T1α/Podoplanin Shows Raft-Associated Distribution in Mouse Lung Alveolar Epithelial E10 Cells

Barth, Kathrin, Bläsche, Robert, Kasper, Michael

January 2010

Aims: T1α/(podoplanin) is abundantly expressed in the alveolar epithelial type I cells (ATI) of rodent and human lungs. Caveolin-1 is a classical primary structural protein of plasmalemal invaginations, so-called caveolae, which represent specialized lipid rafts, and which are particularly abundant in ATI cells. The biological functions of T1α in the alveolar epithelium are unknown. Here we report on the characteristics of raft domains in the microplicae/microvillar protrusions of ATI cells, which contain T1α. Methods: Detergent resistant membranes (DRMs) from cell lysates of the mouse epithelial ATI-like cell line E10 were prepared using different detergents followed by flotation in a sucrose gradient and tested by Western and dot blots with raft markers (caveolin-1, GM1) and nonraft markers (transferrin receptor, PDI and β-Cop). Immunocytochemistry was employed for the localization of T1α in E10 cells and in situ in rat lungs. Results: Our biochemical results showed that the solubility or insolubility of T1α and caveolin-1 differs in Triton X-100 and Lubrol WX, two distinct non-ionic detergents. Caveolin-1 was unsoluble in both detergents, whereas T1α was Triton X-100 soluble but Lubrol WX insoluble. Immunofluorescence double stainings revealed that both proteins were colocalized with GM1, while caveolin-1 and T1α were not colocalized in the plasma membrane. Cholesterol depletion modified the segregation of T1α in Lubrol WX DRMs. Cellular processes in ultrathin sections of cultured mouse E10 cells were immunogold positive. Immunoelectron microscopy (postembedding) of rat lung tissue revealed the preferential localization of T1α on apical microvillar protrusions of ATI cells. Conclusion: We conclude that T1α and caveolin-1 are located in distinct plasma membrane microdomains, which differ in their protein-lipid interactions. The raft-associated distribution of T1α may have an impact on a specific, not yet clarified function of this protein in the alveolar epithelium. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.

info:eu-repo/classification/ddc/540

ddc:540

info:eu-repo/classification/ddc/610

ddc:610

Reconstituting APP and BACE in proteoliposomes to characterize lipid requirements for β-secretase activity

Kalvodova, Lucie

11 September 2006

Proteolytic processing of the amyloid precursor protein (APP) may lead to the formation of the Abeta peptide, the major constituent of amyloid plaques in Alzheimer`s disease. The full-length APP is a substrate for at least 2 different (alpha and beta) proteases ("secretases"). The beta-secretase, BACE, cleaves APP in the first step of processing leading to the formation of the neurotoxic Abeta. BACE competes for APP with alpha-secretase, which cleaves APP within its Abeta sequence, thus precluding Abeta formation. It is thus important to understand how is the access of the alpha- and beta-secretase to APP regulated and how are the individual activities of these secretases modulated. Both these regulatory mechanisms, access to substrate and direct activity modulation, can be determined by the lipid composition of the membrane. Integral membrane proteins (like APP and BACE), can be viewed as solutes in a two-dimensional liquid membrane, and as such their state, and biological activity, critically depend on the physico-chemical character (fluidity, curvature, surface charge distribution, lateral domain heterogeneity etc.) of the lipid bilayer. These collective membrane properties will influence the activity of embedded membrane proteins. In addition, activity regulation may involve a direct interaction with a specific lipid (cofactor or co-structure function). Interactions of membrane proteins are furthermore affected by lateral domain organization of the membrane. Previous results had suggested that the regulation of the activity of the alpha- and beta-secretases and of their access to APP is lipid dependent, and involves lipid rafts. Using the baculovirus expression system, we have purified recombinant human full-length APP and BACE to homogeneity, and reconstituted them in large (~100nm, LUVs) and giant (10-150microm, GUVs) unilamellar vesicles. Using a soluble peptide substrate mimicking the beta-cleavage site of APP, we have examined the involvement of individual lipid species in modulating BACE activity in LUVs of various lipid compositions. We have identified 3 groups of lipids that stimulate proteolytic activity of BACE: 1.cerebrosides, 2.anionic glycerophospholipids, 3. cholesterol. Furthermore, we have co-reconstituted APP and BACE together in LUVs and demonstrated that BACE cleaves APP at the correct site, generating the beta-cleaved ectodomain identical to that from cells. We have developed an assay to quantitatively follow the beta-cleavage in proteoliposomes, and we have shown that the rate of cleavage in total brain lipid proteoliposomes is higher than in phosphatidylcholine vesicles. We have also studied partitioning of APP and BACE in GUVs between liquid ordered (lo) and liquid disordered (ld) phases. In this system, significant part of the BACE pool (about 20%) partitions into the lo phase, and its partitioning into lo phase can be further enhanced by cross-linking of membrane components. Only negligible fraction of APP can be found in the lo phase. We continue to study the behavior of co-reconstituted APP and BACE in GUVs The work presented in this thesis has yielded some interesting results and raised further questions. One of the important assignments of this project will in the next stage be the characterization of the impact of membrane domain organization on the beta-cleavage. Different domain arrangements that can be hypothesized in cell membranes can be modeled by varying the degree of phase fragmentation in proteoliposomes comprising reconstituted APP and BACE.

