Rôle de la protéine DUSP5 dans l’autophagie des cardiomyocytes / Role of the protein DUSP5 during autophagy in the cadiomyocytes

Emond-Boisjoly, Marc-Alexandre

January 2016

Résumé: L’autophagie est un processus essentiel au maintien de l’homéostasie cellulaire. Elle permet de dégrader et recycler aussi bien des organelles entières que des composants cytoplasmiques non fonctionnels. De plus, l’augmentation d’autophagie en condition de stress constitue une réponse adaptative favorisant la survie cellulaire. Chez les cardiomyocytes, l’autophagie en condition basale est indispensable au renouvellement, entre autres, des mitochondries et des protéines formant les sarcomères. De plus, les stress tels l’ischémie cardiaque ou la carence en nutriments induisent une augmentation de l’autophagie protectrice. Dans certaines conditions extrêmes, il a été suggéré qu’un surcroît d’autophagie puisse toutefois exacerber la pathologie cardiaque en provoquant la mort des cardiomyocytes. Considérant l’importance de ce processus dans la physiopathologie cardiaque, l’identification des mécanismes signalétiques régulant l’autophagie chez les cardiomyocytes a été le sujet de recherches intenses. À cet effet, l’activation des Mitogen-Activated Protein Kinase (MAPK) a été démontrée pour réguler, avec d’autres voies signalétiques, l’autophagie et l’apoptose des cardiomyocytes. Il est donc probable que les Dual-Specificity Phosphatase (DUSP), enzymes clés contrôlant l’activité des MAPK, participent aussi à la régulation de l’autophagie. Afin de vérifier cette hypothèse, nous avons induit l’autophagie chez des cardiomyocytes isolés de rats nouveau-nés en culture. L’analyse de marqueurs d’autophagie par immunobuvardage démontre que l’activation des MAPK ERK1/2 et p38 corrèle avec l’activité autophagique chez les cardiomyocytes. Dans ces conditions, la diminution d’expression de la majorité des ARNm encodant les différentes DUSP retrouvées chez les cardiomyocytes contraste de façon marquée avec l’augmentation d’expression de l’ARNm Dusp5. De plus, nous avons démontré par une étude de gain de fonction que l’activation soutenue de p38 par surexpression d’un mutant MKK6 constitutivement actif stimule l’autophagie chez les cardiomyocytes. De façon surprenante, la perte de fonction de p38 obtenue par surexpression d’un mutant p38 dominant négatif n’altère en rien la réponse autophagique initiatrice dans notre modèle in vitro. Nos résultats suggèrent que les DUSP puissent réguler, via leurs actions sur les MAPK, d’importantes étapes du processus autophagique chez les cardiomyocytes. / Abstract: Autophagy is a process essential to the maintenance of cellular homeostasis. It helps degrade and recycle whole organelles and nonfunctional cytoplasmic components. In addition, the adaptative up regulation of autophagy in stress condition promotes cell survival. In cardiomyocytes basal autophagy is essential to the renewal of, among others, mitochondria and proteins forming sarcomeres. In addition, stresses such as ischemic heart or nutrient deficiency induce an increase in protective autophagy. In extreme conditions, it has been suggested that autophagy may exacerbate cardiac disease causing the death of cardiomyocytes. Considering the importance of this process in cardiac pathophysiology, identify ing safety mechanisms regulating autophagy in cardiomyocytes has been the subject of intense research. To this end, activation of mitogen-activated protein kinase (MAPK) has been demonstrated to regulate, with other signaling pathways, autophagy and cardiomyocyte apoptosis. It is therefore likely that Dual-Specificity Phosphatases (DUSPs), key enzymes that control the activity of MAPKs, also participate in the regulation of autophagy. To test this hypothesis, we have induced autophagy in isolated cardiomyocytes of newborn rats in culture. Analysis of autophagy markers by immunoblotting demonstrated that the activation of MAPKs ERK1/2 and p38 correlates with autophagic activity in cardiomyocytes. Under these conditions, the decrease in expression of the majority of mRNAs encoding different DUSPs found in cardiomyocytes contrast sharply with the increase mRNA expression of Dusp5. Furthermore, we demonstrated by again of function study that sustained activation of p38 by overexpression of a constitutively active MKK6 mutant stimulates autophagy in cardiomyocytes. Surprisingly, the loss of p38 function obtained by overexpression of a dominant negative p38 mutant does not affect the autophagic response in our in vitro model, but increases the lipidation of autophagosomes marker LC3. Our results suggest that DUSPs can regulate, through their actions on MAPKs, important stages of autophagy in cardiomyocytes.

