SFR TransBioMed - Université de Bordeaux
Transcription
SFR TransBioMed - Université de Bordeaux
SFR TransBioMed 2013 Bilan d’activité Foreword The Federative Research Structure TransBioMed was created in January 2011. It gathers about 500 people belonging to 12 laboratories. The aim in setting up this federation was to bring together scientists involved in research on human pathophysiology, from its very basic aspects up to clinical applications. Covered domains include cancer, infectious diseases, immunology, cardiovascular and lung diseases, genetics and metabolism. The major objectives of TransBioMed are: • To provide the community with an active scientific animation, mostly based on invited seminars • To establish, equip, maintain and staff state-of-the-art technical platforms • To promote collaborations, using a specific call for projects • To foster the career development of young scientists This document will briefly introduce you to the organization and activities of TransBioMed and of its constitutive teams. Dr Jean Rosenbaum 3 contents Flow chart..........................................................................................6 Scientific animation...........................................................................7 Call for Projects.................................................................................8 > Cancer...........................................................................................9 Genetics and Biology of Sarcomas (INSERM U916).................... 11 Breast Cancer Group (INSERM U916)............................................ 12 Molecular mechanisms of the response to treatment (INSERM U916)............................................................................ 13 Angiogenesis and the tumor microenvironment (INSERM U1029) (team 1).......................................................................................... 14 Angiogenesis and the tumor microenvironment (INSERM U1029) (team 2)...................................................................................... 15 Biotherapies (INSERM U1035)...................................................... 16 Leukemic hematopoiesis (INSERM U1035).................................... 17 Dermatology group (INSERM U1035)............................................ 18 ER stress & Cancer (Inserm U1053)........................................... 19 Post-transcriptional regulation of genes, microRNAs and liver cancer (Inserm U1053)................................................ 20 Cytoskeleton & Cancer group (Inserm U1053)............................ 21 Liver cancer (Inserm U1053)...................................................... 22 > Immunology - Microbiology............................................................ 23 Intracellular dynamic of subviral structures (CNRS UMR 5234).... 25 African Trypanosoma virulence factor and pathogenicity (CNRS UMR 5234)........................................................................ 26 Trypanosome cytoskeleton biogenesis (CNRS UMR 5234).......... 27 Candida and Pathogenicity (CNRS UMR 5234)............................ 28 Variability, replication and mobility of viral and bacterial genomes (CNRS UMR 5234)........................................................ 29 Pluripotency and early steps of differentiation (CNRS UMR 5164). 30 Activation of human T lymphocytes (CNRS UMR 5164)................ 31 > Biochemistry Genetics..................................................................... 33 Energy transduction systems and mitochondrial morphology (SysTEMM) (IBGC CNRS UMR 5095)............................................ 35 Functional analysis of amyloids (IBGC CNRS UMR 5095)................ 36 Genetics of Metabolic Networks (IBGC CNRS UMR 5095)............. 37 Cellular energy metabolism (IBGC CNRS UMR 5095)......................38 Molecular genetics of mitochondrial systems (IBGC CNRS UMR 5095)....................................................................39 Chromosome Segregation (IBGC CNRS UMR 5095)..................... 40 Mitochondria, stress and cell death (IBGC CNRS UMR 5095)........ 41 Cell Growth and Division (IBGC CNRS UMR 5095)........................ 42 4 TITRE Mitochondrial organization and dynamics (IBGC CNRS UMR 5095).. 43 Contents Control and Dynamics of Cell Division (IBGC CNRS UMR 5095)... 44 Cell Biology of Quiescence (IBGC CNRS UMR 5095).................... 45 Non-self recognition in fungi (IBGC CNRS UMR 5095)................... 46 Rare diseases: Genetics and Metabolism (MRGM, EA4576)....... 47 > Cardio-thoracic...........................................................................49 Bronchial remodelling (INSERM U1045)........................................51 Endothelial cell Biology (INSERM U1045).....................................52 Pathophysiology of pulmonary circulation (INSERM U1045).........53 Cardiovascular adaptation to ischemia (INSERM U1034).............54 technological platforms..................................................55 > Flow Cytometry core facility with high speed cell sorter.......58 > The Histology platform..............................................................60 > Level 3 safety laboratory...........................................................62 > Vectorology platform.................................................................64 5 Flow chart Secrétariat Gestion Directeur Communication Hélène Aouizerate Virginie Rocher Jean Rosenbaum Les PlatesFormes Les 4 Axes Vectorologie : Véronique Guyonnet-Duperat Alice Vimeney Andreas Bikfalvi Mojgan Mergny Michael Kann Julie Déchanet-Merville Bertrand Daignan-Fornier Didier Lacombe Roger Marthan Alain-Pierre Gadeau Cytométrie : Vincent Pitard Santiago Gonzalez Les Comités de ¨Pilotage de chaque axe : Andreas Bikfalvi Richard Iggo Frédéric Mazurier Muriel Priault Hervé Bonnefoi Michael Kann Charlotte Behr Derrick Robinson Philippe Lehours Thierry Noel Bertrand Daignan-Fornier Isabelle Sagot Anne Devin Didier Lacombe Roger Marthan Cécile Duplaa Alain-Pierre Gadeau Thierry Letellier Jean-François Quignard Laboratoire P3 Michel Ventura Histologie Les laboratoires de chaque axe : Histologie Nathalie DugotSenant Andréas BIKFALVI INSERM U 1029 Université Bordeaux 1 Mécanismes moléculaires de l’Angiogenèse Michael Kann CNRS UMR 5234 Université Bordeaux Segalen Microbiologie cellulaire et moléculaire et pathogénicité Hubert DE VERNEUIL INSERM U 1035 Université Bordeaux Segalen Biothérapie des maladies génétiques et cancers Jean-François MOREAU CNRS UMR 5164 Université Bordeaux Segalen Composantes innées de la réponse immunitaire et différentiation Jean-Philippe MERLIO EA 2406 Université Bordeaux Segalen Histologie et Pathologie moléculaires des tumeurs Francis MEGRAUD INSERM U 853 Université Bordeaux Segalen Infection à Hélicobacter, inflammation et cancer Josy REIFFERS INSERM U 916 Université Bordeaux Segalen Validation et identification de nouvelles cibles en oncologie Jean ROSENBAUM INSERM U 1053 Université Bordeaux Segalen Physiopathologie du cancer du Foie 6 Bertrand DAIGNAN-FORNIER CNRS UMR 5095 Université Bordeaux Segalen Institut de Biochimie et Génétique Cellulaires Roger Marthan INSERM U 1045 Université Bordeaux Segalen Centre de Recherche cardio-thoracique de Bordeaux Didier LACOMBE Thierry Couffinhal EA 4576 INSERM U 1034 Université Bordeaux Segalen Université Bordeaux Segalen Maladies rares : Génétique et Adapatation cardiovasculaire à métabolisme (MRGM) l'ischémie Scientific animation Organizing the scientific life is one of the main tasks of the TransBioMed SFR. We offer a broad program along several lines: • Seminars with speakers invited by scientists from the SFR. Those are organized at least weekly, often bi-weekly. About half of the speakers come from abroad • A whole-day yearly seminar: this event gathers most people from the SFR and includes guest lectures from prestigious outside speakers, talks by scientists from each of the 4 scientific axis, and a very active poster session • Several thematic seminars have been organized by the scientific axes on MicrobiologyImmunology, Cardio-pulmonary research, and Biochemistry & Genetics • Technical workshops: structural biology, flow cytometry. In addition to these “generalist” events, a whole section is dedicated to the young researchers. These events are organized by a group of young scientists nicknamed TBM docs: • A whole-day yearly Young Scientists meeting that mixes scientific talks by young scientists from TransBioMed and invited conferences dealing with science or career development • Career development evening sessions where experts from recruiting committees from INSERM, CNRS or Universities, or Biotech people, try to give the clues to recruitment 7 Call for Projects The SFR launches a yearly call for projects for the funding of new, emerging projects, that link teams from separate laboratories. The projects are evaluated by external referees and the final selection is made by an ad hoc committee. Four to 6 projects are funded for an amount of 12-20 k€. Projects funded in 2012 Applicant Partner(s) Title Mélanie Bonhivers Roger Marthan Characterisation of SAXO proteins, a novel family of microtubule-associated proteins specific to cilia and flagella: potential implication in bronchial ciliopathies. Emmanuel Tetaud Didier Lacombe Comparative study of energetic compensation mechanisms in human and yeast Aurélia Cassany Julie DéchanetMerville Impact of core 18-27 epitope polymorphism on CD8 T cell response in HLA-A2 patients with chronic HBV infection Chloé James François MoreauGaudry Design of a new model for studying megacaryocytopoiesis based on human iPSC (Induced Pluripotent Stem Cells) Hélène Bœuf François MoreauGaudry Role of miRNA and LIF (Leukemia Inhibitory Factor) in the plasticity of murine ES (Embryonic Stem) and iPS (induced Pluripotent Stem) cells. Projects funded in 2013 8 Applicant Partner(s) Title Muriel Cario André Marie-Elise Truchetet Role of pigmentary defects in the development of the fibrotic process in systemic sclerosis Armelle Menard Bruno Cardinaud, Christophe Grosset Role of the CDT genotoxin of Helicobacter hepaticus in liver carcinogenesis Jean-François Quignard Harald Wodrich Adenoviral infection and modification of the activity of type T (Cav3) calcium channels through competitive recruitment of Nedd4-2. Christophe Richez Cyril Goizet Identification, quantification and characterization of extracellular mitochondrial DNA in rheumatoid arthritis Isabelle Sagot Violaine Moreau, Frédéric Saltel Actin-Bodies, a quiescence marker from yeast to human Philippe Pourquier Eric Chevet Search for DNA-PKcs/Topoisomerase interaction antagonists for potentiating the action of camptothecine derivatives CANCER Genetics and Biology of Sarcomas (INSERM U916) http://www.bergonie.org/fr/basic-research/frederic-chibon.html Frédéric Chibon Our projects are divided into two main axes: 1) Describe and understand the genetics of sarcomas and 2) Transfer research data to patients. Thus, we aim at 3 major objectives: •To study, as exhaustively as possible the genome of sarcomas. To this end, we have launched two Next generation Sequencing (NGS) projects dealing with uterine sarcomas (complete genome) and complex genetics sarcomas (Exome). •Identify the mechanisms responsible for a prognosis signature identified in the team. We study currently 4 candidate genes. •Identify new therapeutic targets and signatures predictive for response to chemotherapy. To this end, we have launched two projects. One aims at characterizing, using CGH and expression arrays, 300 sarcomas receiving a standardized adjuvant treatment in the French Sarcoma Group and the RRePs and NetSarc networks. The second one aims at developing a preclinical tests platform based on a panel of 25 sarcoma cell lines established and characterized in the lab. All these projects will be developed in the continuity of our interaction with the pathologists and clinicians of the French Sarcoma Group for a rapid and efficient transfer for the benefit of patients. • Research team Frédéric Chibon • PH-CR1 INSERM Jean–Michel Coindre • PU-PH Alain Aurias • DR INSERM Binh Nguyen Bui • PH IB Agnès Neuville • MCU-PH, IB Antoine Italiano • CCA IB Céline Brulard • TCH IB Pauline Lagarde • TCH IB Gaëlle Pérot • Ingénieur IB • Selected Publications Italiano A, Lagarde P, Brulard C, Terrier P, Laë M, Marques B, Ranchere-Vince D, Michels JJ, Trassard M, Cioffi A, Piperno-Neumann S, Chevreau C, Blay JY, Delcambre C, Isambert N, Penel N, Bay JO, Bonvalot S, Le Cesne A, Coindre JM, Chibon F. Genetic profiling identifies two classes of soft-tissue leiomyosarcomas with distinct clinical characteristics. Clin Cancer Res. 2013 Mar 1;19(5):11906. doi: 10.1158/1078-0432.CCR-12-2970. Lagarde P, Przybyl J, Brulard C, Pérot G, Pierron G, Delattre O, Sciot R, Wozniak A, Schöffski P, Terrier P, Neuville A, Coindre JM, Italiano A, Orbach D, DebiecRychter M,Chibon F. Chromosome instability accounts for reverse metastatic outcomes of pediatric and adult synovial sarcomas. J Clin Oncol. 