info:eu-repo/classification/ddc/570

ddc:570

Stereoselektive Synthese von lipophilen Inositolen und Ceramiden

Munick, Michael

22 January 2007

Die Arbeit umfasst die Synthese von lipophilen Inositolen und Glycerollipiden, welche auf ihre Raftophilie getestet wurden. Des weiteren wurden eine Reihe neuer Ceramide synthetisiert und diese in Bioassays auf ihre Wirksamkeit gegenüber diversen Krankheiten wie Influenza getestet.

info:eu-repo/classification/ddc/540

ddc:540

Identifikace nového mechanismu regulace Lck zprostředkovanou její C-terminální sekvencí / Identification of a new mechanism of Lck regulation via its C-terminal sequence

Valečka, Jan

January 2014

T-cell activation is a complex process crucial for a proper function of immune system. It has been extensively studied and its main features are well understood. However, some of the events involved in T-cell signalling are still unclear. After T-cell receptor stimulation, Src-family kinase Lck drives the initiation of signalling by tyrosine phosphorylation. Phosphorylation of several downstream targets is dependent on the redistribution of Lck to the different compartment of the plasma membrane, called lipid rafts. In lipid rafts, active Lck is juxtaposed and activates raft-resident substrates which then trigger downstream signalling. The critical in this process is the mechanism of Lck translocation to lipid rafts which has not been studied so far and represents the topic of great academic and clinical interests. Previously, we identified the adaptor protein RACK1 as a candidate protein mediating the redistribution of Lck to lipid rafts by linking it to the microtubular network. In this thesis, we analysed the structural features and functional role of RACK1 in its interaction with Lck. We show here, using the SYF cell lines expressing the wild type and various mutated forms of Lck, that intact SH3 or SH2 domains of Lck are required for an effective RACK1-Lck complex formation. We also documented...

Protein complexes in neurodegenerative diseases

Houston, Nicola Patricia

January 2012

The 14-3-3 family of proteins are important signalling proteins involved in a number of cellular processes. These include cell cycle regulation, apoptosis, signal transduction and cell signalling. There is also considerable evidence in the literature that 14-3-3 proteins play a vital role in the pathology of neurodegenerative diseases, including Alzheimer’s, Parkinson’s, Huntington’s and Prion disease. The neurodegenerative disease of focus in this research is Spinocerebellar Ataxia Type 1 (SCA1). SCA1 is a polyglutamine-repeat disease and the interaction of the disease protein ataxin-1 with 14-3-3 proteins leads to the toxic accumulation and subsequent protein aggregation which is characteristic of this disease. This study focused on attempting to elucidate the structure of various domains of the disease protein and also in identifying potential inhibitors of this deleterious interaction. Unfortunately, structural studies were not successful due to a number of caveats encountered in the expression and purification of the ataxin-1 protein domains. By utilising computational methods and small molecule inhibitors, a number of potential lead compounds which possess the ability to at least partly disrupt the interaction of 14- 3-3ζ have been identified. As 14-3-3 proteins play roles in other neurodegenerative diseases, successful identification of potential drug lead treatments can have far reaching benefits in a number of neurodegenerative diseases including SCA1. Lipid rafts are also involved in neurodegenerative disease pathology. Lipid rafts are cholesterol and sphingolipid rich domains which organise the plasma membrane into discrete microdomains and act as signalling platforms and processing centres which attach specific proteins and lipids. A number of disease proteins are processed at these membrane regions, including those involved in Alzheimer’s, Parkinson’s and Prion disease. This processing is a step which is critical in the pathology of disease and abnormal processing leads to the formation of toxic protein aggregates. Previous research in the lab identified the association of low levels of the five main brain isoforms of 14-3-3 proteins with rafts. This study expanded on this to positively identify the presence of the two phospho-forms of 14-3-3, α and δ. The mechanism by which 14-3-3 proteins associate with rafts was also investigated, indicating that 14-3-3 associates with rafts via an unidentified raftbound protein(s). In addition, the phosphorylation status and quaternary structure of 14-3-3 in the presence of sphingolipids has been explored.