Autophagie

ERK

DUSP

Cardiomyocyte

Autophagy

p38

Starvation

Characterizing the Impact of Helicobacter pylori Infection on the Host Exosome Pathway

Wu, Ted Chia Hao

11 December 2013

Helicobacter pylori is a gram-negative bacterium that infects half the world population and is the etiological cause of numerous gastric pathologies. H. pylori possess numerous mechanisms to promote its survival and modulate host immunity. We propose that H. pylori can modulate intercellular communication by manipulating the host exosome pathway. Exosomes are secreted nanovesicles that contain different proteins and microRNAs that can be transferred between cells to alter cell signaling and gene expression. We demonstrate that H. pylori infection increases host exosome secretion. Furthermore, infection can alter exosome composition as VacA, a bacterial virulence factor, can be exported in exosomes and Argonaute 5, a miRNA effector protein, is upregulated in exosomes during infection. Lastly, we show preliminary evidence that infection-modulated exosomes can modulate immune-regulatory signaling in dendritic cells by activating STAT3. Together, these studies elucidate a novel mechanism by which H. pylori can modulate the host environment and promote its continued survival.

Autophagy

Helicobacter pylori

Exosomes

microRNAs

0379

0410

Examining Mycobacterial Interactions with Host Cellular Pathways

Jurcic Smith, Kristen Leigh

January 2015

<p>Tuberculosis is a devastating disease that has been plaguing humankind for millennia. Co-evolution of humans with Mycobacterium tuberculosis, the causative agent of the disease, has allowed for the pathogen to possess an abundance of survival mechanisms. The outcome of this is the ability of the bacterium to create an intracellular niche lifestyle inside host cells where it can successfully evade the host immune system. While there is a vaccine available, named the BCG vaccine, it confers little protection to adults in the pulmonary form of the disease. The lack of an effective vaccine and the rise of Multidrug-Resistant (MDR) and Extensively Drug-Resistant (XDR) tuberculosis highlight the need for more research into combating Mycobacterium tuberculosis. The purpose of this work is to enhance the field of knowledge of how mycobacterial virulence factors affect host cellular pathways so that the interactions can be exploited for novel therapeutics and vaccine development.</p><p>One of the hypotheses for the poor efficacy of the BCG vaccine is that it fails to elicit a strong CD8+ T cell response during infection. Studies have found that vaccinating mice with apoptotic bodies containing mycobacterial antigens were able to protect mice to a greater degree than BCG and that this is dependent on CD8+ T cell activation. Thus, we hypothesized that a pro-apoptotic mutant of M. tuberculosis could be utilized as a novel vaccine candidate. Through screening a library of M. tuberculosis transposon mutants, we identified an Enhanced Cell Death mutant (ECD19) that functions through caspase 3 mediated apoptosis. Sequencing revealed that the mutant has a transposon insertion in Rv2456c, a probable integral membrane transport protein. Immunogenicity testing via Enzyme-Linked ImmunoSpot (ELISPOT) and Intracellular Cytokine Staining (ICS) assays demonstrated that ECD19 induced an altered immune response when compared to the parental strain M. tuberculosis H37Rv. Additionally, ECD19 has reduced survival in an in vitro THP-1 cell model and in an in vivo mouse model. Taken together, our data suggest that Rv2456c is important to the survival of H37Rv in host cells and that deletion of the gene may enhance the immunogenicity of the bacterium.</p><p>Inappropriate dosing and poor adherence to antibiotics in the treatment of tuberculosis has led to MDR and XDR, the highest incidences of which can be found in the KwaZulu-Natal (KZN) province of South Africa. Little is known about the virulence of these strains, but it is hypothesized that the drug resistance mechanisms come at a cost to the bacteria. In an in vitro assay, we have found that clinical isolates from the KZN region induce higher levels of necrosis than virulent laboratory strains of M. tuberculosis. Additionally, our in vivo studies show that the drug-resistant isolates do not disseminate as well as susceptible strains, and in both immunocompetent and immunocompromised mouse models, mice infected with the drug-resistant strains are able to live longer than mice infected with drug-sensitive strains. As all strains are highly related on a genetic level, we can say that the drug-resistant mechanisms acquired by the strains come at a cost of reduced virulence. Thus, it is likely that higher prevalence of the MDR and XDR in the KZN province is due to the high rate of HIV+, immunocompromised individuals living in the region. </p><p>Lastly, we are interested in building on the knowledge that avirulent mycobacteria are able to induce autophagy in a murine macrophage cell line. Through the use of Mammalian Target of Rapamycin (mTOR) inhibitors and autophagy-deficient macrophages, we were able to show that Mycobacterium smegmatis is able to induce both mTOR and autophagy during infection. Additionally, we found that mycobacterial killing occurs in the absence of autophagy when mTOR is inhibited. This effect is not due to a bactericidal effect of the mTOR inhibitors. From these data, we show that there is an underappreciated role in the induction of mTOR after mycobacterial infection. By studying the interplay of mTOR and autophagy, therapies targeted to favoring host defenses could be developed.</p><p>In summary, the insights from this work enhance the knowledge of how mycobacteria are able to be successful pathogens. This data may be useful in the creation of novel vaccine candidates or the identification of potential drug targets to bolster the therapeutic options in treating those afflicted with tuberculosis.</p> / Dissertation

