver mitochondria by increasing CL content via upregulation of PGPS expression

Hepatic cardiolipin : involvment in energetic conversion and metabolism during cancer cachexia

Les cardiolipines (CL), phospholipides spécifiques des membranes mitochondriales, sont impliquées dans différentes fonctions mitochondriales. Il a été précédemment démontré que l’accumulation des CL entraînait une augmentation du gaspillage énergétique mitochondrial hépatique et une réduction du rendement de la synthèse d’ATP. Ces travaux de thèse montrent qu’à l’inverse, une diminution modérée de la quantité de CL (- 45 %) induit une réduction des capacités oxydatives mitochondriales sans diminuer la synthèse d’ATP et donc une augmentation de l’efficacité de la synthèse d’ATP. Nous démontrons également les mécanismes conduisant à l’accumulation des cardiolipines hépatiques en situation de cachexie cancéreuse. Le TNFa, cytokine proinflammatoire impliquée dans la cachexie cancéreuse, induit une surexpression spécifique de la phosphatidylglycérolphosphate synthase. La surexpression de cette enzyme impliquée dans la synthèse de novo des CL entraîne une accumulation de CL, responsable du gaspillage énergétique mitochondrial.Cardiolipin (CL), a specific mitochondrial phospholipid, is involved in various mitochondrial functions. It has been shown that CL accumulation led to increased mitochondrial hepatic energy wasting and reduced ATP synthesis efficiency. This work showed, on the opposite, that moderate reduction in CL content (-45%) induced a decrease in mitochondrial oxidative capacity without decreasing ATP synthesis rate and thus an increased ATP synthesis efficiency. Then we demonstrated mechanisms responsible for hepatic cardiolipin accumulation during cancer cachexia. TNFa, proinflammatory cytokine involved in cancer cachexia, induced a specific overexpression of phosphatidylglycerolphosphate synthase. Overexpression of this enzyme involved into CL de novo biosynthesis led to CL accumulation, responsible for energy wasting during cancer

Reduced cardiolipin content decreases respiratory chain capacities and increases ATP synthesis yield in the human HepaRG cells

International audienceCardiolipin (CL) is a unique mitochondrial phospholipid potentially affecting many aspects of mitochondrial function/processes, i.e. energy production through oxidative phosphorylation. Most data focusing on implication of CL content and mitochondrial bioenergetics were performed in yeast or in cellular models of Barth syndrome. Previous work reported that increase in CL content leads to decrease in liver mitochondrial ATP synthesis yield. Therefore the aim of this study was to determine the effects of moderate decrease in CL content on mitochondrial bioenergetics in human hepatocytes. For this purpose, we generated a cardiolipin synthase knockdown (shCLS) in HepaRG hepatoma cells showing bioenergetics features similar to primary human hepatocytes. shCLS cells exhibited a 55% reduction in CLS gene and a 40% decrease in protein expression resulting in a 45% lower content in CL compared to control (shCTL) cells. Oxygen consumption was significantly reduced in shCLS cells compared to shCTL regardless of substrate used and energy state analyzed. Mitochondrial low molecular weight supercomplexes content was higher in shCLS cells (+ 60%) compared to shCTL. Significant fragmentation of the mitochondrial network was observed in shCLS cells compared to shCTL cells. Surprisingly, mitochondrial ATP synthesis was unchanged in shCLS compared to shCTL cells but exhibited a higher ATP:O ratio (+ 46%) in shCLS cells. Our results suggest that lowered respiratory chain activity induced by moderate reduction in CL content may be due to both destabilization of supercomplexes and mitochondrial network fragmentation. In addition, CL content may regulate mitochondrial ATP synthesis yield

Defects in mitophagy promote redox-driven metabolic syndrome in the absence of TP53INP1

International audienceThe metabolic syndrome covers metabolic abnormalities including obesity and type 2 diabetes (T2D). T2D is characterized by insulin resistance resulting from both environmental and genetic factors. A genome-wide association study (GWAS) published in 2010 identified TP53INP1 as a new T2D susceptibility locus, but a pathological mechanism was not identified. In this work, we show that mice lacking TP53INP1 are prone to redox-driven obesity and insulin resistance. Furthermore, we demonstrate that the reactive oxygen species increase in TP53INP1-deficient cells results from accumulation of defective mitochondria associated with impaired PINK/ PARKIN mitophagy. This chronic oxidative stress also favors accumulation of lipid droplets. Taken together, our data provide evidence that the GWAS-identified TP53INP1 gene prevents metabolic syndrome, through a mechanism involving prevention of oxidative stress by mitochondrial homeostasis regulation. In conclusion, this study highlights TP53INP1 as a molecular regulator of redox-driven metabolic syndrome and provides a new preclinical mouse model for metabolic syndrome clinical research