2013 Feb 10;31(5):60815 Pérot G, Croce S, Ribeiro A, Lagarde P, Velasco V, Neuville A, Coindre JM, Stoeckle E, Floquet A, Macgrogan G, Chibon F (2012). MED12 Alterations in Both Human Benign and Malignant Uterine Soft Tissue Tumors. PLoS One 7(6):e40015. Lagarde P, Pérot G, Kauffmann A, Brulard C, Dapremont V, Hostein I, Neuville A, Wozniak A, Sciot R, Schöffski P, Aurias A, Coindre JM, Debiec-Rychter M, Chibon F (2012). Mitotic checkpoints and chromosome instability are strong predictors of clinical outcome in gastrointestinal stromal tumors. Clin Cancer Res 18(3):826-38. Gibault L, Ferreira C, Pérot G, Audebourg A, Chibon F, Bonnin S, Lagarde P, Vacher-Lavenu MC, Terrier P, Coindre JM, Aurias A (2012). From PTEN loss of expression to RICTOR role in smooth muscle differentiation: complex involvement of the mTOR pathway in leiomyosarcomas and pleomorphic sarcomas. Mod Pathol 25(2):197-211. Gibault L, Pérot G, Chibon F, Bonnin S, Lagarde P, Terrier P, Coindre JM, Aurias A (2011). New insights in sarcoma oncogenesis: a comprehensive analysis of a large series of 160 soft tissue sarcomas with complex genomics. J Pathol 223(1):64-71. Pérot G, Chibon F, Montero A, Lagarde P, de Thé H, Terrier P, Guillou L, Ranchère D, Coindre JM, Aurias A (2010). Constant p53 pathway inactivation in a large series of soft tissue sarcomas with complex genetics. Am J Pathol 177(4):2080-90. Chibon F, Lagarde P, Salas S, Pérot G, Brouste V, Tirode F, Lucchesi C, de Reynies A, Kauffmann A, Bui B, Terrier P, Bonvalot S, Le Cesne A, Vince-Ranchère D, Blay JY, Collin F, Guillou L, Leroux A, Coindre JM, Aurias A (2010). Validated prediction of clinical outcome in sarcomas and multiple types of cancer on the basis of a gene expression signature related to genome complexity. Nat Med 16(7):781-7. CANCER │ 11 Breast Cancer Group (INSERM U916) www.bergonie.org/en/basic-research/research/ Richard Iggo • Research team Richard Iggo • PU Hervé Bonnefoi • PU-PH Michel Longy • PH Louis Mauriac • PH Gaëtan MacGrogan • PH Nicolas Sévenet • MCU-PH Françoise Bonnet • IE Elodie Richard • IE Elodie Monceau • IE Natalie Jones • Post-doc Stéphanie Verbeke • Post-doc Simon Bayle • Thesard Audrey Rouault • Thesard Virginie Bubien • Thesard The breast cancer group has four principal investigators: Richard Iggo (cell biology), Michel Longy (genetics), Gaetan MacGrogan (pathology) and Hervé Bonnefoi (medical oncology). It conducts research on the biology and treatment of breast cancer. The group receives funding from multiple sources including project grants from INCa, ANR, ARC, and the Aquitaine Region Council, and a programme grant from the Cancer League. Major projects in the group include: 1. Identification of breast cancer predisposition genes by next generation sequencing of tumours and germline DNA from patients attending the genetics clinic at the Bergonie Cancer Institute. 2. Characterisation of breast cancer predisposition genes in cell lines and transgenic mice. 3. Identification of changes acquired by breast tumours during treatment with anti-hormonal therapy. • Selected publications Bertolotto C, Lesueur F, Giuliano S, Strub T, de Lichy M, Bille K, Dessen P, d’Hayer B, Mohamdi H, Remenieras A, Maubec E, de la Fouchardière A, Molinié V, Vabres P, Dalle S, Poulalhon N, Martin-Denavit T, Thomas L, ndryBenzaquen P, Dupin N, Boitier F, Rossi A, Perrot JL, Labeille B, Robert C, Escudier B, Caron O, Brugieres L, Saule S, Gardie B, Gad S, Richard S, Couturier J, Teh BT, Ghiorzo P, Pastorino L, Puig S, Badenas C, Olsson H, Ingvar C, Rouleau E, Lidereau R, Bahadoran P, Vielh P, Corda E, Blanche H, Zelenika D, Galan P, Aubin F, Bachollet B, Becuwe C, Berthet P, Bignon YJ, Bonadona V, Bonafe JL, Bonnet-Dupeyron MN, Cambazard F, ChevrantBreton J, Coupier I, Dalac S, Demange L, D’Incan M, Dugast C, Faivre L, Vincent-Fetita L, Gauthier-Villars M, Gilbert B, Grange F, Grob JJ, Humbert P, Janin N, Joly P, Kerob D, Lasset C, Leroux D, Levang J, Limacher JM, Livideanu C, Longy M, Lortholary A, Stoppa-Lyonnet D, Mansard S, Mansuy L, Marrou K, Mateus C, Maugard C, Meyer N, Nogues C, Souteyrand P, VenatBouvet L, Zattara H, Chaudru V, Lenoir GM, Lathrop M, Davidson I, Avril MF, Demenais F, Ballotti R, Bressac-de-Paillerets B. A SUMOylation-defective MITF germline mutation predisposes to melanoma and renal carcinoma. Nature 2011 ; 480 : 94-8. Bertucci F, Borie N, Roché H, Bachelot T, Le Doussal JM, MacGrogan G, Debono S, Martinec A, Treilleux I, Finetti P, Esterni B, Extra JM, Genève J, Hermitte F, Chabannon C, Jacquemier J, Martin AL, Longy M, Maraninchi D, Fert V, Birnbaum D, Viens P. Gene expression profile predicts outcome after anthracycline-based adjuvant chemotherapy in early breast cancer. Breast Cancer Res Treat 2011 ; 127 : 363-73. Bonadona V, Bonaïti B, Olschwang S, Grandjouan S, Huiart L, Longy M, Guimbaud R, Buecher B, Bignon YJ, Caron O, Colas C, Noguès C, LejeuneDumoulin S, Olivier-Faivre L, Polycarpe-Osaer F, Nguyen TD, Desseigne F, Saurin JC, Berthet P, Leroux D, Duffour J, Manouvrier S, Frébourg T, Sobol H, Lasset C, Bonaïti-Pellié C. Cancer risks associated with germline mutations in MLH1, MSH2, and MSH6 genes in Lynch syndrome. JAMA 2011 ; 305 : 2304-10. Bonnefoi H, Piccart M, Bogaerts J, Mauriac L, Fumoleau P, Brain E, Petit T, Rouanet P, Jassem J, Blot E, Zaman K, Cufer T, Lortholary A, Lidbrink E, André S, Litière S, Dal Lago L, Becette V, Cameron DA, Bergh J, Iggo R, on behalf of 12 │CANCER the EORTC 10994/BIG 1-00 Study Investigators. TP53 status for prediction of sensitivity to taxane versus non-taxane neoadjuvant chemotherapy in breast cancer (EORTC 10994/BIG 1-00): a randomised phase 3 trial. Lancet Oncol 2011 ; 12 : 527-39. Chirgwin J, Sun Z, Smith I, Price KN, Thürlimann B, Ejlertsen B, Bonnefoi H, Regan MM, Goldhirsch A, Coates AS, for the BIG 1-98 Collaborative and International Breast Cancer Study Groups. The advantage of letrozole over tamoxifen in the BIG 1-98 trial is consistent in younger postmenopausal women and in those with chemotherapy-induced menopause. Breast Cancer Res Treat 2012 ; 131 : 295-306. Guedj M, Marisa L, de Reynies A, Orsetti B, Schiappa R, Bibeau F, MacGrogan G, Lerebours F, Finetti P, Longy M, Bertheau P, Bertrand F, Bonnet F, Martin AL, Feugeas JP, Bièche I, Lehmann-Che J, Lidereau R, Birnbaum D, Bertucci F, de Thé H, Theillet C. A refined molecular taxonomy of breast cancer. Oncogene 2012 ; 1196-206-1206. Houdayer C, Caux-Moncoutier V, Krieger S, Barrois M, Bonnet F, Bourdon V, Bronner M, Buisson M, Coulet F, Gaildrat P, Lefol C, Leone M, Mazoyer S, Muller D, Remenieras A, Revillion F, Rouleau E, Sokolowska J, Vert JP, Lidereau R, Soubrier F, Sobol H, Sévenet N, Bressac-de-Paillerets B, Hardouin A, Tosi M, Sinilnikova OM, Stoppa-Lyonnet D. Guidelines for splicing analysis in molecular diagnosis derived from a set of 327 combined in silico/in vitro studies on BRCA1 and BRCA2 variants. Hum Mutat 2012 ; 33 : 1228-38. Rouleau E, Jesson B, Briaux A, Nogues C, Chabaud V, Demange L, Sokolowska J, Coulet F, Barouk-Simonet E, Bignon YJ, Bonnet F, Bourdon V, Bronner M, Caputo S, Castera L, Delnatte C, Delvincourt C, Fournier J, Hardouin A, Muller D, Peyrat JP, Toulas C, Uhrhammer N, Vidal V, StoppaLyonnet D, Bieche I, Lidereau R. Rare germline large rearrangements in the BRCA1/2 genes and eight candidate genes in 472 patients with breast cancer predisposition. Breast Cancer Res Treat 2012 ; 133 : 1179-90. Toulmonde M, Madranges N, Brouste V, Donamaria C, MacGrogan G, Durand M, Bonnefoi H, Mauriac L, Debled M. Docetaxel rechallenge after a first response in non-resistant metastatic breast cancer: significant activity with manageable toxicity. Breast Cancer Res Treat 2012 ; 134 : 325-32. Molecular mechanisms of the response to treatment (INSERM U916) http://www.bergonie.org/fr/basic-research/pierre-soubeyran.html Pierre Soubeyran • Research team Our group is focusing on the identification and validation of new therapeutic targets in 3 tumor types: colon cancers, prostate cancer, and agressive lymphomas in aged patients. We study more particularly calicum signaling and death receptors (see articles in PNAS and Plos Biol 2011) as well as autophagy (Autophagy 2011), and try to identify factros predicting the resposne to chemotherapy and targeted therapies (publications in Pharmacogenomics, Carcinogenesis et Cancer). We can validate targets at the clinical and functional levels, notably using a robotized flow cytometry equipment (publications in 2011 in Am J Pathol and Plos One). We also use multiples techniques including cell and tissue imaging (confocal microscope and ICys laser scanning cytometer), molecular electrophysiology, flow cytometry, especially at high throughput (High Throughput screening), pharmacogenetics and pyrosequencing. Pierre Soubeyran • PU-PH Jacques Bonnet • PU émérite Serge Evrard • PU-PH Jacques Robert • PU-PH Danièle Montaudon • MCU-PH Valérie Le Morvan • IE Université Laurence Bresson–Bepoldin • CR1 CNRS Mojgan Djavaheri–Mergny • CR1 INSERM Philippe Pourquier • CR1 INSERM Pierre Vacher • CR1 INSERM Isabelle Mahouche • AI INSERM Anne–Marie Vacher • AI INSERM Gaëlle Labrunie • IE INSERM Jean-Pierre Portail • IE INSERM Brigitte Godard • Gestionnaire INSERM Nadine Houédé • PH IB Isabelle Soubeyran • PH IB Stéphane Pedeboscq • PH CHU Denis Smith • PH CHU Hervé Wallerand • PH CHU Ricardo Bellott • Ingénieur IB Lydia Lartigue-Faustin • Post-Doc Christophe Rey • Post-Doc Emilie Charles • Thèse Julie Dubois • Thèse Barbara Lortal • Thèse Emmanuel Roche • Thèse Aurore Trocoli • Thèse • Selected publications Djavaheri-Mergny M, Maiuri MC, Kroemer G. Cross talk between apoptosis and autophagy by caspase-mediated cleavage of Beclin 1. Oncogene 2010 ; 29 : 1717-9. Houédé N, Thall PF, Nguyen H, Paoletti X, Kramar A. Utility-based optimization of combination therapy using ordinal toxicity and efficacy in phase I/II trials. Biometrics 2010 ; 66 : 532-40. Laroche-Clary A, Le Morvan V, Yamori T, Robert J. Cytochrome P450 1B1 (CYP1B1) gene polymorphisms as predictors of anticancer drug activity: studies with in vitro models. Mol Cancer Ther 2010 ; 9 : 3315-21. Pédeboscq S, Gravier D, Casadebaig F, Hou G, Gissot A, De Giorgi F, Ichas F, Cambar J, Pometan JP. Synthesis and study of antiproliferative activity of novel thienopyrimidines on glioblastoma cells. Eur J Med Chem 2010 ; 45 : 2473-9. Khadra N, Bresson-Bepoldin L, Penna A, Chaigne-Delalande B, Segui B, Levade T, Vacher AM, Reiffers J, Ducret T, Moreau JF, Cahalan M, Vacher P, Legembre P. CD95/Fas triggers Orai1-mediated localized Ca2+ entry that regulates recruitment of PKCß2 and prevents DISC formation. PNAS 2011 ; 108 : 19072-7. Mathiaux J, Le Morvan V, Pulido M, Jougon J, Bégueret H, Robert J. Role of DNA repair gene polymorphisms in the efficiency of platinum-based adjuvant chemotherapy for non-small cell lung cancer. Mol Diagn Ther 2011 ; 15 : 159-66. Salles G, Seymour JF, Offner F, López-Guillermo A, Belada D, Xerri L, Feugier P, Bouabdallah R, Catalano JV, Brice P, Caballero D, Haioun C, Pedersen LM, Delmer A, Simpson D, Leppa S, Soubeyran P, Hagenbeek A, Casasnovas O, Intragumtornchai T, Fermé C, Gomes da Silva M, Sebban C, Lister A, Estell JA, Milone G, Sonet A, Mendila M, Coiffier B, Tilly H. Rituximab maintenance for 2 years in patients with high tumour burden follicular lymphoma responding to rituximab plus chemotherapy (PRIMA): a phase 3, randomised controlled trial. Lancet 2011 ; 377 : 42-51. Soubeyran I, Mahouche I, Grigoletto A, Leste-Lasserre T, Drutel G, Rey C, Blanchard F, Brouste V, Pédeboscq S, Sabourin JC, Bécouarn Y, Reiffers J, Ichas F, De Giorgi F. Tissue microarray cytometry reveals positive impact of HIPK2 in colon cancer survival irrespective of p53 function. Am J Pathol 2011 ; 178 : 1986-98. Tauzin S, Chaigne-Delalande B, Selva E, Khadra N, Daburon S, Contin-Bordes C, Blanco P, Le Seyec J, Ducret T, Counillon L, Moreau JF, Hofman P, Vacher P, Legembre P. The naturally processed CD95L elicits a c-yes/calcium/PI3Kdriven cell migration pathway. PloS Biol 2011 ; 9 : e1001090. Trocoli A, Mathieu J, Priault M, Reiffers J, Souquere S, Pierron G, Besançon F, Djavaheri-Mergny M. ATRA-induced upregulation of Beclin 1 prolongs the life span of mature Acute Promyelocytic Leukemia (APL) cells but is not essential for the granulocytic differentiation process. Autophagy 2011 ; 7 : 1108-14. Trocoli A, Djavaheri-Mergny M. The complex interplay between autophagy and NF-B signaling pathways in cancer cells. Am J Cancer Res 2011 ; 1 : 629-49. Vacher P, Khadra N, Vacher AM, Charles E, Bresson-Bepoldin L, Legembre P. Does calcium contribute to the CD95 signaling pathway? Anticancer Drugs 2011 ; 22 : 481-7. Auzanneau C, Montaudon D, Jacquet R, Puyo S, Pouysegu L, Deffieux D, Elkaoukabi-Chaibi A, De Giorgi F, Ichas F, Quideau S, Pourquier P. The polyphenolic ellagitannin vescalagin acts as a preferential catalytic inhibitor of the alpha isoform of human DNA topoisomerase II. Mol Pharmacol 2012 ; 82 : 134-41. Laroche-Clary A, Kauffmann A, Smith D, Laurand-Quancard A, Evrard S, Brunet R, Le Morvan V, Robert J. Absence of transcriptomic signature of response to chemotherapy in metastatic colorectal carcinoma patients. Pharmacogenomics 2012 ; 13 : 497-504. Moisan F, Laroche-Clary A, Auzanneau C, Ricard N, Pourquier P, Robert J, Le Morvan V. Deciphering the role of the ERCC2 gene polymorphism on anticancer drug sensitivity. Carcinogenesis 2012 ; 33 : 962-8. Pédeboscq S, Rey C, Petit M, Harpey C, De Giorgi F, Ichas F, Lartigue L. Nonantioxidant properties of alpha-tocopherol reduce the anticancer activity of several protein kinase inhibitors in vitro. PLoS One 2012 ; 7 : e36811. Soubeyran P, Fonck M, Blanc-Bisson C, Blanc JF, Ceccaldi J, Mertens C, Imbert Y, Cany L, Vogt L, Dauba J, Palis R, Andriamampionona F, Houédé N, Floquet A, Chomy F, Brouste V, Ravaud A, Bellera C, Rainfray M. Predictors of early death risk in older patients treated by first-line chemotherapy for cancer. J Clin Oncol 2012 ; 30 : 1829-34. CANCER │ 13 Angiogenesis and the tumor microenvironment (INSERM U1029) (Team 1) http://www.u-bordeaux1.fr/U1029/Site/INSERM_U1029.html Andreas Bikfalvi • Research team Andreas Bikfalvi Pr Sophie Javerzat Pr Clotilde Billottet MCU Patrick Auguste MCU Sophie North MCU Géraldine Miquel ASI Céline Léon IGE Nadège Pujol Tech Cathy Quemener Post-doctoral fellow Jessica Baud IGE Students : Sylvaine Guerit Virginie Godard Wilfried Souleyrau • Selected publications Platonova N, Miquel G, Regenfuss B, Taouji S, Cursiefen C, Chevet E, Bikfalvi A. Evidence for the interaction of fibroblast growth factor-2 with the lymphatic endothelial cell marker LYVE-1. Blood. 