572

Charakterizace buněčného prionového proteinu krevních destiček / The characterization of blood platelet cellular prion protein

Broučková, Adéla

January 2011

The conformational conversion of the cellular prion protein (PrPc) to the misfolded isoform (PrPsc) is the central pathogenic event in the transmissible neurodegenerative prion diseases. The recently shown transmissibility of variant Creutzfeldt-Jakob disease by blood transfusion emphasizes the need for better understanding of the PrPc in blood. In the current thesis, we focused on blood platelet PrPc, which has not been very well described so far. In the first part of the thesis, platelet PrPc was characterized as glycosylphosphatidylinositol- anchored glycoprotein with dominant diglycosylated form. Platelet PrPc was shown to be sensitive to cleavage with proteinase K, which is a feature discriminating between cellular and pathological prion protein. We have confirmed that platelet PrPc binds copper ions by its N- terminal octapeptide repeat region. Regarding quantity of PrPc molecules expressed on blood elements we have proved that both platelets and red blood cells express considerable amount of PrPc and thus can not be neglected in the problematic of prions transmission by blood transfusion. The detailed study regarding PrPc localization in blood platelets is presented in the second part of the thesis. PrPc was shown to be expressed in -granules as well as on the cytoplasmic membrane of...

Rôle de ADAM12 dans la Transition Epithélio-Mésenchymateuse / Role of ADAM12 in Epithelial to Mesenchymal Transition

Ruff, Michaël

27 October 2015

Les échanges entre les cellules tumorales et le microenvironnement jouent un rôle essentiel dans le développement des tumeurs. Dans ce contexte, la nouvelle famille de métalloprotéases, les protéines ADAM, constituent aujourd’hui des régulateurs majeurs de la progression tumorale en agissant sur la biodisponibilité des médiateurs de la communication cellulaire que sont les cytokines, chimiokines et facteurs de croissance. Au sein de cette famille, ADAM12 est la plus associée au cancer. Elle possède la particularité de jouer un rôle dans la signalisation cellulaire, de façon indépendante de son activité métalloprotéase, notamment dans les voies de signalisation du TGFβ. Notre étude montre pour la première fois un rôle pour la forme membranaire d'ADAM12 dans l'induction de la transition épithélio-mésenchymateuse (EMT), un processus essentiel à l'invasion tumorale dont le TGFβ est un inducteur majeur. Cet effet est médié par l'activation des voies de signalisation du TGFβ, impliquant les protéines SMAD3, AKT et ERK et requiert le domaine cytoplasmique d'ADAM12L mais pas son domaine catalytique. L'activation de ces voies de signalisation pourrait impliquer une relocalisation d'ADAM12L au sein de plates-formes de signalisation dans les radeaux lipidiques. Par ailleurs, nous avons montré qu'ADAM12L interagit avec les protéines ZO-1 et ZO-2, des protéines des jonctions serrées, et pourrait favoriser leur désassemblage au cours de l'EMT. Nos travaux ont permis de mettre en évidence une nouvelle fonction pour ADAM12L dans l'EMT, par un mécanisme impliquant une modulation des signaux régulant ce processus. Une meilleure compréhension de la dynamique de ces mécanismes moléculaires pourrait permettre de développer de nouvelles thérapies ciblées pour lutter contre la progression tumorale. / Communication between tumoral cells and the microenvironnement plays an essential role in the developpement of tumors. In that context, the new family of metalloproteases, the ADAM proteins, are major regulators of the tumoral progression by acting on the bioavaibility of importants mediators of cellular communication as cytokines and growth factors. Among this family, ADAM12 is the most associated with cancer. It has been shown to mediate signaling pathways by a process independant of its metalloproteasis activity, in particular for TGFβ signaling. This study show for the first time a role for the membrane form of ADAM12 in the induction of epithelial to mesenchymal transition (EMT), a essential process involved in tumor invasion, whom TGFβ is a main inducer. This effect is mediated by the activation of TGFβ signaling pathways, SMAD3, AKT and ERK and require the cytoplasmic tail of ADAM12L but not its catalytic activity. Activation of these pathways could involve a relocalisation of ADAM12L in special signaling platform in lipid rafts. Moreover, we have shown that ADAM12L interact with ZO-1 and ZO-2, two proteins of tight junctions, and could facilitate their desassembling during EMT. This work underscore for the first time a new function of ADAM12L in EMT, by a mecanism invovlving a modulation of signals regulating this process. A better understanding of the dynamic of these molecular mecanisms could allow the developpement of new targeted therapies to fight against tumoral progression.