Microbiology

Immunology

Apoptosis

Autophagy

Tuberculosis

Vaccine

Relationship between Autophagy, Senescence, and DNA Damage in Radiation Sensitization by PARP Inhibition

Alotaibi, Moureq

01 January 2015

Radiotherapy continues to be a primary modality in the treatment of cancer. DNA damage induced by radiation can promote apoptosis as well as both autophagy and senescence, where autophagy and senescence can theoretically function to prolong tumor survival. A primary aim of this work was to investigate the hypothesis that autophagy and/or senescence could be permissive for DNA repair, thereby facilitating tumor cell recovery from radiation-induced growth arrest and/or cell death. In addition, studies were designed to elucidate the involvement of autophagy and senescence in radiation sensitization by PARP inhibitors and the re-emergence of a proliferating tumor cell population. In the context of this work, the relationship between radiation-induced autophagy and senescence was also determined. Studies were performed using DNA repair proficient HCT116 colon carcinoma cells and a repair deficient Ligase IV (-/-) isogenic cell line. Irradiation promoted a parallel induction of autophagy and senescence that was strongly correlated with the extent of persistent H2AX phosphorylation in both cell lines; however inhibition of autophagy failed to suppress senescence, indicating that the two responses were dissociable. Irradiation resulted in a transient arrest in the HCT116 cells while arrest was prolonged in the Ligase IV (-/-) cells; however, both cell lines ultimately recovered proliferative function, which may reflect maintenance of DNA repair capacity. The PARP inhibitors (Olaparib) and (Niraparib) increased the extent of persistent DNA damage induced by radiation as well as the extent of both autophagy and senescence; neither cell line underwent significant apoptosis by radiation alone or in the presence of the PARP inhibitors. Inhibition of autophagy failed to attenuate radiation sensitization, indicating that autophagy was not involved in the action of the PARP inhibitors. As with radiation alone, despite sensitization by PARP inhibition, proliferative recovery was evident within a period of 10-20 days. While inhibition of DNA repair via PARP inhibition may initially sensitize tumor cells to radiation via the promotion of senescence, this strategy does not appear to interfere with proliferative recovery, which could ultimately contribute to disease recurrence.

Autophagy

Senescence

DNA repair

PARP inhibition

Pharmacology

AMPK Promotes Xenophagy Through ‘Priming’ of Autophagic Kinases upon Detection of Salmonella Outer Membrane Vesicles

To, Truc

28 January 2019

The autophagy pathway is an essential component of the innate immune response, capable of rapidly targeting intracellular bacteria, which are subsequently degraded by lysosomal enzymes. Recent work has begun to elucidate the regulatory signalling for autophagy induction in response to pathogenic bacteria. However, the initial signalling regulating autophagy induction in response to the detection of pathogens remains largely unclear. Here we report that AMPK, an important upstream activator of the autophagy pathway, is rapidly stimulated upon detection of pathogenic bacteria, prior to bacterial invasion. Bacterial recognition is initially achieved through detection of outer membrane vesicles (OMVs). Additionally, we show that AMPK signalling relieves mTORC1-mediated repression of the autophagy pathway in response to Salmonella infection, positioning the cell for a rapid induction of autophagy. Surprisingly, we found that the activation of AMPK and inhibition of mTORC1 in response to extracellular Salmonella are not accompanied by an induction of bulk autophagy. However, upon Salmonella invasion AMPK signalling is required for efficient and selective targeting of bacteria-containing vesicles by the autophagy pathway through activation of pro-autophagic kinase complexes. Collectively, these results demonstrate a key role for AMPK signalling in coordinating the rapid autophagic response prior to invasion of pathogenic bacteria.