2013 Feb 14;121(7):1229-37 Soulet F, Kilarski WW, Roux-Dalvai F, Herbert JM, Sacewicz I, Mouton-Barbosa E, Bicknell R, Lalor P, Monsarrat B, Bikfalvi A. Mapping the extracellular and membrane proteome associated with the vasculature and the stroma in the embryo. Mol Cell Proteomics. 2013 May 14 The aim of the laboratory is to study the cross talk between angiogenesis and tumor biology, and in particular metastasis, and to reinforce the translational aspects of our research programs. While angiogenesis is thought to promote tumor growth through the delivery of oxygen and nutriments to the growing tumor, recent evidence suggests that additional functions may be involved. We are interested in unraveling paracrine effects of angiogenic vessels on primary tumor growth, tumor invasion and metastasis. Emerging evidence also indicates that tumors can escape angiogenic blockade. We are interested in identifying mechanisms of escape and new therapeutic targets to prevent/treat tumor escape induced after angiogenic blockade or radiotherapy. The aim is also to identify new potential therapeutic targets for cancer that are related to angiogenesis and tumor cell invasion. Furthermore, today there are no validated tests to routinely monitor angiogenesis in patients. The conventional endpoints used to evaluate anticancer agents, such as response rate, prolongation of time to progression and time to death are inadequate to assess antiangiogenic agents. Furthermore we aim to gain insights into the formation of the prematastatic niche. The following studies have been conducted in the last years : - Development of new models of tumor angiogenesis in the chick embryo - Biological role and structure-function analysis of the CXC chemokines CXCL4L1 and CXCL4 - Role of endothelial kinesins in tumor angiogenesis - Role of the unfolded protein response in angiogenesis and tumor cell invasion - Role of fibroblast growth factors (FGFs) in lymphangiogenesis and of the lymphatic marker Lyve-1 Fergelot P, et al. The Experimental Renal Cell Carcinoma Model in the Chick Embryo. Angiogenesis 2013 Jan;16(1):181-94 Dubrac A, et al. Functional divergence between two chemokines is conferred by single amino acid change. Blood, 2010, 116(22):4703-11 Cavill R, et al. A combined metabonomic and transcriptomic approach to investigate metabolism during development in the chick chorioallantoic membrane. J Proteome Res. 2010 Jun 4;9(6):3126-34] Auf G, et al Inositol-requiring enzyme 1alpha is a key regulator of angiogenesis and invasion in malignant glioma. Proc Natl Acad Sci U S A. 2010 Aug 31;107(35):15553-8. Glioblastoma cells (green) coopting vessels (red) 14 │CANCER Angiogenesis and the tumor microenvironment (INSERM U1029) (Team 2) http://www.u-bordeaux1.fr/U1029/Site/INSERM_U1029.html A-Majid Khatib To attain their biological active forms, a variety of protein precursors are processed by proteases named proprotein convertases (PCs). We are pioneered in this field of investigation. Our previous studies were the first to demonstrate the importance of the maturation of protein precursors such as matrix metalloproteases, adhesion molecules, and growth factors by these enzymes in carcinogenesis, angiogenesis and metastasis. We found that inhibition of the PCs in various tumor cells represses their malignant phenotypes and their ability to mediate tumor growth and angiogenesis. We also identified MT1-MMP, PDGF-A, PDGF-B, VEGF-C and Hepcidin as new PCs substrates. Inhibition of these molecules processing by specific inhibitors or through directed mutagenesis blocks their functions. For example unprocessed PDGF and VEGF-C was found to inhibit tumor growth and the formation of tumor vascular and lymphatic vessels. Based on these and other findings we postulate that PCs play a key role in the growth, survival and metastatic potential of tumor cells by regulating the activity of their cognate substrates and downstream effectors. This multidisciplinary research program covers several interconnecting areas from cells to small animals (zebrafish, mice) and proteins, to the basic chemistry of inhibitors and clinical settings. The aim of our team is: [1] Development of small molecules PC inhibitors and evaluate their effects on angiogenesis, tumor growth and metastasis. [2] Evaluation of the correlation between the expression/activity of PCs and tumor progression and metastasis. Now that the role of PCs in various diseases is well established, the proposed investigations will not only add information on their exact mode of actions, but will provide further evidence that expression of PCs is a major event leading to carcinogenesis and metastasis. In the long term, the program will provide a rationale for testing a new family of small molecule compounds as potential anti-tumorigenic and angiogenic agents or in conjunction with standard therapy in clinical settings. The 4 best inhibitors (blue) docked into the Furin active site identified by Virtual ligand screening (VLS) Tumor cells expressing tomato-vector were injected into eGFP-labelled, transgenic fli-1 zebrafish and tumor cells were visualisezd under UV light. Vessels are in green and tumor cells in red. C: Higher magnification. Arrow indicates tumor cells. • Research team A-Majid Khatib Martin Hagedorn Fabienne Soulet Claude Lalou Jia Ma Allain Barbara Students : Fatma Sfaxi Christophe Chemineau • Selected publications Scamuffa N, Metrakos P, Calvo F, Khatib AM. Identification of the myosin heavy polypeptide 9 as a downstream effector of the proprotein convertases in the human colon carcinoma HT-29 cells. Methods Mol Biol. 2011;768:207-15. Khatib AM, Lahlil R, Scamuffa N, Akimenko MA, Ernest S, Lomri A, Lalou C, Seidah NG, Villoutreix BO, Calvo F, Siegfried G. Zebrafish ProVEGF-C expression, proteolytic processing and inhibitory effect of unprocessed ProVEGF-C during fin regeneration. PLoS One. 2010, 5:e11438. Basak A, Chen A, Scamuffa N, Mohottalage D, Basak S, Khatib AM. Blockade of furin activity and furin-induced tumor cells malignant phenotypes by the chemically synthesized human furin prodomain. Curr Med Chem. 2010;17:2214-21. Scamuffa N, Basak A, Lalou C, Wargnier A, Marcinkiewicz J, Siegfried G, Chrétien M, Calvo F, Seidah NG, Khatib AM. Regulation of prohepcidin processing and activity by the subtilisinlike proprotein convertases Furin, PC5, PACE4 and PC7. Gut. 2008. 57:157382. Scamuffa N, Siegfried G, Bontemps Y, Ma L, Basak A, Cherel G, Calvo F, Seidah NG, Khatib AM. Selective inhibition of proprotein convertases represses the metastatic potential of human colorectal tumor cells. J Clin Invest. 2008,118:352-63. CANCER │ 15 Biotherapies (INSERM U1035) www.u1035.u-bordeaux2.fr François Moreau-Gaudry iPSC and porphyrias • Research team François Moreau-Gaudry, PU-PH, HDR Chercheurs et Enseignant-chercheurs Aurélie Bedel, MCU-PH Sandrine Dabernat, MCU-PH, HDR Cécile Ged, MCU-PH, HDR Evelyne Peuchant, MCU-PH, HDR Emmanuel Richard, MCU-PH Hubert de Verneuil, PU-PH, HDR Jean-Marc Blouin, AHU Personnels ITA Magalie Lalanne, Technicienne Bordeaux 2 Isabelle Moranvillier, Technicienne Bordeaux 2 Corrine Bourdie, Technicienne INSERM Miguel Taillepierre, IE CDD Doctorants François Béliveau Marie Lafitte Yann Duchartre • Selected publications Bedel A, Taillepierre M, GuyonnetDuperat V, Lippert E, Dubus P, Dabernat S, Mautuit T, Cardinaud B, Pain C, Rousseau B, Lalanne M, Ged C, Duchartre Y, Richard E, de Verneuil H, Moreau-Gaudry F. Metabolic Correction of Congenital Erythropoietic Porphyria with iPSCs Free of Reprogramming Factors. Am J Hum Genet. 2012 Jul 13;91(1):109-21. Lafitte M, Rousseau B, Moranvillier I, Taillepierre M, Peuchant E, GuyonnetDupérat V, Bedel A, Dubus P, de Verneuil H, Moreau-Gaudry F, Dabernat S. In vivo gene transfer targeting in pancreatic adenocarcinoma with cell surface antigens. Mol Cancer. 2012 Oct 22;11:81 16 │CANCER Erythropoietic porphyrias are genetic diseases linked to an enzymatic defect in the heme biosynthetic pathway, leading to the toxic accumulation of porphyrins in the bone marrows, red blood cells, spleen and liver. They are associated with a cutaneous photosensitivity of variable severity according to the type of porphyria. The oncly curative treatment for severe porphyrias is allogeneic bone marrow transplantation, which requires a HLA-compatible donor. We are developing gene therapy approaches for erythropoietic porphyrias using lentiviral-based gene transfer into autologous hematopoietic stem cells. We are currently evaluating the potential of human and murine induced pluripotent stem cells obtained through reprogramming somatic stem cells and their differentiation into the hematopoietic and hepatic lineage for the treatment of these diseases. Hepatocyte differentiation from human iPSCs: physiopathological studies and therapeutic applications for inherited liver diseases. Transplantation of allogenic or genetically modified autologous hepatocytes may be an alternative to whole-liver transplantation for the treatment of inherited liver diseases (ILD). Several aspects can actually limit the clinical use of hepatocyte transplantation such as poor in vitro amplification, limited engraftment of transplanted hepatocytes in vivo, and the necessity for immune suppression (allogenic graft). Furthermore, relevant ILD-patients-specific models of hepatocytes would strongly enhance our knowledge of the pathophysiological mechanism responsible for ILD. In this project, we propose to generate induced pluripotent stem cells (iPSCs) from patients with primary hyperoxaluria type-1 (PH1). PH1 is an inherited disorder due alanine-glyoxylateamino transferase (AGT) deficiency and characterized by overproduction of oxalate by the liver leading to sever nephrocalcinosis, nephrolithiasis and end-stage renal failure. PH1-iPSCs-derived hepatocytes would represent faithfully models to support pathophysiological studies and therapeutic drug screening. We will also evaluate a targeted gene therapy approach in PH1-iPSCs-derived hepatocytes using TALENmediated gene correction at the endogenous human AGXT locus. This strategy would offer a safe and broad genetic correction together with physiological regulation of the therapeutic transgene. A similar approach is considered for acute hepatic porphyrias to develop patient-specific hepatocytes as models for porphyrinogenic drug screening. Our goal is to improve the development of iPSCs-derived hepatocytes as valuable models of ILD and develop new therapeutic approaches in regenerative medicine. Molecular targets and gene therapy of pancreas adenocarcinoma Pancreas cancer is among the 10 most common cancers and is the 4th cause of cancer death in occidental countries. Ductal pancreas adenocarcinoma is by far the most deadly since its diagnosis is difficult. Indeed, it lacks early and specific clinical features, and there is also a lack of biological markers that can be used for prevention or early detection. Thus, only few patients can benefit from a curative surgery. Other treatments are limited since this cancer is very much radio- and chemo-resistant. A major focus in research in this field deals in the understanding of the molecular mechanisms involved in tumor development or aggressiveness, with the aim of finding new targets. Alternately, one could target genes known to be specifically deregulated in this disease, in order to slow down tumor progression, or induce tumor cell death. Within this frame, we develop several projects: (1) is the FGFR3 receptor a possible target to control pancreas adenocarcinoma progression, (2) can we use targeted gene therapy against this disease, (3) can we use an association of several natural products with anti-cancer properties in order to reduce the progression of this cancer? Leukemic hematopoiesis (INSERM U1035) www.u1035.u-bordeaux2.fr François-Xavier Mahon Chronic myeloid leukemia We study chronic myeloid leukemia (CML: www.lmc-cml.org) as a model disease. This hematologic malignancy is characterized by a marker allowing to recognize leukemic cells. This marker, the Philadelphia chromosome, has a molecular equivalent, the BCR-ABL gene. The chimeric BCR-ABL protein has a deregulated tyrosine kinase (TK) activity. This TK is the “engine” of leukemic cells as it activates proliferation, antiapoptotic pathways and genetic instability. This hematologic malignancy has greatly contributed to the advent of targeted therapies and our team has contributed to the pre-clinical and clinical development of an original drug, STI571, better known today as imatinib (or Glivec°). It became the leader of a new class of drugs known as TK inhibitors (TKI). We have shown in vitro and in vivo the emergence of resistances that led the pharmaceutical industry to develop 2nd and 3rd generation TKIs on which we are now focusing our research. One of the key questions nowadays is more the persistence of leukemic cells than the resistance. Indeed a proportion of tumor cells, likely the more immature, are persisting despite a long-term treatment. We are thus investigating the molecular mechanism that underlie oncogene independence or the cooperation with other kinases. Other myeloid malignancies - Clinical biology of myeloproliferative syndromes (MPS): within european and international networks (European Leukemia Net, MPN&MPNreuronet), we participate to the collaborative efforts aiming at developing and standardizing tests for the detection and quantification of mutations found in SMP (JAK2V617F, exon 12, MPLW515, PDGFR) or related diseases (hereditary erythrocytosis and thrombocytosis). We also characterize the functional consequences of genetic alterations that we find - Pathogenesis of des myeloid malignancies: this research is also in close link with the clinic. We investigate how genetic/cytogenetic alterations participate to leukemogenesis. We work nowadays especially on two models: 1) we have recently described an acute myeloid leukemia characterized by a fusion gene MYB-GATA1 that defines a new cytogenetic entity, and are refining the functional characterization of the fusion gene and its relationship with basophil hematopoiesis. 