Adam12

Transition Epithélio-Mésenchymateuse

TGFβ

Erk

Radeaux lipidiques

Zo

Adam12

Epithelial to Mesenchymal Transition

TGFβ

Erk

Lipid rafts

Zo

Charakterizace buněčného prionového proteinu krevních destiček / The characterization of blood platelet cellular prion protein

Broučková, Adéla

January 2011

The conformational conversion of the cellular prion protein (PrPc) to the misfolded isoform (PrPsc) is the central pathogenic event in the transmissible neurodegenerative prion diseases. The recently shown transmissibility of variant Creutzfeldt-Jakob disease by blood transfusion emphasizes the need for better understanding of the PrPc in blood. In the current thesis, we focused on blood platelet PrPc, which has not been very well described so far. In the first part of the thesis, platelet PrPc was characterized as glycosylphosphatidylinositol- anchored glycoprotein with dominant diglycosylated form. Platelet PrPc was shown to be sensitive to cleavage with proteinase K, which is a feature discriminating between cellular and pathological prion protein. We have confirmed that platelet PrPc binds copper ions by its N- terminal octapeptide repeat region. Regarding quantity of PrPc molecules expressed on blood elements we have proved that both platelets and red blood cells express considerable amount of PrPc and thus can not be neglected in the problematic of prions transmission by blood transfusion. The detailed study regarding PrPc localization in blood platelets is presented in the second part of the thesis. PrPc was shown to be expressed in -granules as well as on the cytoplasmic membrane of...

Les effets cellulaires des inhibiteurs de la protéase virale utilisés en thérapie anti-VIH sur le muscle strié squelettique humain. / The cell effects of the HIV protease inhibitors used in highly active antiretroviral therapy of HIV-1 infection on the human skeletal muscle.

