32 research outputs found

    RĂŽle du TGF-bĂ©ta dans la carcinogenĂšse hĂ©patique liĂ©e au virus de l’hĂ©patite C

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    Chronic HCV infection) may progress to liver fibrosis, cirrhosis and hepatocellular carcinoma (HCC). HCV core binds several cellular proteins and in particular Smad3, a major protein of transforming growth factor beta (TGF-Β) signalling.. The aim of this study was to determine the implication of HCV core protein in TGF-Β responses. High genetic variability is a characteristic of HCV and it was previously shown that HCV core protein isolated from tumour (cT) or adjacent non-Tumour (cNT) livers displayed different sequences. Both were able to shift TGF-B responses from tumour suppressor to tumour promotor by decreasing hepatocyte apoptosis and increasing epithelial-Mesenchymal transition (EMT). Core cT was more potent than core cNT to promote this effect that was mainly attributed to the capacity of HCV core to alleviate Smad3 activity. Moreover, HCV core protein activated the latent form of TGF-Β through increased thrombospondin expression. It is commonly accepted that αSMA (alpha smooth muscle actin) is a hallmark of EMT. In the current study another SMA isoform, ÎłSMA was found to be polymerized during hepatocyte EMT. ÎłSMA was expressed in HCC tissues and correlated with EMT, stem cell and aggressiveness markers. In conclusion, this work contributed to a better understanding of the HCV core role in hepatitis fibrosis and HCC related to HCV. Indeed, HCV core might act both as an autocrine and paracrine way by modulating TGF-Β responses within hepatocytes and by activating hepatic stellate cells in stromal environment through its capacity to activate TGF-Β.L’infection chronique par le virus de l’hĂ©patite C (VHC) conduit au dĂ©veloppement de la fibrose et de la cirrhose qui risque d’évoluer vers le carcinome hĂ©patocellulaire (CHC). La protĂ©ine de capside du VHC interagit avec de nombreuses protĂ©ines de l’hĂŽte et en particulier avec Smad3, protĂ©ine majeure de la voie de signalisation du transforming growth factor beta (TGF-Β). Mon travail de thĂšse consistait Ă  Ă©tudier les consĂ©quences biologiques de l’interaction entre la protĂ©ine de capside avec la voie de signalisation du TGF-Β. Le VHC prĂ©sente une grande variabilitĂ© gĂ©nĂ©tique et des travaux du laboratoire ont montrĂ© l’existence de sĂ©quences diffĂ©rentes de protĂ©ines de capside du virus entre les rĂ©gions tumorales (cT) et cirrhotiques (cNT) d’un mĂȘme sujet. Nous avons montrĂ© que ces diffĂ©rentes protĂ©ines de capside exprimĂ©es dans des hĂ©patocytes orientent les rĂ©ponses biologiques du TGF-Β vers la promotion tumorale en diminuant l’apoptose et en augmentant la transition Ă©pithelio-MĂ©senchymateuse (TEM) en particulier le variant cT. Cet effet est attribuĂ© Ă  la capacitĂ© de la protĂ©ine de capside de diminuer l’activitĂ© transcriptionnelle de Smad3. De plus, les variants de la protĂ©ine de capside activent le TGF-Β latent via l’augmentation de l’expression de la trombospondine. L’un des marqueurs classiquement exprimĂ© au cours d’une TEM est l’alpha-Actine musculaire lisse (αSMA). Nous avons montrĂ© qu’une autre isoforme, la ÎłSMA, Ă©tait polymĂ©risĂ©e dans les cellules hĂ©patiques dĂ©veloppant une TEM. L’expression de ÎłSMA a Ă©tĂ© retrouvĂ©e sur des coupes de CHC et a pu ĂȘtre significativement corrĂ©lĂ©e Ă  la fois avec des marqueurs de la TEM, des marqueurs progĂ©niteurs et avec l’agressivitĂ© de la tumeur.Ce travail apporte une meilleure comprĂ©hension du rĂŽle de la protĂ©ine de capside dans la fibrose hĂ©patique liĂ©e Ă  l’infection virale. En effet, la protĂ©ine de capside du VHC agit Ă  la fois de façon autocrine dans les hĂ©patocytes en modulant les rĂ©ponses du TGF-Β vers la promotion tumorale et de façon paracrine, en affectant l’activation des cellules Ă©toilĂ©es en myofibroblastes par le TGF-Β activĂ©