Autophagy

Cellular signalling

Xenophagy

Infection

Salmonella

Characterising futile autophagosome based toxicity and its implications in disease

Button, Robert William

January 2017

Macroautophagy (‘autophagy’ hereafter) mediates the capture of aberrant cytoplasmic material into vesicles called autophagosomes, which then shuttle to lysosomes for degradation. Autophagy is implicated in numerous diseases, largely in a pro-survival role. However, autophagy has also been suggested as a form of programmed cell death (PCD), from cases of dying cells showing autophagosome accumulations. Debate occurs between whether these vesicles drive the lethality, or are instead a failing rescue attempt. This study aimed to provide clarity on this issue. Via the use of chemical and genetic strategies of inducing autophagosome accumulations, we found combining stimulators of autophagosome biogenesis with lysosomal degradation inhibitors gave rise to toxicity. Notably, this effect was dependent on the autophagy machinery and independent of other PCD routes. Research into the underlying mechanisms revealed an energy deficit under these conditions. Since autophagosomes cannot be recycled at lysosomes here, their continued synthesis affords no survival benefits, and instead just serves to deplete cellular energy further. For this reason, we designate this event ‘Futile Autophagosome Synthesis’ (FAS) toxicity. Other contributors to this toxicity include the persistence of harmful agents like Reactive Oxygen Species (ROS). Having established our FAS model, we explored its relevance in both cancer and neurodegeneration. Importantly, we found FAS inducing strategies to be effective in tumour treatment. Also, inhibiting FAS reduced the toxicity seen in neurodegenerative disease. Therefore, not only does this study improve our knowledge of autophagy in PCD, but also indicates it may have important medical implications.

Pathogenesis of light chain-induced dysfunction in cardiac amyloidosis

Snyder, Christina AnnaMarie

22 January 2016

Although a rare disease, light chain (LC) amyloidosis (AL) is the most common systemic amyloidosis in developed countries. It is caused by an overproduction of immunoglobulin LC proteins in bone marrow plasma cells. In AL amyloidosis, LCs that are prone to misfolding and insolubility will aggregate, form fibrils, and deposit themselves in various tissues, thereby causing organ dysfunction. The most fatal manifestation of AL amyloidosis is associated with cardiac involvement, defined by the presence of extracellular AL amyloid deposits within the heart. Cardiac amyloid infiltration typically leads to diastolic dysfunction followed by heart failure and has a median survival of approximately 6 months from the time of diagnosis if untreated. Clinical observation suggests that a reduction in circulating LCs results in an improvement in heart failure symptoms despite minimal changes in amyloid deposition. This has led to the concept that LCs themselves are cytotoxic to cardiomyocytes. Recent studies indicate that AL LCs induce oxidative stress, cellular dysfunction, and apoptosis (programmed cell death) in cardiomyocytes via a p38α mitogen-activated protein kinase (MAPK) mechanism. They may therefore be a target for amyloidosis therapy. By understanding how LCs cause cardiac dysfunction, we can target this process with therapies and utilize downstream measures of LC activity as diagnostic and prognostic tools. The objective of this study was to determine the role of autophagy in AL amyloidosis. Autophagy is the intracellular process of degrading aging or dysfunctional cellular components. Autophagy can be beneficial by preventing proteotoxicity and providing nutrients, amino acids, and other necessities during times of cellular stress. On the other hand, increased autophagy, like apoptosis, may mediate cellular death depending on the type of stimulus and its duration. Autophagy is induced by a variety of stimuli, including oxidative stress. AL has been demonstrated to increase reactive oxygen species (ROS), and it is unknown if autophagy mediates cardiomyocyte dysfunction in AL cardiac amyloidosis. We thus sought to determine if it is a factor in amyloid cardiotoxicity. We explored the ERK1/2, p38, and JNK MAPK pathways in particular, since MAPK signaling cascades regulate several transcription factors involved in the cell cycle and p38α has been implicated in ROS-induced cardiac AL amyloidosis. Adult rat ventricular myocytes (ARVM) were harvested from healthy adult male rats and exposed to a variety of experimental conditions in vitro. ARVM were treated with vehicle control, human LC obtained from a patient without cardiac involvement, a positive control (aldosterone), and human AL light chains obtained from a patient with AL cardiac amyloidosis in the presence or absence of UO126, SB203580, or SP600125 (specific inhibitors of ERK1/2, p38, and JNK, respectively). The resulting protein expression levels of autophagy indicators LC3II and ATG4B in cardiomyocytes were analyzed by Western blotting. The ratio of phosphorylated to total ERK1/2 protein expression was also explored. We found that AL light chains did not contribute to autophagy via the ERK1/2, p38, or JNK pathways. In contrast to our previous unpublished findings, the protein levels of autophagy indicators in AL-treated ARVM did not differ from vehicle control levels, suggesting that AL did not activate autophagy. However non-cardiomyopathic light chains (LC) did increase LC3II expression in ARVM, despite their human source exhibiting no clinical indications of cardiac involvement. This implies that autophagy induced by non-cardiomyopathic LCs may be beneficial and protect against the development of the cardiotoxicity seen in AL cardiac amyloidosis. Further studies are necessary to understand the effect of autophagy in the heart and its role in cardiac amyloidosis. Continuing to explore the underlying mechanisms of AL light chain toxicity will contribute to the development of diagnostic, prognostic, and treatment strategies for AL amyloidosis.