Mercier, Olivia

30 November 2010

Les inhibiteurs de la protéase virale (IPs) sont utilisés avec succès dans le cadre d'une thérapie anti-VIH-1. L'efficacité de ce traitement est incontestable notamment en terme de réduction de la charge virale et de maintient du taux de lymphocytes CD4 circulants. Depuis l'incorporation des IPs dans la prise en charge thérapeutique, on note une réduction significative de la morbidité et de la mortalité ainsi qu'un allongement de la durée de vie des patients. Cependant, la prise de ces molécules anti-rétrovirales s'accompagne de nombreux effets secondaires. Les plus préoccupants d'entre eux sont : une lipodystrophie partielle, une hyperlipidémie, une insulino-résistance, une athérosclérose prématurée, ainsi que des infarctus du myocarde. Les patients sont également confrontés à l'apparition de maladies généralement associées à l'âge telles que la neurodégenérescence, l'ostéopénie et le développement de tumeurs malignes. Les mécanismes cellulaires et moléculaires impliqués dans ces altérations métaboliques n'ont pas encore été élucidés. L'objectif de cette étude était d'étudier les effets cellulaires de quatre IPs (Atazanavir, Lopinavir, Ritonavir et Saquinavir) sur la cellule musculaire striée squelettique humaine. Ces travaux ont permis d'identifier une augmentation de la production d'espèces oxygénées réactives (ERO), une altération morphologique du réticulum sarco/endoplasmique (RS/RE) ainsi qu'une augmentation de l'expression de CHOP, un marqueur du stress de ce compartiment et une diminution de l'expression et de la localisation dans les microdomaines membranaires (lipid rafts) de la cavéoline 3 et de la flotilline 1. Enfin, l'utilisation d'un antioxydant, le Resvératrol protége le myotube primaire humain de ces différentes altérations engendrées par les IPs. Ces données suggèrent un rôle central de la surproduction d'ERO dans le développement du stress du RE/RS et de la perte de localisation des protéines résidantes des microdomaines membranaires. De plus , en l'absence de persceptive vaccinale concrète, le Resvératrol, au travers de ces effets protecteurs, pourrait se révéler un atout de choix dans l'atténuation des effets secondaires des IPs en contribuant ainsi à l'amélioration de la prise en charge du patient séropositif. / HIV protease inhibitors (PI) have been successfully used in highly active antiretroviral therapy (HAART) of HIV-1 infection, the most effective treatment currently available. Incorporation of protease inhibitors in HAART has significantly reduced the morbidity and mortality and prolonged the lifespan of patients with HIV infection. Protease inhibitor benefits are unfortunately compromised by a number of clinically important adverse side-effects. Most patients on HAART develop a metabolic syndrome associated with partial lipodystrophy, hyperlipidemia, insulin resistance, premature atherosclerosis and myocardial infarction. Moreover, these patients face a growing number of other age-related comorbidities, such as neurodegeneration, osteopenia and malignancies. The cellular and molecular mechanisms underlying protease inhibitor-associated metabolic abnormalities remain elusive, but they seem to be related to overproduction of reactive oxygen speci es (ROS), induction of endoplasmic reticulum stress and activation of the unfolded protein response (UPR). The objective of this thesis was to determine the cell effects of four PIs (Atazanavir, Lopinavir, Ritonavir and Saquinavir) in cultures of primary human skeletal myotubes. This study showed that PIs increased ROS production, altered sarco/endoplasmic reticulum (SR/ER) morphology, increased expression of C/EBP homologous protein, a SR/ER stress marker, and decreased expression and localization at lipid rafts of Caveolin 3 and Flotillin 1. In addition, we showed that the antioxidant Resveratrol protected the human primary myotube of these iatrogenic effects. These data suggest a central role of the overproduction of ERO in the development of SR/ER stress and mislocalization of lipid raft proteins induced by PIs. Besides, in absence of vaccine, Resveratrol may be used by a potentiel therapeutic agent to attenuate PI-induced side effects

Thérapie anti-VIH1

Inhibiteur de protéase virale

Stress du réticulum

Resvératrol

Stress oxydant

Microdomaines membranaires

Haart

Protease inhibitors

Endoplasmic reticulum stress

Oxydative stress

Lipid rafts

Resveratrol

Caractérisation moléculaire de la modulation spatio-temporelle des fonctions du phagosome