2) mixed myeloproliferative and myelodysplastic syndromes, especially atypical CML, which pathophysiology is poorly understood. We are especially interested in expression and epigenetic regulation of micro-ARN in this model. • Research team François-Xavier MAHON, PU-PH Chercheurs et Enseignant-chercheurs Françis BELLOC, Ingénieur, CHU de Bordeaux, HDR Bruno CARDINAUD, MC, Institut Polytechnique de Bordeaux Francis Lacombe, PH, CHU de Bordeaux Eric LIPPERT, MCU-PH Jean-Max PASQUET, CR1 INSERM Arnaud PIGNEUX, PH, CHU de Bordeaux Béatrice TURCQ, CR1 CNRS, HDR Stéphanie DULUCQ, PH, CHU de Bordeaux Personnels ITA Valérie PROUZET-MAULEON, IE Bordeaux 2 Valérie LAGARDE, Technicienne Bordeaux 2 Post-Doctorant Romain GIOIA, CDD INCA Doctorantes Kelly AIRIAU Marina JOSSELIN • Selected publications Gioia R, Leroy C, Drullion C, Lagarde V, Etienne G, Dulucq S, Lippert E, Roche S, Mahon FX, Pasquet JM. Quantitative phosphoproteomics revealed interplay between Syk and Lyn in the resistance to nilotinib in chronic myeloid leukemia cells.Blood. 2011 Aug 25;118(8):221121. Rea D, Etienne G, Nicolini F, ConyMakhoul P, Johnson-Ansah H, Legros L, Huguet F, Tulliez M, Gardembas M, Bouabdallah K, Rousselot P, Cayuela JM, Guilhot F, Mahon FX. First-line imatinib mesylate in patients with newly diagnosed accelerated phase-chronic myeloid leukemia. Leukemia. 2012 Mar 30. doi: 10.1038/leu.2012.92 CANCER │ 17 Dermatology group (INSERM U1035) www.u1035.u-bordeaux2.fr • www.maladiesrarespeau.fr Alain Taieb • Research team Alain TAIEB, PU-PH, HDR Annie BERARD, MCU-PH, HDR Katia BONIFACE, MC Muriel CARIO-ANDRE, Ingénieur, CHU de Bordeaux, HDR Vincent CASOLI, PU-PH, HDR Khaled EZZEDINE, PH, CHU de Bordeaux Thomas JOUARY, PH, CHU de Bordeaux Frédéric MAZURIER, DR2 INSERM Djavad MOSSALAYI, PU, HDR Daniel MOYNET, MC Hamid REZVANI, CR2 INSERM Isabelle LAMRISSI-GARCIA, Technicienne Bordeaux 2 Denis THIOLAT, AGT Bordeaux 2 Catherine PAIN, Technicienne CDI contrat privé Walid MAHFOUF, IE CDD Post-Doctorants François Moisan Houssam Raad Martin SERRANO-SANCHEZ Doctorants Mohsen HASSEINI Sorilla PREY Abir ZEBIAN • Selected publications XPC silencing in normal human keratinocytes triggers metabolic alterations that drive the formation of squamous cell carcinomas.Rezvani HR, Kim AL, Rossignol R, Ali N, Daly M, Mahfouf W, Bellance N, Taïeb A, de Verneuil H, Mazurier F, Bickers DR. J Clin Invest. 2011 Jan;121(1):195-211. Rezvani HR, Ali N, Serrano-Sanchez M, Dubus P, Varon C, Ged C, Pain C, Cario-André M, Seneschal J, Taïeb A, de Verneuil H, Mazurier F. Loss of epidermal hypoxia-inducible factor1α accelerates epidermal aging and affects re-epithelialization in human and mouse. J Cell Sci. 2011 Dec 15;124(Pt 24):4172-83 18 │CANCER Relationships between genomic mutations, alteration of energy metabolism and increase in reactive oxygen species during cancer initiation Key words: Xeroderma pigmentosum, DNA repair, Warburg effect, skin cancers Study of the role of HIF factors in hematopoietic and epidermic cells Key words: Hypoxia, HIF, hematopoiesis, epidermis, aging, cancer Beta-adrenergic signalization and angiogenesis Key words: propranolol, hemangioma, vasculogenesis, antiangiogenic therapy Vitiligo pathophysiology Key words: Vitiligo, melanocyte, dermis, paracrine factors, inflammation A description of our projects can be found on our website: www.u1035.u-bordeaux2.fr ER stress & Cancer (INSERM U1053) www.gref-bordeaux.fr/fr/ER_stress Eric Chevet The «ER stress and cancer» team focuses on the understanding of adpatation mechanisms set in place by the normal and pathological cells to cope with their environment. The team is particularly interested in the role of the first sub-cellular compartment of the secretory pathway, the endoplasmic reticulum (ER). This compartment, which can represent up to 50% of the total cellular membranes, plays instrumental roles in the maintenance of calcium, lipides, and protein homeostasis. • Research team Eric Chevet, DR2 S Taouji, IE Inserm N Dejeans, post doc S Lhomond, Thèse When ER homeostasis is perturbed, the imbalance is sensed in the lumen of this compartment and transmitted to the cytosol and the nucleus. Three sensors have been identified thus far and named protein kinase RNA-like endoplasmic reticulum kinase (PERK), Activating Transcription Factor 6 (ATF6) and Inositol Requiring Enzyme 1 (IRE1). The signalling pathways activated downstream of these three ER stress sensors are collectively called the Unfolded Protein Response (UPR). The UPR aims at restoring ER homeostasis but if this fails, it triggers programmed cell death. The UPR is activated in numerous pathologies including diabetes, degenerative disorders ro cancer. Our team focuses on elucidating the molecular mechanisms of ER stress in cancers (the models studied in the laboratory are glioblastoma, hepatocellular carcinoma and cholangiocarcinoma). We demonstrated that the IRE1 arm of the UPR significantly contributes to tumor growth in vitro and in vivo through the activation of its cytosolic endoribonuclease activity. The currrent projects aim at dissecting IRE1 signalling networks in cancer and identifying natural and synthetic molecules susceptible to alter IRE1 functions. On a longer term, the experimental strategies currently developed in the laboratory will be applied to the other ER stress sensors PERK and ATF6. • Selected publications Huber AL, Lebeau J, Guillaumot P, Pétrilli V, Malek M, Chilloux J, Fauvet F, Payen L, Kfoury A, Renno T, Chevet E, Manié SN. p58(IPK)-Mediated Attenuation of the Proapoptotic PERK-CHOP Pathway Allows Malignant Progression upon Low Glucose. Mol Cell. 2013 Dejeans N, Pluquet O, Lhomond S, Grise F, Bouchecareilh M, Juin A, Meynard-Cadars M, Bidaud-Meynard A, Gentil C, Moreau V, Saltel F, Chevet E. Autocrine control of glioma cells adhesion/ migration through Inositol Requiring enzyme 1α (IRE1α)mediated cleavage of Secreted Protein Acidic Rich in Cysteine (SPARC) mRNA. J Cell Sci. 2012 125:4278-87 Guichard C, Amaddeo G, Imbeaud S, Ladeiro Y, Pelletier L, Ben Maad I, Calderaro J, Bioulac-Sage P, Letexier M, Degos F, Clément B, Balabaud C, Chevet E, Laurent A, Couchy G, Letouzé E, Calvo F, Zucman-Rossi J. Integrated analysis of somatic mutations and focal copy-number changes identifies key genes and pathways in hepatocellular carcinoma. Nature Genetics, 2012;44(6):694-8 Yi P, Higa A, Taouji S, Bexiga MG Marza E, Arma D, Castain C Le Bail B, Simpson JC, Rosenbaum J, Balabaud C, Bioulac-Sage P, Blanc JF, Chevet E. Sorafenib–mediated targeting of the AAA+ ATPase p97/VCP leads to disruption of the secretory pathway, endoplasmic reticulum stress and hepatocellular cancer cell death. Mol Cancer Ther 2012 11:2610-20 Bouchecareilh M, Higa A, Fribourg S, Moenner M, Chevet E. Peptides derived from the bifunctional kinase/RNase enzyme IRE1{alpha} modulate IRE1{alpha} activity and protect cells from endoplasmic reticulum stress. FASEB J. 2011 25: 3115-29. Yi P, Thang Nguyên D, Higa-Nishiyama A, Auguste P, Bouchecareilh M, Dominguez M, Bielmann R, Palcy S, Liu JF and Chevet E. MAPK scaffolding by the Bcl2-inhibitor of transcription 1 (BIT1) in the Golgi apparatus modulates stress resistance. J Cell Science 2010; 23 :1060-72 CANCER │ 19 Post-transcriptional regulation of genes, microRNAs and liver cancer (INSERM U1053) www.gref-bordeaux.fr/en/microRNA Christophe Grosset • Research team Christophe GROSSET, CR1 INSERM Francis SAGLIOCCO, Assistant Professor, Bordeaux Segalen University Sarah LESJEAN, AI INSERM Flora Cartier, Post-doc • Selected publications 1- Maurel, M. et al. MicroRNA-1291mediated silencing of IRE1α enhances Glypican-3 expression. RNA, 2013, 19(6): 778-788. 2- Maurel, M. et al. A functional screening identifies five miRNAs controlling Glypican-3: Role of miR1271 down-regulation in hepatocellular carcinoma. Hepatology, 2013, 57 (1): 195-204. 3- Jalvy-Delvaille, S. et al. Molecular basis of differential target regulation by miR-96 and miR-182. The Glypican-3 as a model. Nucl Acids Res, 2012, 40 (3), 1356-1365. 4- Simon, D. et al. A mutation in the 3’UTR of the HDAC6 gene abolishing the post-transcriptional regulation mediated by hsa-miR-433 is linked to a new form of dominant X-linked chondrodysplasia, Hum Mol Genet, 2010, 19, 2015-2027. 5- Laloo, B., et al. Analysis of posttranscriptional regulations by a functional, integrated, and quantitative method. Mol and Cel Prot, 2009, 8(8):1777-1788. My team works on the post-transcriptional regulation of genes by microRNAs (miRNAs), small non-coding RNAs which control translation and messenger RNA (mRNA) stability. Our favourite gene is the Glypican-3 (GPC3), a gene overexpressed in liver cancer and which participates in liver tumorigenesis through the Wnt/β-catenin pathway. We study the miRNAs regulating GPC3 expression and evaluate the role played by these regulations in the growth of cancerous hepatic cells. We developed a system, named Dual-Fluorescence-FunREG (Figure 1), which allows the screening of miRNA (and siRNA) libraries in human cells and the identification of miRNAs functionally active on a specific gene. Figure 1: Principle of the DF-FunREG screening methodology. Target cells expressing the Reference «Tomato» and Test «GFP + 3’UTR of interest» transgenes are transfected by each miRNA from the library. The miRNAs inducing a significant variation of the GFP/Tomato ratio compared to the control RNA (reference value « A ») are selected as «hits». PRO: promoter EF1-alpha-long (Ref. 2). Using Dual-Fluorescence-FunREG, we identified 5 miRNAs regulating positively or negatively GPC3 expression in tumoral hepatic cells through its 3’ untranslated region (Figure 2; Ref. 1 to 3). MiR-96 and miR-1271 down-regulated GPC3 expression through a direct microRNA:3’UTR recognition process. The 3 others, miR-129-1-3p, miR-1291 and miR1303, enhanced GPC3 expression, likely by an indirect mechanism. This assumption was further demonstrated with miR-1291 which favours GPC3 expression by inhibiting the expression of the endoplasmic reticulum (ER)resident stress sensor IRE1α through a specific site located in its 5′ UTR. Finally IRE1α cleaves GPC3 mRNA at a 3′ UTR consensus site, thereby prompting its decay and GPC3 downregulation. Figure 2: Summary of GPC3 3’UTRassociated post-transcriptional regulations mediated by 5 miRNAs and the endoribonuclease IRE1α. Red line: negative effect. Green arrow: positive (and likely indirect) effect (Ref. 1 to 3). In conclusion, our data show that GPC3 expression is regulated by several miRNAs and the endoribonuclease IRE1α (Figure 2) illustrating the fascinating notions of collaborative post-transcriptional gene regulation network. Finally, the altered expression of some of these factors (especially miR-1271) in liver cancer favours GPC3 expression and thus, the expansion of cancerous liver cells. Therefore, these factors constitute bona fide molecular targets in liver cancer. 