Medicine

Amyloidosis

Autophagy

Cardiology

Light chain

Sphingomyelin as a danger signal in cell-autonomous immunity

Ellison, Cara Jane

January 2017

Individual cells employ mechanisms of cell-autonomous immunity to defend their cytosol against bacterial invasion. One such mechanism involves indirect detection of the pathogen through recognition of pathogen-induced disturbances causing the appearance of specific host molecules in an abnormal location. For example, glycans, which are located on the extracellular leaflet of the plasma membrane under homeostatic conditions, become hidden inside bacteria-containing vacuoles (BCVs) during bacterial entry into the cell. Upon BCV rupture, glycans become exposed to the cytosol where they act as a danger signal and are detected by the cytosolic danger receptor, Galectin 8. My research reveals that sphingomyelin, a host lipid predominantly located on the outer leaflet of the plasma membrane, is exposed to the cytosol on damaged BCVs. I visualised the appearance of intracellular sphingomyelin by utilising Lysenin - a sphingomyelin-specific toxin from earthworms – as a cytosolic sphingomyelin reporter. Lysenin is recruited to BCVs in a sphingomyelin-dependent manner upon cytosolic entry of both Gram-negative and Gram-positive bacteria. Lysenin co-localises with Galectin 8 on a proportion of BCVs, indicating that sphingomyelin exposure occurs upon membrane damage. Moreover, I elucidated that sphingomyelin exposure occurs before glycan exposure on damaged BCVs indicating that BCV rupture may proceed through two stages: ‘minor’ and ‘major’ damage. My investigations into possible causes of vacuole rupture are on going. To identify endogenous cellular receptors for cytosol-exposed sphingomyelin, I established and executed an assay to compare enrichment of mammalian cell lysate proteins on liposomes containing or lacking sphingomyelin. Following mass spectrometry analysis, 49 candidate proteins were tested for recruitment to Salmonella. Twelve candidates were recruited to BCVs upon infection. Of these twelve, I pursued five candidates in greater detail due to their recruitment to Salmonella being either entirely unknown, or known, but via a non-sphingomyelin mechanism. Further analysis of one candidate in particular, TECPR1, elucidated that TECPR1 is recruited to Salmonella in a sphingomyelin-dependent manner and possesses sphingomyelin-specific binding properties in vitro. Therefore, my thesis research identifies TECPR1 as an endogenous sphingomyelin-binding protein.