Goyette, Guillaume

04 1900

La phagocytose est un processus par lequel des cellules spécialisées du système immunitaire comme les macrophages ingèrent des microorganismes envahisseurs afin de les détruire. Les microbes phagocytés se retrouvent dans un compartiment intracellulaire nommé le phagosome, qui acquiert graduellement de nombreuses molécules lui permettant de se transformer en phagolysosome possédant la capacité de tuer et dégrader son contenu. L’utilisation de la protéomique a permis de mettre en évidence la présence de microdomaines (aussi nommés radeaux lipidiques ou radeaux membranaires) sur les phagosomes des macrophages. Notre équipe a démontré que ces radeaux exercent des fonctions cruciales au niveau de la membrane du phagosome. D’abord nous avons observé que la survie du parasite intracellulaire L. donovani est possible dans un phagosome dépourvu de radeaux lipidiques. Parallèlement nous avons constaté qu’un mutant de L. donovani n’exprimant pas de LPG à sa surface(LPG-) est rapidement tué dans un phagosome arborant des radeaux membranaires. Pour comprendre le mécanisme de perturbation des microdomaines du phagosome par la molécule LPG, nous avons provoqué la phagocytose de mutants LPG- du parasite et comparé par microscopie les différences avec le parasite de type sauvage. Nous avons ainsi démontré que le LPG de L. donovani est nécessaire et suffisant au parasite pour empêcher la maturation normale du phagosome. Nous avons également découvert que la molécule LPG permet d’empêcher la formation des radeaux lipidiques sur le phagosome et peut aussi désorganiser les radeaux lipidiques préexistants. Enfin, nous avons montré que l’action de LPG est proportionnelle au nombre d’unités répétitives de sucres (Gal(β1,4)-Manα1-PO4) qui composent cette molécule. Nos travaux ont démontré pour la première fois le rôle important de ces sous-domaines membranaires dans la maturation du phagosome. De plus, nos conclusions seront des pistes à suivre au cours des études cliniques ayant pour but d’enrayer la leishmaniose. Le second objectif de ce travail consistait à effectuer la caractérisation des radeaux lipidiques par une analyse protéomique et lipidomique à l’aide de la spectrométrie de masse. Nous avons ainsi entrepris l’identification systématique des protéines présentes dans les radeaux membranaires des phagosomes et ce, à trois moments clés de leurmaturation. Le traitement des phagosomes purifiés avec un détergent nous a permis d’isoler les «Detergent Resistent Membranes» (DRMs) des phagosomes, qui sont l’équivalent biochimique des radeaux membranaires. Nous avons ainsi établi une liste de 921 protéines associées au phagosome, dont 352 sont présentes dans les DRMs. Les protéines du phagosome sont partagées presque également entre trois tendances cinétiques (augmentation, diminution et présence transitoire). Cependant, une analyse plus spécifique des protéines des DRMs démontre qu’une majorité d’entre elles augmentent en fonction de la maturation. Cette observation ainsi que certains de nos résultats montrent que les radeaux lipidiques des phagosomes précoces sont soit très peu nombreux, soit pauvres en protéines, et qu’ils sont recrutés au cours de la maturation du phagosome. Nous avons aussi analysé les phospholipides du phagosome et constaté que la proportion entre chaque classe varie lors de la maturation. De plus, en regardant spécifiquement les différentes espèces de phospholipides nous avons constaté que ce ne sont pas uniquement les espèces majoritaires de la cellule qui dominent la composition de la membrane du phagosome. L’ensemble de nos résultats a permis de mettre en évidence plusieurs fonctions potentielles des radeaux lipidiques, lesquelles sont essentielles à la biogenèse des phagolysosomes (signalisation, fusion membranaire, action microbicide, transport transmembranaire, remodelage de l’actine). De plus, la cinétique d’acquisition des protéines de radeaux lipidiques indique que ceux-ci exerceraient leurs fonctions principalement au niveau des phagosomes ayant atteint un certain niveau de maturation. L’augmentation du nombre de protéines des radeaux membranaires qui s’effectue durant la maturation du phagosome s’accompagne d’une modulation des phospholipides, ce qui laisse penser que les radeaux membranaires se forment graduellement sur le phagosome et que ce ne sont pas seulement les protéines qui sont importées. / Macrophages are specialized cells of the immune system which mediate destruction and killing of invading micro-organisms. They do so by engulfing them by a process called phagocytosis. Microbes are then captured in an intracellular compartment, the phagosome, which gradually acquire molecules able to attack and degrade its cargo. Use of proteomics let us demonstrate the presence of flotillin-1 enriched microdomains (also called lipid rafts or membrane rafts) on the phagosomes. Our team demonstrated the crucial importance of these rafts in the phagocytosis process. Indeed, survival of L. donovani correlates with its presence in a ‘raftless’ phagosome while a mutated L. donovani without LPG is rapidly killed in a phagosome containing lipid rafts. To understand the membrane raft destabilisation mechanism mediated the LPG molecule, we induced phagocytosis of parasites devoid of LPG (LPG-) and compared it to the wild type parasite by microscopy. We first demonstrated that LPG alone is necessary to prevent normal maturation of the phagosome. Additionally, we discovered that the LPG molecule not only inhibits lipid rafts formation on the phagosome but also disorganise pre-existing lipid rafts. This effect of LPG is proportional to the number of repetitive sugar units (Gal( 1,4)-Man 1-PO4) which compose this molecule. Our work demonstrated for the first time an important role of the membrane rafts in the phagosome maturation. Moreover, our conclusions will give new interesting leads for clinical studies on leishmaniosis. The second goal of this work was to characterise them with proteomics and lipidomics tools. To do this, we undertook the systematic identification of proteins present on both subdomains of the phagosome (lipid rafts versus the rest of the phagosomal membrane). To achieve this, we purified phagosomes, from which we isolated lipid rafts by floating Triton X-100 insoluble membranes (DRMs for Detergent Insoluble Membranes). After that, we identified proteins by mass spectrometry.

phagosome

radeaux lipidiques

radeaux membranaires

protéomique

Leishmania

macrophage

lipid rafts

membrane rafts

proteomics

phagosome

macrophage

Leishmania