20 │CANCER Cytoskeleton & Cancer group (INSERM U1053) www.gref-bordeaux.fr/en/cytoSk-cancer-group Violaine Moreau et Frédéric Saltel Reorganization of the actin cytoskeleton is important for cell migration, cell shape change, and interactions with other cells and the environment. Abnormal cell migration and invasion is a characteristic of malignant cancer cells and is one component of metastasis, the major clinical problem in cancer. Consequently, alterations in cytoskeletal signalling pathways are increasingly being recognized as important for cancer invasion and metastasis. Our group uses a wide range of biochemical, cell biological methods and animal models to study how actin cytoskeleton is regulated and involved in hepatocellular carcinoma cell invasion. We mainly developed two axes: Role of Rho GTPases in the development of hepatocellular carcinoma (Violaine Moreau) Our recent work focused on the atypical Rho GTPase, RhoE/Rnd3. Using patient samples and cultured cells, we have documented the frequent down-regulation of RhoE/Rnd3 in hepatocellular carcinoma (HCC) and shown that it behaves as a suppressor of invasion (Hepatology, 2012). Left-hand side: Phylogenetic tree of the Rho GTPase family (from Grise et al., BBA-Reviews in Cancer, 2009). Rnd3/RhoE is shown in red. Right-hand side: Rnd3 is down-regulated in tumor liver. Immunohistochemistry of Rnd3 in HCC versus cirrhotic tissue. Tissues were stained with anti-Rnd3 antibody. Involvement of invadosomes in hepatocellular carcinoma (Frédéric Saltel) Invadosomes are F-actin structures involved in extracellular matrix degradation. Our last study established the existence of a new linear organization of invadosomes specifically induced by type I collagen fibrils (MBoC, 2012). This physiological organization of type I collagen is present in liver endothelial and hepatic cancer cells. Our future objective will be to determine the impact of linear invadosomes in HCC cell invasion. • Research team Violaine MOREAU, CR1 INSERM Frédéric SALTEL, CR1 INSERM Valérie LAGREE, MCU Lisa PAYSAN, Thèse Julie DI MARTINO, Thèse Caroline GEST, Post-doc • Selected publications Bidaud-Meynard A*, Arma D*, Taouji S*, Laguerre M, Dessolin J, Rosenbaum J, Chevet E# & Moreau V#. A novel smallmolecule screening strategy identifies mitoxantrone as a RhoGTPase inhibitor. Biochem. J., 2013 Feb 15;450(1):5562. Juin A, Planus E, Guillemot F, Horakova P, Albiges-Rizo C, Génot E, Rosenbaum J, Moreau V, Saltel F. Extracellular matrix rigidity controls podosome induction in microvascular endothelial cells. Biol Cell. 2013 Jan;105(1):46-57. Grise F*, Sena S*, Bidaud-Meynard A, Baud J, Hiriart J-B, Makki K, DugotSenant N, Staedel C, Bioulac-Sage P, Zucman-Rossi J, Rosenbaum J & Moreau V. Rnd3/RhoE is downregulated in hepatocellular carcinoma and involved in cellular invasion. Hepatology 2012, 55:1766-1775. Juin A, Billottet C*, Moreau V*, Destaing O, Albiges-Rizo C, Rosenbaum J, Génot E# & Saltel F#. Physiological type I collagen organization induces the formation of a novel class of linear invadosomes. Mol. Biol. Cell 2012, 23(2):297-309. Confocal images of the formation of linear invadosomes induced by type I collagen fibrils (in red), and visualized using the staining of a specific marker (Tks5 in green). These linear invadosomes are able to promote degradation of the gelatin (in grey) underneath, the hallmark of invadosomes. CANCER │ 21 Liver cancer (INSERM U1035) www.gref-bordeaux.fr/en/liver-cancer Jean Rosenbaum • Research team Jean Rosenbaum, DR1 INSERM Patrick Lestienne, DR2 INSERM Paulette Bioulac-Sage, PU-PH Jean-Frédéric Blanc, PU-PH Aksam Merched, professor Véronique Neaud, adjoint technique UBS Nathalie Allain-Courtois, technicienne UBS Anne-Aurélie Raymond, post-doc Samira Benhamouche, post-doc Hepatocellular carcinoma is the most frequent primary liver cancer. It is one of the most frequent and deadly cancers worldwide. We have identified the overexpression in HCC of Reptin and Pontin, two members of the AAA+ family, and shown that were important for HCC progression. We aim at better understanding their mechanisms of action and target them for therapy. We have notably generated a new conditional knock-out mouse for Reptin that will allow in-depth analysis of its role in a relevant setting. Senescent tumor cells with senescenceassociated heterochromatin foci following Reptin silencing A B C D Identification of Small molecule inhibitors of Pontin ATPase activity • Selected publications 1.Grigoletto A, Neaud V, Allain-Courtois N, Lestienne P, Rosenbaum J. The ATPase activity of Reptin is required for its effects on tumor cell growth and viability in hepatocellular carcinoma. Mol Cancer Res, 2013, 11(2) : 133–9 2.Guichard C, Amaddeo G, Imbeaud S, Ladeiro Y, Pelletier L, Ben Maad I, Calderaro J, Bioulac-Sage P, Letexier M, Degos F, Clément B, Balabaud C, Chevet E, Laurent A, Couchy G, Letouzé E, Calvo F, Zucman-Rossi J. Integrated analysis of somatic mutations and focal copynumber changes identifies key genes and pathways in hepatocellular carcinoma. Nature Genetics, 2012, May 6;44(6):694-8 3.Ménard L, Taras D, Grigoletto A, Haurie V, Nicou A, Dugot-Senant N, Costet P, Rousseau B, Rosenbaum J. In vivo silencing of Reptin blocks the progression of human hepatocellular carcinoma in xenografts and is associated 22 │CANCER with replicative senescence. J Hepatol 2010, 52: 681-9 4.Haurie V, Ménard L, Nicou A, Touriol C, Metzler P, Fernandez J, Taras D, Lestienne P Balabaud C, BioulacSage P, Prats H, Zucman-Rossi J, Rosenbaum J. The ATPase Pontin is overexpressed in hepatocellular carcinoma and co-regulated with Reptin through a new post-translational mechanism. Hepatology 2009, 50 : 1871-1883. 5.Rousseau B, Ménard L, Haurie V, Taras D, Blanc JF, Moreau-Gaudry F, Metzler P, Hugues M, Boyault S, Lemière S, Canron X, Costet P, Cole M, Balabaud C, Bioulac-Sage P, Zucman-Rossi J, Rosenbaum J. Overexpression and role of the ATPase and putative DNA helicase RuvB-like 2 in human hepatocellular carcinoma. Hepatology 2007, 46 : 1108-18. immunology microbiology Intracellular dynamic of subviral structures (CNRS UMR 5234) www.mfp.cnrs.fr/mfp/team_dissv_en.php équipe FRM Michael Kann and Harald Wodrich ● HBV: the human hepatitis B virus is a major human pathogen responsible for circa 1 Mio death per year. Our research is focused on 1) the intracytosolic trafficking of the capsid, which surrounds the viral genome towards the nucleus, 2) the still unknown passage – for all viruses – from the microtubules to the nuclear pore and 3) the subsequent steps. These comprise the crossing of the viral genome inside the capsid through the nuclear pore (Fig. 1), the liberation of the viral genome from the capsid and the intranuclear genome conversion/repair. The investigations are based on microscopical Fig. 1. HBV capsids at the techniques for localization and on biochemical cyto-plasmic and nuclear methods for adjacent investigations. The project was side of the nuclear pore. electron recently expanded to the naturally polymorphism of Transmission HBV in collaboration with the Research Centre for microscopy. From Kann & Epidemiology and Biostatistics, Bordeaux (ISPED). Panté, MBC, 2002. ● Parvoviruses: recent investigations showed that parvoviruses enter the nucleus of resting cells but circumvent the passage through the nuclear pore. Our recent investigations using time lapse microscopy showed that parvoviruses dock to the nuclear pore and induce disintegration of the nuclear membrane. This process occurred even in the absence of cytosol and requires some key enzymes of mitosis. The underlying mechanism of how parvoviruses cross the nuclear membrane are thus of high interest in basic science in order to understand the activating intranuclear cascades. However the impact of this topic is not restricted to the gain of basic knowledge but has applied consequences as these viruses are frequently used candidates in cancer therapy and are moreover the vector for the first licensed drug in gene therapy world-wide. ● Adenoviruses: the research focuses on the mechanism of endosomal escape, cytosolic trafficking and nuclear import. These investigations are linked to adenoviral application in gene therapy, vaccination and cancer therapy. Our research has shown that these pathways require the interaction of the capsid protein VI with the cellular ubiquitin/proteasome system. Protein VI also mediates endosomal escape, which triggers innate immunity, thus causing Ad mediated inflammation. Work in progress investigates protein VI function in pathogenesis, intracellular trafficking and cell activation related to post-translational modifications with ubiquitin and SUMO. The project includes biochemical assays and cell based systems as well as advanced microscopic techniques. For a better understanding of adenoviral pathogenesis, protein VI sequences from patients with adenovirus infections are investigated for their role in disease development. Further analysis on adenoviruses is performed in collaboration with the hospital analysing the impact of adenoviral variability on different clinical parameters. Fig. 2. Top: Ad capsids (green signal) separate from protein VI (red signal) and accumulate at the microtubule organizing centre 45 min after infection. Bottom panel: Ad capsids with mutated protein VI incapable of binding to cellular ubiquitin ligases remain with the capsid (yellow signal) and show altered intracellular trafficking (Wodrich et al. PLoS Pathogens 2010) • Research team Marie-Edith LAFON (MD-PhD) Christian Cazenave (scientist - CR1) Fabienne Rayné (scientist – MCU) Aurélia Cassany (postdoc) Tetsuro Komatsu (postdoc) Jessica Raque (technician) Cindy Aknin (technician) Muriel Faure della Corte (technician) Quentin Osseman (PhD student) Sisley Austin (PhD student) Remi Vaillant (PhD student in collaboration with the Heinrich-Pette Institut, Hamburg, Gemany) Kenza Snoussi (PhD student in collaboration with the University of Tsukuba, Japan) Somar Kassab (MD-PhD student) • Selected publications Schreiner S,Martinez R, Groitl P, Rayne F, Vaillant R, Wimmer P, Bossis G, Sternsdorf T, Marcinowski L, Ruzsics Z, Dobner T, Wodrich H. Transcriptional activation of the adenoviral genome is mediated by capsid protein VI.. PLoS Pathog. 2012 Feb;8(2):e1002549 Schmitz A, Schwarz A, Foss M, Zhou L, Rabe B, Hoellenriegel J, Stoeber M, Panté N, Kann M. Nucleoporin 153 arrests the nuclear import of hepatitis B virus capsids in the nuclear basket. PLoS Pathog. 2010 Jan 29;6(1):e1000741 Wodrich H, Henaff D, Jammart B, Segura-Morales C, Seelmeir S, Coux O, Ruzsics Z, Wiethoff CM, Kremer EJ. A capsid-encoded PPxY-motif facilitates adenovirus entry. PLoS Pathog. 2010 Mar 19;6(3):e1000808 (must read Faculty of 1000) Rabe B, Delaleau M, Bischof A, Foss M, Sominskaya I, Pumpens P, Cazenave C, Castroviejo M,Kann M. Nuclear entry of hepatitis B virus capsids involves disintegration to protein dimers followed by nuclear reassociation to capsids. PLoS Pathog. 2009 Aug;5(8):e1000563 immunology-microbiology │ 25 African Trypanosoma virulence factor and pathogenicity (CNRS UMR 5234) www.mcmp.aquitaine.cnrs.fr/mfp/ Théo Baltz and Virginie Coustou • Research team Zeinab AMMAR (PhD student) Corinne ASENCIO (AI) Nicolas BITEAU (IR) Virginie COUSTOU-LINARES (CR1) Julien IZOTTE (AI) Davita PILLAY (Post-doctorante) Nicolas PLAZOLLES (Tcn) Loïc RIVIERE (MCU) Magali THONNUS (Tcn) • Selected publications Guegan F, Plazolles N, Baltz T, Coustou V. Erythrophagocytosis of desialylated red blood cells is responsible for anaemia during Trypanosoma vivax infection. Cell Microbiol. 2013 Feb 20. doi: 10.1111/cmi.12123. [Epub ahead of print] Coustou V, Plazolles N, Guegan F, Baltz T. Sialidases play a key role in infection and anaemia in Trypanosoma congolense animal trypanosomiasis. Cell Microbiol. 2012 Mar;14(3):431-45. Epub 2012 Feb 13. Coustou V, Guegan F, Plazolles N, Baltz T. Complete in vitro life cycle of Trypanosoma congolense: development of genetic tools. PLoS Negl Trop Dis. 2010 Mar 2;4(3):e618. Giroud C, Ottones F, Coustou V, Dacheux D, Biteau N, Miezan B, Van Reet N, Carrington M, Doua F, Baltz T. Murine Models for Trypanosoma brucei gambiense disease progression--from silent to chronic infections and early brain tropism. PLoS Negl Trop Dis. 2009 Sep 1;3(9):e509 Virulence and pathogenesis factors of African Trypanosomes. T.b. gambiense is responsible for more than 90% of reported cases of human sleeping sickness in West and Central Africa. Isolation by in vitro culture of different T. b. gambiense field isolates directly from the CSF of patients allowed the group to develop murine models with chronic, sub-chronic and silent infections, mimicking the situation in the field. Engineering of a T. b. gambiense isolate to express Renilla Luciferase revealed an unexpected early tropism not only for the brain but also for other organs such as the spleen and lungs. These murine models, combined with bioluminescence and immune-histochemistry, provide new insights into disease progression and could possibly reveal new mechanisms involved in host-parasite interactions (Fig 6, Giroud et al., PLoS Negl Trop Dis 2009). T. congolense is the main causative agent of animal trypanosomiasis in Africa. Pathogenesis is mainly due to anaemia The group succeeded in producing long-term cultures of all the developmental stages and to finally complete the whole lifecycle in vitro. This improved model offers the opportunity to conduct phenotype analyses of genetically modified strains throughout the in vitro lifecycle and also during experimental infections.