    Liver Cancer-Derived Hepatitis C Virus Core Proteins Shift TGF-Beta Responses from Tumor Suppression to Epithelial-Mesenchymal Transition

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    International audienceBACKGROUND: Chronic hepatitis C virus (HCV) infection and associated liver cirrhosis represent a major risk factor for hepatocellular carcinoma (HCC) development. TGF-beta is an important driver of liver fibrogenesis and cancer; however, its actual impact in human cancer progression is still poorly known. The aim of this study was to investigate the role of HCC-derived HCV core natural variants on cancer progression through their impact on TGF-beta signaling. PRINCIPAL FINDINGS: We provide evidence that HCC-derived core protein expression in primary human or mouse hepatocyte alleviates TGF-beta responses in terms or growth inhibition or apoptosis. Instead, in these hepatocytes TGF-beta was still able to induce an epithelial to mesenchymal transition (EMT), a process that contributes to the promotion of cell invasion and metastasis. Moreover, we demonstrate that different thresholds of Smad3 activation dictate the TGF-beta responses in hepatic cells and that HCV core protein, by decreasing Smad3 activation, may switch TGF-beta growth inhibitory effects to tumor promoting responses. CONCLUSION/SIGNIFICANCE: Our data illustrate the capacity of hepatocytes to develop EMT and plasticity under TGF-beta, emphasize the role of HCV core protein in the dynamic of these effects and provide evidence for a paradigm whereby a viral protein implicated in oncogenesis is capable to shift TGF-beta responses from cytostatic effects to EMT development