616.9

Identification of regulators in autophagosome formation using image-based siRNA screening

Yu, Qijia

January 2017

Autophagy, referring to macroautophagy, is an evolutionarily conserved degradation pathway. Through autophagy cells can degrade damaged organelles, lipid vesicles and misfolded protein aggregates with implications in various pathological conditions, including neurodegenerative diseases, cancers, and infectious diseases. Autophagy is one of the major intracellular membrane-trafficking processes and its morphology includes the initiation, maturation, transportation and degradation of autophagosomes, where the double-membrane autophagosomes package the cargo for degradation. Therefore, understanding how autophagosomes form and are regulated is important in this field. Here we conducted a genome-wide siRNA screen using a high-throughput imaging system to identify undiscovered regulators in autophagosome formation. In this study, HEK293 cells stably expressing GFP-DFCP1 (GFP-tagged zinc finger FYVE-type containing 1) were used and amino acid starvation was used to induce autophagy. After the first round of primary screening, a small-scale screen was conducted with the same conditions including 384 candidates and additionally with these candidates HEK293 cells stably expressing GFPLC3 (GFP-tagged microtubule associated protein 1 light chain 3) were used to monitor the late steps of the autophagy process. From these rounds of screening, 39 candidates were selected and validated by investigating early autophagosome markers for their effects on autophagosome formation. Finally, five of the best candidates were confirmed based on their depletion effects on autophagy. Among these five candidates, DCAKD (dephospho-CoA kinase domain containing), WDR91 (WD repeat domain 91) and WDR65 were further investigated. Preliminary data using both RNAi and CRISPR Cas9 showed that DCAKD affected the accumulation of some early autophagy markers on initiation membranes in autophagosome formation. Interestingly, protein levels of canonical autophagy markers remained unchanged in DCAKD-deficient cells. Another candidate WDR91 showed the ability to mediate endosomal and lysosomal PtdIns3P and mildly affect autophagy initiation. WDR65 also inhibited early autophagy events. However, the detailed mechanism for these proteins are yet to be determined. In summary, our work provided more understanding on the egulation of autophagosome formation, as well as a list of potentially novel regulators.

571.6

Les mécanismes de réponse à l'inflammation chronique dans le foie stéatosique et les conséquences sur l'homéostasie cellulaire et la cancérogénèse / Response mechanisms to chronic inflammation in steatotic liver and consequences on cellular homeostasy and carcinogenesis