(Fig 7, Coustou et al., PLoS Negl Trop Dis 2010). Ongoing research focuses on the identification and characterisation of novel pathogenic factors, in terms of their protective potential, specifically in the context of an “anti-anaemia” vaccine. Several factors will be expressed as recombinant proteins and their purifications done in collaboration with the platform of the unit. Fig. 1: Bioluminescence analysis of mice infected with the silent T. b. gambiense isolate and of their organs (1, uninfected; 2, infected). Fig. 2: In vitro culture system for T. congolense. Insect stages (PCF, EMF, MCF) are represented on the left as individual or adherent (colonies) cells. The mammalian stage (BSF) on the right is represented in blood or on BAE 26 │Immunology-microbiology Trypanosome cytoskeleton biogenesis (CNRS UMR 5234) http://www.mfp.cnrs.fr/mfp/team_bct_en.php Derrick Robinson Trypanosoma brucei is a flagellated protozoan that is the causal agent for African sleeping sickness. It is used in studies of basic parasite biology for health perspectives and also as a model organism to study numerous biological phenomena such as characterization of gene expression, cell cycle analysis, protein trafficking, glycobiology and cytoskeleton biogenesis. In order to obtain a better understanding of flagella and cell cytoskeleton biogenesis in general, our lab’s research have focused on immunological and proteomic analysis of minor flagellar proteins of this model organism. Subsequently, our group has made a panel of polyclonal / monoclonal antibodies against minor cytoskeleton proteins. We have also used bioinformatics approaches to identify the biochemical means for basal body segregation in T. brucei. We also focus on novel proteins and structures including uncharacterized basal body, spindle proteins, and flagellar proteins. We have recently identified a microtubule-associated protein, TbSAXO, involved in flagellum motility in the parasite. This protein belongs to a family of proteins involved in the stabilization of microtubules from in ciliated and/or flagellated organisms from protozoa to mammals. Their role in the cilia/flagella function is under study. Currently, our main focus has centered on a component of a previously unknown collar-like structure localized at the point of emergence the flagellum from the cell. Using western blots from two-dimensional gels and mass spectrometry we identified a 67kDa protein. The gene encoding the 67kDa protein was cloned, histidine-tagged and the protein affinity purified. Finally mouse polyclonals/monoclonal were raised against this protein. Using GFP and Immunofluorescence studies show that this protein is a component of a collar-like structure located at the site where the flagellum exits the cell. This collar is also a component of the flagellar pocket (FP). The FP is the sole organelle responsible for endo and exocytosis in this these cells (figure 1). We have named the 67kDa protein BILBO1. BILBO1 is essential for parasite survival. Because BILBO1 is essential for cell survival we have an excellent subject for further study of flagellar pocket biogenesis. • Research team Derrick ROBINSON DR2 CNRS. Mélanie BONHIVERS CR1 CNRS. Denis DACHEUX-DESCHAMPS (MCU) BX2. Benoit ROGER (MCU BX1). Nicolas LANDREIN (TCN CNRS) Elodie BERDANCE (PhD Student). • Selected publications Dacheux D, Landrein N, Thonnus M, Gilbert G, Sahin A, Wodrich H, Robinson DR, Bonhivers M. A MAP6-related protein is present in protozoa and is involved in flagellum motility. PLoS One. 2012;7(2):e31344 Joice AC, Lyda TL, Sayce AC, Verplaetse E, Morris MT, Michels PA, Robinson DR, Morris JC. Extra-glycosomal localisation of Trypanosoma brucei hexokinase 2. Int J Parasitol. 2012 Apr;42(4):401-9. May SF, Peacock L, Almeida Costa CI, Gibson WC, Tetley L, Robinson DR, Hammarton TC. The Trypanosoma brucei AIR9-like protein is cytoskeleton-associated and is required for nucleus positioning and accurate cleavage furrow placement. Mol Microbiol. 2012 Apr;84(1):77-92 Giroud C, Ottones F, Coustou V, Dacheux D, Biteau N, Miezan B, Van Reet N, Carrington M, Doua F, Baltz T. Murine Models for Trypanosoma brucei gambiense disease progression from silent to chronic infections and early brain tropism. PLoS Negl Trop Dis. 2009 Sep 1;3(9):e509 Absalon S, Blisnick T, Bonhivers M, Kohl L, Cayet N, Toutirais G, Buisson J, Robinson D, Bastin P. Flagellum elongation is required for correct structure, orientation and function of the flagellar pocket in Trypanosoma brucei. J Cell Sci. 2008 Nov 15;121(Pt 22):3704-16 Bonhivers, M., Nowacki, S., Landrein, N. and Robinson, D. R. Biogenesis of the trypanosome endo-exocytotic organelle is cytoskeleton mediated. PLoS PLoS Biol 6, e105. Bonhivers M, Landrein N, Decossas M, Robinson DR. A monoclonal antibody marker for the exclusion-zone filaments of Trypanosoma brucei.Parasit Vectors. 2008 Jul 10;1(1):21. immunology-microbiology │ 27 Candida and Pathogenicity (CNRS UMR 5234) www.mcmp.aquitaine.cnrs.fr/mfp/team_pc_en.php Thierry Noël • Research team Accoceberry Isabelle, MCU-PH Albert Olivier, AHU Dementhon Karine, MCF Fitton-Ouhabi valérie, ADT Gabriel Frédéric, PHC Noël Thierry, PR, group leader Sabra Ayman, Doctorant • Selected publications Dementhon, K., El-Kirat-Chatel, S., and Noel, T. (2012). Development of an in vitro model for the multi-parametric quantification of the cellular interactions between Candida yeasts and phagocytes. PLoS ONE, 7(3):e32621. PMID 22479332 Noel, T. (2012). The cellular and molecular defense mechanisms of the Candida yeasts against aztole antifungal drugs. Journal of Medical Mycology, 22: 173-178. ISSN 11565233, 10.1016/j.mycmed.2012.04.004 Gabriel, F., Noel, T., and Accoceberry, I. (2011). Lindnera (Pichia) fabianii blood infection after mesenteric ischemia. Medical Mycology 50, 310-314. PMID 21671831. El-Kirat-Chatel, S., Dementhon, K., and Noel, T. (2011). A two-step cloning-free PCR-based method for the deletion of genes in the opportunistic pathogenic yeast Candida lusitaniae. Yeast 28, 321-330. PMID 21456057 Gabriel, F., Noel, T., and Accoceberry, I. (2011). Fatal invasive trichosporonosis due to Trichosporon loubieri in a patient with T-lymphoblastic lymphoma. Medical Mycology 49, 306-310. PMID 20950223 Patent Gabriel F, Accoceberry I, Bessoule J-J, Manon S, Noël T inventors; Université de Bordeaux, Centre National de la Recherche Scientifique (CNRS), Centre Hospitalier Universitaire (CHU) de Bordeaux, assignee. Novel Beta-oxidation pathway and hemiascomycetes yeast mutants. European Patent EP11159920.5, (2011, March 25). 28 │immunologY-microbiologY Fungi of medical interest have become the first cause of opportunistic parasitic diseases in industrialized countries, mainly because of the expanding immunocompromised population. Our main research topic focuses on the role of fungal lipid signalling and fungal lipid metabolism during the first stage of the infectious process, when fungal cells meet the innate immune cells of the host, macrophages and neutrophils. We are also interested by specific lipid biosynthetic pathways, which are important targets for antifungals, and by lipid membrane transporters which allow fungal cells to resist to antifungal therapy. Our team works preferentially with non-albicans Candida species, notably Candida lusitaniae that we developed as a model organism for several years, and which is now accessible to both formal and reverse genetics. BASIC RESEARCH A – Cellular and molecular characterization of the interactions between Candida and phagocytic cells We developed a new in vitro model for a multi-parameter characterization of interaction of Candida fungal cells with murine macrophages and human neutrophils (Dementhon et al, 2012). This model is based on the use of combined microscopy, fluorometry, flow cytometry and viability assays, and that of fluorochromes specific to phagocytes and yeasts, and is amenable to the high throughput screening of mutant strains. This model allows us to address the molecular mechanisms involved in yeast response to macrophages versus neutrophils, either by the screening of libraries of random tagged mutants of Candida, or by inactivating target genes involved in the biosynthesis of oxygenated lipids. B – Role of the fungal lipid metabolism during the interaction Candida / macrophage We discovered novel pathways of fatty acid oxidation in the opportunistic pathogenic ascomycetous yeast C. lusitaniae (Gabriel et al, 2011, European Patent). Two of them are dependent on Fox2p, the multifunctional protein of the β-oxidation. The third one is peroxisomal, fox2p-independent, and is unknown so far in Fungi. Our aims are to characterize the peroxisomal fox2p-independent pathway of fatty acids catabolism, and to define the role of the fatty acids catabolism in the virulence of the Candida yeasts, notably when they survive to macrophages. C - Molecular characterization of antifungal resistance in C. lusitaniae. We demonstrated cross-resistance between flucytosine (5FC) and fluconazole (FLC) in several genetically unrelated clinical isolates of C. lusitaniae. Our data support the idea that 5FC behaves as a competitive inhibitor of the entry of fluconazole, which has never been characterized so far in fungi. We are investigating the membrane transporters involved in the cross-resistance between 5FC and FLC. CLINICAL INVESTIGATIONS – TRANSFER OF TECHNOLOGY Other domains of expertise in clinical and applied research : • Molecular identification and description of new emergent and rare opportunistic fungal species • Suceptibility testing of yeast and moulds to antifungals and to natural and synthetic molecules under development. Macrophage infected with Candida cells. Left: fluorescence panel showing a macrophage, with its membrane stained with APC-antiCD16 antibody (red) and its cyttoplasm with calcein (green), containing several calcofluorlabeled yeast cells (blue). Right: bright field. Variability, replication and mobility of viral and bacterial genomes (CNRS UMR 5234) www.mcmp.aquitaine.cnrs.fr/mfp/team_vrmg.php Marie-Line ANDREOLA, Michel VENTURA, Hervé FLEURY Our group is interested in the replication of human pathogens. Understanding of such mechanisms must lead to the development of new therapeutic approaches. Four principal projects are developed. The first project concerns the study of the Human Immunodeficiency Virus (HIV) DNA synthesis and integration mediated by the viral reverse transcriptase (RT) and integrase (IN). More recently, the study of the RNA dependent RNA polymerase (RdRp) of the hepatitis C virus (HCV) was developed as a new project of the laboratory. These studies allowed us to better understand the mechanisms involved in replication of the viral genomes. Furthermore the clinical studies performed in all around the world, mainly in South East of Asia and Africa, brought numerous informations on the HIV-1 variability, the impact on viral replication, and the resistance to therapeutic drugs. We designed biochemical and cellular models for the study of the interactions between enzymes involved in stabilization of the nucleic acids and/or interactions of the viral pathogens with potential cellular partners. The recent data that we obtained about the mobility of viral nucleic acids allowed us to analyze the mechanism of enzymes mediating the mobility of bacterial genes involved in antibiotic resistance (integrase/transposase). Our expertise in DNA polymerase characterization led us to original contributions to the following fields: • Reverse transcription initiation and HIV RT interactions with its substrates. • RNA synthesis initiation by HCV RdRp. • Processing and integration of HIV-1 DNA by viral integrase. • Involvement of a bacterial integrase (Int1) of class 1 integron and of a transposase (IS91 family) in the mobility of genes inducing resistance to antibiotics. A better knowledge of these recombination/transposition mechanisms should lead to design new therapeutic approaches against highly resistant bacterial strains. Also we developed in collaboration with chemists and microbiologists new specific inhibitors of HIV-1 RT and of HCV RdRp. A new antiviral strategy against RNA viruses has also been established. Three international patents have been approved related to these projects HCV replication cycle. • Research team Chercheurs, Enseignants-chercheurs Marie Line ANDREOLA (DR2) Corinne ARPIN (MCU-HC) Pantxika BELLECAVE (Post Doc) Mohamed BENLEULMI (Post Doc) Jean Luc BRUN (PU-PH) Véronique DUBOIS (MCU-PH) Michel DUPON (PU-PH) Hervé FLEURY (PU-PH) Isabelle GARRIGUE (MCU-PH) Cyril MASANTE (Post Doc) Didier NEAU (PU-PH) Vincent PARISSI (CR1) Claudine QUENTIN-NOURY ( PR1) Jean Marie RAGNAUD ( PU) Sandrine REIGADAS ( MEB) Ludivine SINZELLE (Post Doc) Françoise TESSIER (MCU) Jean François VELY (PU-PH) Michel VENTURA (DR2) ITA : Catherine ANDRE (ADT2P) Lucie BESNARD (IE CDD) Christina CALMELS (AI) Laure COULANGE-MAYONNOVE (ADT1) Jennifer PAPUCHON (Tce) Patricia PINSON (IE) Etudiants : Anais JASPART (Doctorante) Haytham YASSINE (Doctorant) HIV-1 replication cycle (from Schaker, 2010) • Selected publications Cosnefroy O, Tocco A, Lesbats P, Thierry S, Calmels C, Wiktorowicz T, Reigadas S, Kwon Y, De Cian A, Desfarges S, Bonot P, San Filippo J, Litvak S, Le Cam E, Rethwilm A, Fleury H, Connell PP, Sung P, Delelis O, Andréola ML, Parissi V. Stimulation of hRAD51 nucleofilament restricts HIV-1 integration in vitro and in infected cells. J Virol. (2012) 86(1):513-26. Epub 2011 Oct 19 Reigadas S, Masquelier B, Calmels C, Laguerre M, Lazaro E, Vandenhende M, Neau D, Fleury H, Andréola ML. Structure analysis of HIV-1 IN Y143C/R raltegravir resistance mutation in association with the secondary mutation T97. Antimicrob Agents Chemother (2011) 55, 3187-94. Lesbats P, Botbol Y, Chevereau G, Vaillant C, Calmels C, Arneodo A, Andréola ML, Lavigne M and Parissi V (2011) Functional coupling between HIV-1 integrase and the SWI/SNF chromatin remodeling complex for efficient in vitro integration into stable nucleosomes PLoS Pathogens, 7(2):e1001280.PMID:21347347 Reigadas S, G Anies, B Masquelier, C Calmels, LJ. Stuyver, V Parissi, H Fleury, ML Andréola. (2010) The HIV-1 integrase mutations Y143C/R are an alternative pathway for resistance to raltegravir and impact the enzyme functions. PLoS ONE, Apr 26;5(4):e10311PMID: 20436677 Mahias K, Ahmed-El-Sayed N, Masante C, Bitard J, Staedel C, Darfeuille F, Ventura M, Astier-Gin T. Therese Identification of a structural element of the hepatitis C virus minus strand RNA involved in the initiation of RNA synthesis. Nucleic Acids Res, 2010, Jul 1;38(12):4079-91.. Bitard J, Chognard G, Dumas E, Rumi J, Masante C, Mahias K, Astier-Gin T, Ventura M. Hijacking hepatitis C viral replication with a non-coding replicative RNA. Antiviral Res. 2010 Jul;87(1):9-15. immunology-microbiology │ 29 Pluripotency and early steps of differentiation (CNRS UMR 5164) www.umr5164.u-bordeaux2.fr/ Hélène Bœuf • Research team Permanent members (alphabetical order) Group leader : Bœuf Hélène (DR2, CNRS) Boiron J. M. (PH-EFS) Brunet de la Grange Philippe (CR-EFS) Chevaleyre Jean (IR-EFS) Conrad Véronique (MCF, UBS) Faucheux Corinne (MCF, UBS) Fédou Sandrine (Tech, UBS) Fontenay Bijou (PH-EFS) Gauthereau Xavier (AI, CNRS) Ivanovic Zoran (PH-EFS) Lafarge Xavier (PH-EFS) Massé Karine (MCF, UBS) Praloran Vincent (PU – PH) Thézé Nadine (PU – UBS) Thiébaud Pierre (CR1, CNRS) Veschambre Philippe (MCF, UBS) Villacreces Arnaud (IE, UBS) Wlaski Marija (IR-EFS) Non permanent members for the 20102012 period Fabre Annabelle : ½ ATER position : 20112012 Mathieu ME: PhD student: 2009-2011 Peytour Yann: PhD student : 2009-2011 Peytour Yann (IR-Contractuel, UBS ; 20112012) Tocco Alice: PhD student (2012-2014) Our research program is focused on the study of the alternative mechanisms of self-renewal and of early cell commitment in three models: mouse embryonic stem cells (ES), mouse and human adult hematopoietic stem cells (HSC) and Xenopus embryo. In Mouse ES cell model (maintained pluripotent in vitro, in the presence of LIF (Leukemia Inhibitory Factor)], we try to understand the mechanisms of action of LIF and its targets on cell plasticity. - We have set up a “reversion/ reprogrammation functional test” allowing the characterization of genes and signaling pathways involved in LIFdependent plasticity of murine ES cells. - We have investigated the conservation of function of new pluripotencylinked proteins in murine and Xenopus models and found conservation of function of the Mras gene, a LIF-dependent Pluri gene that we previously identified in mES cells (Trouillas 2009). - We have initiated collaborative works to study the impact of “LIF signatures” in self renewal properties of mES cells in parallel with cancer stem cells (in glioma model) and iPSC (induced pluripotent Stem Cells). Xenopus team’s work is centered on the study of cellular and molecular mechanisms of commitment and differentiation of embryonic cells in Xenopus laevis model. We are following several leads: the TEAD/ VESTIGIAL protein complexes during development; the LIF signaling pathway in Xenopus embryos; the expression profiles and functions of ligands and receptors of the purinergic pathway during embryonic development of Xenopus. Adult hematopoetic stem cells (HSC), are used in cellular therapy to cure hematological are used in cellular therapy to cure hematological malignancies. We showed that hypoxia favors the maintenance and quiescence of HSC. We will pursue on the role of physiological hypoxia on hematopoiesis by investigating quiescence and self renewal mechanisms in normal and leukemic HSC and will develop a novel strategy to establish iPS (induced Pluripotent stem cells) starting with human CD34+ hematopoietic stem cells. • Selected publications Duchez, P., Chevaleyre, J, Brunet de la Grange, P., Vlaski, M., Boiron, J.M. and Ivanovic, Z.(2012): Functional stability (at +4°c) of hematopoietic stem and progenitor cells amplified ex vivo from cord blood CD34+ cells. Cell Transplant, In press. Duchez P, Chevaleyre J, Vlaski M, Dazey B, Milpied N, Boiron JM, Ivanovic Z. (2012): Definitive set-up of clinical-scale procedure for ex-vivo expansion of cord blood hematopoietic cells for transplantation. Cell Transplant. 21(11):2517-21 Massé K, Dale N. (2012): Purines as potential morphogens during embryonic development. Purinergic Signal. 8(3):503-21. Gan Q, Thiébaud P, Thézé N, Jin L, Xu G, Grant P, Owens GK. (2011). WD repeat-containing protein 5, a ubiquitously expressed histone methyltransferase adaptor protein, regulates smooth muscle cell-selective gene activation through interaction with pituitary homeobox 2. J Biol Chem. 286(24):21853-64. Guitart AV, Debeissat C, Hermitte F, Villacreces A, Ivanovic Z, Boeuf H, Praloran V. (2011) Very low oxygen concentration (0.1%) reveals two FDCP-Mix cell subpopulations that differ by their cell cycling, differentiation and p27KIP1 expression. Cell Death Differ. Jan;18(1):174-8. 30 │Immunology-microbiology Ivanovic Z, Duchez P, Chevaleyre J, Vlaski M, Lafarge X, Dazey B, Robert-Richard E, Mazurier F, Boiron JM. (2011) : Clinicalscale cultures of cord blood CD34(+) cells to amplify committed progenitors and maintain stem cell activity. Cell Transplant. 20(9):1453-63. Faucheux C, Naye F, Tréguer K, Fédou S, Thiébaud P, Théze N. (2010). Vestigial like gene family expression in Xenopus: common and divergent features with other vertebrates. Int J Dev Biol. 54(8-9):1375-82. Mathieu M.E., Saucourt C., Mournetas V., Gauthereau X., Thézé N., Praloran V., Thiébaud P and H. Bœuf (2012) : LIF-dependent signaling: new pieces in the Lego. Stem cell Reviews and Reports, Mar;8(1):1-15. Tréguer K, Faucheux C, Veschambre P, Fédou S, Thézé N, Thiébaud P (2013) : Comparative functional analysis of ZFP36 genes during Xenopus development. PLos One, 8(1):e54550. Mathieu, ME, Saucourt, C., Soulet, F., Gauthereau, X., Fedou, S., Thézé, N., Thiébaud, P. and H. Boeuf (2013): Mras GTPase is a novel stemness marker with impact on mouse embryonic stem cell plasticity and on Xenopus embryonic cell fate. In press, Development. Activation of human T lymphocytes (CNRS UMR 5164) www.umr5164.u-bordeaux2.fr/pages/jdm-presentation.html Julie Déchanet-Merville Modulation of T cell activation is a general concern in the prevention or cure of various diseases including cancer, infections and autoimmune disorders. The main objective of the team is to understand the basic mechanisms leading to T lymphocyte activation, regulation and effector functions, with specific regards to gamma-delta T cells. Three main topics are investigated: (i) identifying the antigens recognized by gamma-delta TCRs, (ii) understanding the role of gamma-delta T cells in the response to infectious pathogens (plasmodium falciparum and cytomegalovirus) and (iii) characterizing the mechanisms leading to the activation of T lymphocytes in auto-immune diseases. We combine in vitro and in vivo approaches using both patient cohorts and animal models to progress in the understanding of basic biology of T lymphocytes and provide proof of concept that manipulation of T lymphocytes may impact disease outcome. This is made possible through the tight links that have been established between the basic research developed by our unit and the clinical activities in several Bordeaux University hospital departments, which represent one hallmark of our research. • Research team Team leader Déchanet-Merville Julie Heads of groups Behr Charlotte Blanco Patrick Scientists Capone Myriam Contin-Bordes Cécile Couzi Lionel Duffau Pierre Mamani-Matsuda Maria Merville Pierre Richez Christophe Lazaro Estibaliz Taupin Jean-Luc Research assistants Daburon Sophie Douchet Isabelle Gonzales Santi Loizon Séverine Netzer Sonia Pitard Vincent Post-doctorants Faustin Benjamin Furman David Marlin Romain PhD Students Bachelet Thomas Howard Jenny Jacquemin Clément Khairallah Camille Khoryati Liliane • Selected publications Willcox C*, Pitard V*, Netzer S, Couzi L, Salim M, Silberzahn T, Moreau JF, Hayday A, Willcox B*, and Déchanet-Merville J*. CMV and tumor stress-surveillance by human gamma-delta T cell receptor binding to Endothelial Protein C Receptor. *equal contributors. Nature Immunology (2012) 13: 872-879. Saint-Basile, V Pitard, J Déchanet-Merville, JF Moreau, M Troye-Blomberg, O Mercereau-Puijalon, C Behr. Control of Plasmodium falciparum erythrocytic cycle: gamma-delta T cells target the red blood cell-invasive merozoites. Blood (2011) 118:6952-6962 Couzi L, Pitard V, Sicard, X, Garrigue I, Hawchar O, Merville P, JF Moreau and J Déchanet-Merville. Antibody-dependent anti-cytomegalovirus activity of human gamma-delta T cells expressing CD16 (FcgammaRIIIa). Blood (2012) 119:1418-27 Duffau P, Seneschal J, Nicco C, Richez C, Lazaro E, Douchet I, Bordes C, Viallard JF, Goulvestre C, Pellegrin JL, Weill B, Moreau JF, Batteux F and Blanco P. Platelet CD154 potentiates interferon-alpha secretion by plamacytoid dendritic cells in systemic lupus erythematosus. Science Translational Medicine. (2010) 2:47-56. G Costa, S Loizon, M Guenot, I Mocan, F Halary, G de immunology-microbiology │ 31 Biochemistry genetics Energy transduction systems and mitochondrial morphology (SysTEMM) (IGBC CNRS UMR 5095) www.ibgc.cnrs.fr/?page=equipe&eq=systemm Daniel Brèthes ATP is the universal fuel molecule of any cell. The F1Fo-ATP synthase is a key enzyme of the energetic metabolism since it is responsible for most of the cellular synthesis of ATP. This 600 kDa complex is composed in yeast by 17 distinct subunits. It uses the energy of an electrochemical proton gradient to synthesize ATP. When protons are conducted across its membrane region, this conduction drives the rotation of a rotor part. This rotor part protrudes in the hydrophilic catalytic sector and induces conformational changes that lead to ATP synthesis. The main project of the team concerns the structural characterisation of the yeast F1-Fo ATP synthase. We have recently obtained the first refined structure of the yeast F1-c10 sub-complex at 3,4 Å resolution (figure). This work brought new information on the catalytic head, on the central stalk an on the structure of the membrane rotor. However, whatever the crystallization conditions or the inhibited state of the enzyme, the peripheral stalk is always lost during the crystallization process. We are developing new techniques of crystallisation in lipidic sponge phase in order to obtain the structure of the entire complex and get information on the proton channel domain. We have also settled collaboration with a team from the CBMN in Bordeaux to determine the structure and the dynamics of interaction of the small membrane subunits involved in the dimerization/oligomerization process by NMR. By cryo-electron microscopy and single particles analysis, we have obtained the structure at low resolution (30 Å) of the dimer of the ATP synthase solubilised in mild detergent. The localisation of the interfacial subunits at the dimerization interface will be done by cryo-EM using functionalized nanogold particles. The membrane deformation properties of this complex due to its oligomerization are also studied by reconstitution experiments and electron microscopy tomography. The yeast enzyme, like mammalian ATP synthases, is not only involved in ATP synthesis but also in the organization of the inner mitochondrial membrane: ATP synthase dimers constitute the building blocks of large oligomers that are involved in mitochondrial cristae morphology. A second project of the team is focused on the study of the dynamics and the regulation of the oligomerization The mitochondrial ultrastructure is normal in control HeLa cells (A) and altered in cells depleted in dimerization subunits (B, C). bar = 0.5 µm of this complex in relation with other mitochondrial processes such as fusion, fission or metabolic modifications in yeast and in human cells. In yeast the two dimerization subunits are not required for ATP synthase assembly and activity but are strictly necessary for the enzyme oligomerization. Recently, we demonstrate that the down-regulation of the mammalian homologues of these subunits by a shRNA strategy affects the stability of ATP synthase with a 50% decrease of the available functional enzyme and a destabilization of the ATP synthase oligomers, correlated with the fission of the mitochondrial network and the disorganization of mitochondrial ultrastructure. • Research team Daniel Brèthes, DR2 CNRS Alain Dautant, CR1 CNRS Marie-France Giraud, CR1 CNRS Isabelle Larrieu, IE2 CNRS Guy Lauquin, PR0 UBS Patrick Paumard, MCU UBS Corinne Sanchez, MCU UBS Nadir Seddiki, CDD ANR Collaboration within IBGC Bénédicte Salin, IR2 CNRS • Selected publications Habersetzer J, Ziani W, Larrieu I, StinesChaumeil C, Giraud M-F, Brèthes D, Dautant A and Paumard P. (2013) ATP synthase oligomerization: From the enzyme models to the mitochondrial morphology. Int. J. Biochem. Cell. Biol. 45, 99-105. Giraud MF, Paumard P, Sanchez C, Brèthes D, Velours J and Dautant A. (2012) Rotor architecture in the yeast and bovine F1-c-ring complexes of F-ATP synthase. J. Struct. Biol. 177, 490-497. Velours J, Stines-Chaumeil C, Habersetzer J, Chaignepain S, Dautant A and Brèthes D. (2011) Evidence of the proximity of ATP synthase subunits 6 (a) in the inner mitochondrial membrane and in the supramolecular forms of Saccharomyces cerevisiae ATP synthase. J. Biol. Chem. 286, 35477-35484. Dautant A, Velours J, Giraud MF. (2010) Crystal structure of the Mg·ADPinhibited state of the yeast F1c10-ATP synthase. J. Biol. Chem. 285, 2950229510. Talbot J-C, Dautant A, Polidori A, Pucci B, Cohen-Bouhacina T, Maali A, Salin B, Brèthes D, Velours J and Giraud M-F. (2009) Hydrogenated and fluorinated surfactants derived from Tris(hydroxymethyl)-acrylamidomethane allow the purification of a highly active yeast F1F0 ATP-synthase with an enhanced stability. J. Bioenerg. Biomembr. 