    RĂŽle of TGF-Beta in Liver Cancer Related Hepatitis C Virus

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    L’infection chronique par le virus de l’hĂ©patite C (VHC) conduit au dĂ©veloppement de la fibrose et de la cirrhose qui risque d’évoluer vers le carcinome hĂ©patocellulaire (CHC). La protĂ©ine de capside du VHC interagit avec de nombreuses protĂ©ines de l’hĂŽte et en particulier avec Smad3, protĂ©ine majeure de la voie de signalisation du transforming growth factor beta (TGF-Β). Mon travail de thĂšse consistait Ă  Ă©tudier les consĂ©quences biologiques de l’interaction entre la protĂ©ine de capside avec la voie de signalisation du TGF-Β. Le VHC prĂ©sente une grande variabilitĂ© gĂ©nĂ©tique et des travaux du laboratoire ont montrĂ© l’existence de sĂ©quences diffĂ©rentes de protĂ©ines de capside du virus entre les rĂ©gions tumorales (cT) et cirrhotiques (cNT) d’un mĂȘme sujet. Nous avons montrĂ© que ces diffĂ©rentes protĂ©ines de capside exprimĂ©es dans des hĂ©patocytes orientent les rĂ©ponses biologiques du TGF-Β vers la promotion tumorale en diminuant l’apoptose et en augmentant la transition Ă©pithelio-MĂ©senchymateuse (TEM) en particulier le variant cT. Cet effet est attribuĂ© Ă  la capacitĂ© de la protĂ©ine de capside de diminuer l’activitĂ© transcriptionnelle de Smad3. De plus, les variants de la protĂ©ine de capside activent le TGF-Β latent via l’augmentation de l’expression de la trombospondine. L’un des marqueurs classiquement exprimĂ© au cours d’une TEM est l’alpha-Actine musculaire lisse (αSMA). Nous avons montrĂ© qu’une autre isoforme, la ÎłSMA, Ă©tait polymĂ©risĂ©e dans les cellules hĂ©patiques dĂ©veloppant une TEM. L’expression de ÎłSMA a Ă©tĂ© retrouvĂ©e sur des coupes de CHC et a pu ĂȘtre significativement corrĂ©lĂ©e Ă  la fois avec des marqueurs de la TEM, des marqueurs progĂ©niteurs et avec l’agressivitĂ© de la tumeur.Ce travail apporte une meilleure comprĂ©hension du rĂŽle de la protĂ©ine de capside dans la fibrose hĂ©patique liĂ©e Ă  l’infection virale. En effet, la protĂ©ine de capside du VHC agit Ă  la fois de façon autocrine dans les hĂ©patocytes en modulant les rĂ©ponses du TGF-Β vers la promotion tumorale et de façon paracrine, en affectant l’activation des cellules Ă©toilĂ©es en myofibroblastes par le TGF-Β activĂ©.Chronic HCV infection) may progress to liver fibrosis, cirrhosis and hepatocellular carcinoma (HCC). HCV core binds several cellular proteins and in particular Smad3, a major protein of transforming growth factor beta (TGF-Β) signalling.. The aim of this study was to determine the implication of HCV core protein in TGF-Β responses. High genetic variability is a characteristic of HCV and it was previously shown that HCV core protein isolated from tumour (cT) or adjacent non-Tumour (cNT) livers displayed different sequences. Both were able to shift TGF-B responses from tumour suppressor to tumour promotor by decreasing hepatocyte apoptosis and increasing epithelial-Mesenchymal transition (EMT). Core cT was more potent than core cNT to promote this effect that was mainly attributed to the capacity of HCV core to alleviate Smad3 activity. Moreover, HCV core protein activated the latent form of TGF-Β through increased thrombospondin expression. It is commonly accepted that αSMA (alpha smooth muscle actin) is a hallmark of EMT. In the current study another SMA isoform, ÎłSMA was found to be polymerized during hepatocyte EMT. ÎłSMA was expressed in HCC tissues and correlated with EMT, stem cell and aggressiveness markers. In conclusion, this work contributed to a better understanding of the HCV core role in hepatitis fibrosis and HCC related to HCV. Indeed, HCV core might act both as an autocrine and paracrine way by modulating TGF-Β responses within hepatocytes and by activating hepatic stellate cells in stromal environment through its capacity to activate TGF-Β

    Microencapsulated Hepatocytes Differentiated from Human Induced Pluripotent Stem Cells: Optimizing 3D Culture for Tissue Engineering Applications

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    Liver cell therapy and in vitro models require functional human hepatocytes, the sources of which are considerably limited. Human induced pluripotent stem cells (hiPSCs) represent a promising and unlimited source of differentiated human hepatocytes. However, when obtained in two-dimensional (2D) cultures these hepatocytes are not fully mature and functional. As three-dimensional culture conditions offer advantageous strategies for differentiation, we describe here a combination of three-dimensional (3D) approaches enabling the successful differentiation of functional hepatocytes from hiPSCs by the encapsulation of hiPSC-derived hepatoblasts in alginate beads of preformed aggregates. The resulting encapsulated and differentiated hepatocytes (E-iHep-Orgs) displayed a high level of albumin synthesis associated with the disappearance of α-fetoprotein (AFP) synthesis, thus demonstrating that the E-iHep-Orgs had reached a high level of maturation, similar to that of adult hepatocytes. Gene expression analysis by RT-PCR and immunofluorescence confirmed this maturation. Further functional assessments demonstrated their enzymatic activities, including lactate and ammonia detoxification, as well as biotransformation activities of Phase I and Phase II enzymes. This study provides proof of concept regarding the benefits of combining three-dimensional techniques (guided aggregation and microencapsulation) with liver differentiation protocols as a robust approach to generate mature and functional hepatocytes that offer a permanent and unlimited source of hepatocytes. Based on these encouraging results, our combined conditions to produce mature hepatocytes from hiPSCs could be extended to liver tissue engineering and bioartificial liver (BAL) applications at the human scale for which large biomasses are mandatory

    GDF15 secreted by senescent endothelial cells improves vascular progenitor cell functions