Degli Esposti, Davide

15 June 2011

Le foie est un organe essentiel à la vie chez tous les mammifères. C’est un organe central du métabolisme énergétique et de la détoxification des substances xénobiotiques auxquelles l’individu est exposé. Le foie est la cible d’agressions diverses, telles que les virus, l’alcool, les substances chimiques présentes dans l’alimentation ou l’environnement. Il peut également subir destransformations pathologiques profondes, lors du diabète ou de l’obésité par exemple.La stéatose hépatique, caractérisée par une accumulation de triglycérides sous forme de vésiculesgénérant une réponse inflammatoire, est connue depuis de nombreuses années. Son étude a permisde définir un modèle en deux étapes (« two hits ») indispensables à la genèse d’une stéatohépatite ou NASH. La première est l’accumulation de lipides, la seconde consiste en la genèse d’un stress oxydant et la libération de cytokines. La NASH est une des conséquences pathologiques du syndrome métabolique au cours duquel une résistance des tissus à l’insuline se développe.Récemment, la composition des lipides accumulés dans la NASH a été décrite et montre la présence de cholestérol libre et de différents métabolites des acides gras dont la toxicité est grande mais variable. De façon surprenante, une nouvelle hypothèse tend à émerger quant aux rôles protecteurs de certaines catégories de lipides. En effet, le stockage des triglycérides sous forme de vésicules pourrait être un mécanisme de survie cellulaire (Neuschwander-Tetri, 2010). Il s’agirait principalement d’une tolérance à la mort cellulaire par nécrose ou apoptose. Dans ce contexte,l’activation de l’autophagie serait capitale et la nécrose ne serait plus un mécanisme non contrôlé,mais au contraire un système finement régulé.Des données expérimentales récentes suggèrent l’existence d’un réseau complexe d’interactions moléculaires qui lient, dans la NASH comme dans le cas de la cancérogenèse, le métabolisme énergétique, la réponse inflammatoire systémique et tissulaire et des altérations subcellulaires, telles que les lésions des mitochondries et du réticulum endoplasmique.Nous avons utilisé le cas particulier du préconditionnement ischémique, une technique chirurgicale qui consiste, grâce à de courtes périodes d’occlusion vasculaire avant l’ischémie, à conférer au tissu une protection contre les lésions d’ischémie/reperfusion (I/R), pour étudier les mécanismes de survie mis en place par les hépatocytes stéatosiques au cours d’un stress d’I/R. Dans deux contextes différents, celui d’une ischémie chaude au cours d’une hépatectomie partielle et celui d’une ischémie froide au cours de la transplantation hépatique, nous avons montré que l’autophagie peut jouer un rôle central dans la protection des hépatocytes stéatosiques. Cependant, il est envisageable qu’un dysfonctionnement de l’autophagie pourrait conduire à la genèse d’altérations cellulaires comme une instabilité génomique, caractéristique de la transformation cancéreuse. L’équilibre entre la survie et la mort cellulaire dépend donc de l’intégration de cette signalisation complexe, qui concerne l’état énergétique de la cellule, la réponse aux stress transitoires et l’adaptation aux stress chroniques. Dans ce contexte, l’autophagie semble jouer un rôle central dans l’intégration de la réponse aux stress (Kroemer et al 2010), ce qui pourrait favoriser directement ou indirectement la transformation cancéreuse d’une cellule.L’amélioration de la compréhension des mécanismes impliqués dans la tolérance et la survie des hépatocytes chargés de lipides en réponse à un stress inflammatoire, ischémique ou du réticulum endoplasmique semble donc essentielle. Elle permettrait en effet la mise en place de nouvelles stratégies thérapeutiques qui pourraient améliorer la prise en charge des patients, augmenter le nombre de greffons disponibles pour les greffes, et la prévention des risques cancérogènes pour le foie. / Liver is a an essential to life organ in all mammals. It plays a central role in energy and drug metabolism. Liver is constantly challenged by damaging compounds such as viruses, alcohol and chemicals from food intake or from the environment. It can also undergo some deep pathological transformations, e.g. in diabetes or obesity. Liver steatosis has been known for many years, it is defined as an accumulation of triglycerides vesicles generating an inflammatory response in hepatocytes. A « two step hypothesis » has been proposed for the genesis of Non Alcoholic Steatohepatitis (NASH). The first step is the fat accumulation, the second step involves the generation of an oxidative stress and the release ofcytokines. NASH is one of the pathological consequences of metabolic syndrome, when insulin resistance occurs in the tissues.The composition of accumulated fat in NASH has been recently described and reveals the presence of free cholesterol and different fatty acids metabolites with a high but variable toxicity. Surprisingly, a new hypothesis tends to emerge about the protective effects of some types of lipides.Triglyceride storage in vesicles could indeed be a survival mechanism for cells (Neuschwander-Tetri, 2010). It is assumed that it would mainly result in an tolerance to cell death by necrosis orapoptosis. In this context, (activation of) autophagy would play a key-role and necrosis, usually an uncontrolled mechanism, would become accurately regulated. Similarly to oncogenesis, recent experimental data in NASH suggest that energy metabolism,systemic and tissular inflammatory response and subcellular alterations such as impaired mitochondria and ER are connected in a complex network of molecular interactions. Ischemic preconditioning (IP) is a surgical technique consisting of brief periods of vascular occlusion which confer protection against subsequent ischemia/reperfusion via endogenous protective mechanisms. We investigated the survival mechanisms set up by steatotic hepatocytes during I/R, with or without IP. In the following two situations, warm ischemia during partial hepatectomy and cold ischemia during liver transplantation, we pointed out that autophagy can play a central role in steatotic hepatocytes protection. However, an autophagy dysfunction might result in the generation of cellular impairments such as genomic instabilities, typical features of oncogenic transformation. Therefore, the balance between cell survival or death depends on the integration of a complex signaling, taking into account the cellular energetic state, the cell response to transient stress and its adaptation to chronical stress. In that context, autophagy seems to play a central role in the integration of stress response (Kroemer et al Mol Cell 2010), which could promote, directly or indirectly the malignant cell transformation.Therefore, it seems essential to improve the understanding of mechanisms involved in tolerance and survival of lipid-full hepatocytes in response to an inflammatory, ischemic or ER stress. Indeed, this would help developing new therapeutical strategies to improve patients care, increase the number of available grafts for transplants, and prevent cancer risks in liver.

Autophagie

Steatosis

Autophagy

Hepatocellular carcinoma

Cancer

Liver