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    International audienceEndothelial dysfunction (ED) is part of the first steps in the development of cardiovascular diseases (CVD). Growth Differentiation Factor 15 (GDF15) is a cytokine belonging to the Transforming Growth Factor ÎČ superfamily and its expression is increased both during ED and in CVD. Because high blood levels of GDF15 have been reported during ED, we hypothesized that GDF15 could be produced by endothelial cells in response to a vascular stress, possibly to attenuate endothelial function loss. Since senescence is mainly involved in both vascular stress and endothelial function loss, we used Endothelial Colony Forming Cells generated from adult blood (AB-ECFCs) as a model of endothelial cells to investigate GDF15 expression during cellular senescence. Then, we analyzed the potential role of GDF15 in AB-ECFC functions and senescence. When AB-ECFCs become senescent, they secrete increased levels of GDF15. We investigated GDF15 paracrine effects on non-senescent AB-ECFCs and showed that GDF15 enhanced proliferation, migration, NO production and activated several signaling pathways including AKT, ERK1/2 and SMAD2 without triggering any oxidative stress. Taken together, our results suggest that GDF15 production by senescent AB-ECFCs could act in a paracrine manner on non-senescent AB-ECFCs, and that this interaction could be beneficial to its model cells. Therefore, GDF15 could play a beneficial role in a dysfunctional vascular system as previously reported in patients with CVD, by limiting ED related to vascular stress occurring in these diseases

    On‐Chip Differentiation of Hepatic Cords with Radial Flow

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    International audienceDue to a more physiological reproduction of the in vivo situation, liver‐on‐a‐chip devices in recent studies have shown higher sensitivity and accuracy for hepatotoxicity testing compared to traditional in vitro liver models. In this context, this work presents an original microfluidic device mimicking 3D hepatic cords organized radially, like in the liver lobule. Ten cell‐culture chambers seeded at a high density are disposed with a parallelized flow that emulates blood flow from the portal triad to the central vein in the liver lobule. Using this device, on‐chip differentiation of human HepaRG‐Hepatoblast (HepaRG‐HB) to HepaRG‐Hepatocytes (HepaRG‐HC) has been studied in terms of self‐organization capabilities, bile canaliculi formation and albumin expression. Our results indicate that due to the design of the cell culture chamber, which mechanically constrains tissue proliferation, and the physiologically relevant microfluidic flow condition used during tissue development, the HepaRG‐HBs in the device can proliferate, self‐organize, and spontaneously differentiate in a DMSO free medium forming long, directional bile canaliculi. On the contrary, under the same conditions, differentiated HepaRG‐HC is observed to aggregate without long bile canaliculi and form tissues resembling traditional HepaRG‐HC cultures. © 2024 Institute of Electrical Engineers of Japan. Published by Wiley Periodicals LLC

    On‐Chip Differentiation of Hepatic Cords with Radial Flow

    No full text
    International audienceDue to a more physiological reproduction of the in vivo situation, liver‐on‐a‐chip devices in recent studies have shown higher sensitivity and accuracy for hepatotoxicity testing compared to traditional in vitro liver models. In this context, this work presents an original microfluidic device mimicking 3D hepatic cords organized radially, like in the liver lobule. Ten cell‐culture chambers seeded at a high density are disposed with a parallelized flow that emulates blood flow from the portal triad to the central vein in the liver lobule. Using this device, on‐chip differentiation of human HepaRG‐Hepatoblast (HepaRG‐HB) to HepaRG‐Hepatocytes (HepaRG‐HC) has been studied in terms of self‐organization capabilities, bile canaliculi formation and albumin expression. Our results indicate that due to the design of the cell culture chamber, which mechanically constrains tissue proliferation, and the physiologically relevant microfluidic flow condition used during tissue development, the HepaRG‐HBs in the device can proliferate, self‐organize, and spontaneously differentiate in a DMSO free medium forming long, directional bile canaliculi. On the contrary, under the same conditions, differentiated HepaRG‐HC is observed to aggregate without long bile canaliculi and form tissues resembling traditional HepaRG‐HC cultures. © 2024 Institute of Electrical Engineers of Japan. Published by Wiley Periodicals LLC
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