41, 349-360. Biochemistry - Genetics │35 Functional analysis of amyloids (IGBC CNRS UMR 5095) www.ibgc.cnrs.fr/?page=equipe&eq=hsp Christophe Cullin • Research team Christophe Cullin, Professeur UB2 Loan Lascu, Professeur Christelle Marchal, MdC UB2 Claude Bobo, TCS CNRS Hélène Vignaud , Doctorante MRT Our goal is to understand the molecular characteristics of toxic amyloids. To answer this challenging question, we have taken advantage of toxic mutants heterologously expressed in yeast and combine various approaches from genetics to biophysics. In previous studies, we have isolated and characterized at a cellular and molecular level the structural particularities of a toxic amyloid mutant of Het-s, a prion protein from P.anserina. We are currently working with another amyloid protein related to Alzheimer disease (AD). We characterize at the molecular level different Aß variants responsible for familial Aß and/or selected for their high toxicity in the yeast model. We will use this model to isolate drugs active against Aß toxicity and analyze in vitro their interaction with Aß. We have put in place an efficient platform allowing the production of pure Aß and propose to study both the aggregates formed but also to characterize the intermediates of amyloidogenesis. These studies will include “classical” approaches such as Tht binding, but also various biophysical techniques including FTIR, CryoTEM and NMR. The toxicity of amyloid-forming proteins will be correlated with their interactions with lipid membrane during the aggregation. We will follow this interaction by different approaches (plasmon waveguide resonance, polarization-modulated infrared reflection absorption spectroscopy (PMIRRAS), ellipsometry, cryoTEM…) in a frame of a collaboration with the team of S. Lecomte (CBMN, Pessac). The comparison of biophysical characteristics of the different Aß variants should help us to highlight the molecular properties of Aß toxicity. • Selected publications 1- Ta, H. P., Berthelot, K., Coulary-Salin, B., Castano, S., Desbat, B., Bonnafous, P., Lambert, O., Alves, I., Cullin, C. and Lecomte, S. (2012) A yeast toxic mutant of HET-s amyloid disrupts membrane integrity. Biochim Biophys Acta 2- D’Angelo, F., Vignaud, H., Di Martino, K., Salin, B., Devin, A., Cullin, C. and Marchal, C. (2012) A yeast model for Aß aggregation exemplifies the role of membrane trafficking and PICALM in cytotoxicity. Disease Models & Mechanisms In press 3- Millot, G. A., Berger, A., Lejour, V., Boulé, J. B., Bobo, C., Cullin, C., Lopes, J., Stoppa-Lyonnet, D. and Nicolas, A. (2011) Assessment of human Nter and Cter BRCA1 mutations using growth and localization assays in yeast. Hum Mutat 36 │Biochemistry - Genetics 4-Berthelot, K., Ta, H. P., Géan, J., Lecomte, S. and Cullin, C. (2011) InVivo and In Vitro Analyses of Toxic Mutants of HET-s: FTIR Antiparallel Signature Correlates with Amyloid Toxicity. J Mol Biol 412, 137-152 5- Ta, H. P., Berthelot, K., Coulary-Salin, B., Desbat, B., Géan, J., Servant, L., Cullin, C. and Lecomte, S. (2011) Comparative studies of nontoxic and toxic amyloids interacting with membrane models at the air-water interface. Langmuir 27, 4797-4807 6- Berthelot, K., Lecomte, S., Géan, J., Immel, F. and Cullin, C. (2010) A yeast toxic mutant of HET-s((218-289)) prion displays alternative intermediates of amyloidogenesis. Biophys J 99, 1239-1246 7- Couthouis, J., Marchal, C., D’Angelo, F., Berthelot, K. and Cullin, C. (2010) The toxicity of an «artificial» amyloid is related to how it interacts with membranes. Prion 4, 283-291 Genetics of Metabolic Networks (IGBC CNRS UMR 5095) www.ibgc.cnrs.fr/?page=equipe&eq=grm Bertrand Daignan-Fornier • Research team Cell size, a complex trait at the crossroad between metabolism and the cell cycle Cell size can vary more than fifty folds among cell types and organisms, however for a given cell type, cell size is noticeably constant. Cell size homeostasis implies that specific mechanisms are devoted to estimating cell size and coordinating growth (increase in cell volume) and proliferation (increase in cell number). Although studied for more than 50 years, the mechanisms that regulate cell size in eukaryotes remain largely mysterious. Our project is to decipher the genetic control of cell size in yeast.Our aim is to identify the different pathways involved in cell size control. Cell size is a highly complex trait affected by hundreds of genes. Therefore, the global understanding of cell size control cannot be achieved by studying individual mutations. We use a systems biology approach to get an integrated picture of the phenomenon. The first pathway that we have identified is the Sir2-60S pathway (Figure below) that includes more than 30 mutants Identification of the targets of AICAR, a compound that selectively kills aneuploid cells This project is aimed at understanding how the highly promising drug AICAR is acting in vivo specifically on aneuploid cells. Using yeast, nematode and mammalian cells, we perform target deconvolution and validation by combining genetics and affinity chromatography approaches. We have identified several proteins that are affected by AICAR in vivo in yeast. We found a strong conservation among the yeast and mouse AICAR-binders, thus establishing the broad impact of this approach to predict relevant pharmacological networks. Benoît Pinson - CR1 CNRS Chloé Philippe – Master 2 Christelle Saint-Marc - AI CNRS Delphine Albrecht – Master 2 Jérémy Tissot-Dupont –AI ANR Johanna Ceschin – ASI Bdx2 José E. Gomes _ MCF Bdx2 Michel Moenner – PR1 Bdx1 Stéphane Puyo – Post-Doc Ligue • Selected publications Hurlimann HC, Laloo B, Simon-Kayser B, Saint-Marc C, Coulpier F, Lemoine S, Daignan-Fornier B, Pinson B. (2011) Physiological and toxic effects of the purine intermediate 5-Amino-4ImidazoleCarboxAmide Ribonucleotide (AICAR) in yeast. J Biol Chem.. 286: 30994-31002. Laporte D, Lebaudy A, Sahin A, Pinson B, Ceschin J, Daignan-Fornier B, Sagot I. (2011) Metabolic status rather than cell cycle signals control quiescence entry and exit. J Cell Biol. 192(6):949-57. Saint-Marc C, Pinson B, Coulpier F, Jourdren L, Lisova O, Daignan-Fornier B. (2009) Phenotypic consequences of purine nucleotide imbalance in Saccharomyces cerevisiae. Genetics. 183(2):529-38, Pinson B, Vaur S, Sagot I, Coulpier F, Lemoine S, Daignan-Fornier B. (2009) Metabolic intermediates selectively stimulate transcription factor interaction and modulate phosphate and purine pathways. Genes Dev. 2009 23(12):1399-407. Biochemistry - Genetics │37 Cellular energy metabolism (IGBC CNRS UMR 5095) http://www.ibgc.u-bordeaux2.fr/?page=equipe&eq=mec Anne Devin The aim of our studies is to better define the role of mitochondria in the structuration and regulation of the cellular energy metabolism as well as in a number of vital process, either normal or pathological: stress adaptation, cell proliferation. • Research team Nicole Avéret - MCU UBS Anne Devin - CR1 CNRS Audrey Ladonne - CDD AI INSERM Jean-Pierre Mazat - Professeur émérite UBS Stéphane Ransac - MCU UBS Michel Rigoulet - Professeur UBS Christophe Rocher - IGE UBS Edgar Yoboue - Post-Doc 1. Physiological adaptations, energy metabolism and mitochondrial biogenesis in the yeast levure Saccharomyces cerevisiae a – Control and regulation of mitochondrial biogenesis Mitochondrial biogenesis requires both the nuclear and mitochondrial genomes, and several major enzymatic complexes (respiratory chain, ATPsynthase) are made of proteins coded by one or the other genome. We aim at better understanding the relationship between the number, the composition and the activity of mitochondria and the cellular energy requirements. We specifically try to better understand the role of the Ras/AMPc pathway and of reactive oxygen species. b - Crabtree and Warburg effects The fate and proliferation of cells are closely linked to their metabolic state and especially to their energy metabolism. More than 50 years ago, Otto Warburg showed that the ability of cancer cells to proliferate was directly linked to the degree of repression of the mitochondrial metabolism associated with and increase in the glycolytic flux. The more the mitochondrial metabolism is repressed and glycolysis activated, the more cancer cells can proliferate. We are working on the molecular mechanisms involved in this process and on their reversibility. 2. Mechanisms of regulation of phosphorylative oxidations: organization and regulation of the pathways of reoxydation of cytosolic NADH The oxidative metabolism in S. cerevisiae is an example of integrated system: NADH produced during glycolysis or cytosolic oxidation of ethanol is brought to NADH dehydrogenase located on the external side of the internal de la membrane. NADH dehydrogenase activity leads to the inhibition of glycerol3-P-déshydrogénase and thus of the glycerol-3-P shuttle. There is evidence that the 2 NADH dehydrogenases (Nde1p, Nde2p) do not regulate glycerol3-Pdehydrogenase similarly. In addition, variation in the supramolecular organization of the respiratory chain, that may itself depend on the provided substrates, may affect its ability to reoxidize either NADH or FADH2. We are investigating the relationship between the provided substrates, organization of the respiratory chain, and ROS production. • Selected publications Baret P, Septembre-Malaterre A, Rigoulet M, Lefebvre d’Hellencourt C, Priault M, Gonthier MP, Devin A. Dietary polyphenols preconditioning protects 3T3-L1 preadipocytes from mitochondrial alterations induced by oxidative stress. Int J Biochem Cell Biol. 2013 Jan;45(1):167-74 Yoboue ED, Devin A. Reactive oxygen species-mediated control of mitochondrial biogenesis. Int J Cell Biol. 2012;2012:403870 Casteilla L, Devin A, Salin B, Averet N, Rigoulet M. UCP1 as a water/proton co-transporter. Mitochondrion. 2012 Jul;12(4):480-1 Yoboue ED, Augier E, Galinier A, Blancard C, Pinson B, Casteilla L, Rigoulet M, Devin A. cAMP-induced mitochondrial compartment biogenesis: role of glutathione redox state. J Biol Chem. 2012 Apr 27;287(18):14569-78 Carneiro L, Allard C, Guissard C, Fioramonti X, TourrelCuzin C, Bailbé D, Barreau C, Offer G, Nédelec E, Salin 38 │Biochemistry - Genetics B, Rigoulet M, Belenguer P, Pénicaud L, Leloup C. Importance of mitochondrial dynamin-related protein 1 in hypothalamic glucose sensitivity in rats. Antioxid Redox Signal. 2012 Aug 1;17(3):433-44 Casteilla L, Devin A, Carriere A, Salin B, Schaeffer J, Rigoulet M. Control of mitochondrial volume by mitochondrial metabolic water. Mitochondrion. 2011 Nov;11(6):862-6 Diaz-Ruiz R, Rigoulet M, Devin A. The Warburg and Crabtree effects: On the origin of cancer cell energy metabolism and of yeast glucose repression. Biochim Biophys Acta. 2011 Jun;1807(6):568-76 Rigoulet M, Yoboue ED, Devin A. Mitochondrial ROS generation and its regulation: mechanisms involved in H(2)O(2) signaling. Antioxid Redox Signal. 2011 Feb 1;14(3):459-68 Molecular genetics of mitochondrial systems (IGBC CNRS UMR 5095) http://www.ibgc.u-bordeaux2.fr/?page=equipe&eq=gmsm Jean-Paul di Rago ATP synthase is a major enzymatic system of mitochondria, responsible for the last steps in oxidative phosphorylation. It is made of about 20 polypeptide subunits with a double genetic origin, nuclear and mitochondrial. We are interested in the mechanisms involved in the formation of this complex in the baker yeast Saccharomyces cerevisiae and in Human. To this aim, we have set up genetic and biochemical strategies in order to identify new factors involved in the biogenesis of this system. The cell mitochondrial content is clearly tightly regulated, but the regulatory mechanisms are poorly understood. This is an important issue, not only for basic research, but also in diseases since a change in the number of mitochondria is observed in many diseases (mitochondrial dysfunctions and cancer). Our approach is based on a collection of yeast ATP synthase mutants that show a huge increase in the number of mitochondrias. • Research team E. Tetaud, CR1 CNRS S. Duvezin-Caubet, CR1 CNRS J.-P. Lasserre, MCU Bxd2 J.-P. di Rago, DR2 CNRS F. Godard, TCE CNRS A. Martos, Doctorant ANR A. Kabala, Thèse co-tutelle F. Courtin, AI FRM Mitochondrial genomes are supposed to be derived from an ancestral prokaryotic genome which size was considerably reduced during evolution, notably because of a massive gene transfer towards the nucleus. Why a mitochondrial genome is maintained after close to two billion years of evolution is ill understood. We use the yeast model to understand the adaptations that are required for a nuclear relocalization of the mitochondrial genes of ATP synthase. Finally, we have generated yeast models for human diseases associated with a defect in ATP synthase, and in collaboration with Marc Blondel (Brest), we have used these models to screen for drugs that could help the research for treatments against these diseases. We apply the same strategy to other diseases that can be modelized in yeast. • Selected publications Kucharczyk R., Giraud M.-F., Brèthes D., WysockaKapcinska M., Ezkurdia N., Salin B., Velours J., Camougrand N, Haraux F. and Jean-Paul di Rago. Defining the pathogenesis of human mtDNA mutations using a yeast model : the case of T8851C. Int J Biochem Cell Biology, 2013 Jan;45(1):130-40 Bietenhader M., Martos A., Tetaud E., Aiyar RS, Sellem C.H., Kucharczyk R., Clauder-Münster S., Giraud M.F., Godard F., Salin B., Sagot I., Gagneur J., DéquardChablat M., Contamine V., Hermann-Le Denmat S., Sainsard-Chanet A., Steinmetz L.M. and di Rago J.-P. Experimental Relocation of the Mitochondrial ATP9 Gene to the Nucleus Reveals Forces Underlying Mitochondrial Genome Evolution. Plos Genetics, 2012;8(8):e1002876 Couplan E, Aiyar RS, Kucharczyk R, Kabala A, Ezkurdia N, Gagneur J, St Onge RP, Salin B, Soubigou F, Le Cann M, Steinmetz LM, di Rago JP, Blondel M. A yeastbased assay identifies drugs active against human mitochondrial disorders. Proc Natl Acad Sci U S A. 2011 Jul 19;108(29):11989-94 Godard F, Tetaud E, Duvezin-Caubet S, di Rago JP. A genetic screen targeted on the FO component of mitochondrial ATP synthase in Saccharomyces cerevisiae. J Biol Chem. 2011 May 20;286(20):18181-9 Déquard-Chablat M, Sellem CH, Golik P, Bidard F, Martos A, Bietenhader M, di Rago JP, Sainsard-Chanet A, Hermann-Le Denmat S, Contamine V. Two nuclear life cycle-regulated genes encode interchangeable subunits c of mitochondrial ATP synthase in Podospora anserina. Mol Biol Evol. 2011 Jul;28(7):2063-75 Biochemistry - Genetics │39 Chromosome Segregation (IGBC CNRS UMR 5095) www.ibgc.cnrs.fr/?page=equipe&eq=mmtc Jean-Paul Javerzat team • Research Sonia Dheur CR1 CNRS Sabine Vaur CR2 CNRS Stéphanie Vazquez T CNRS Jean-Paul Javerzat DR CNRS • Selected publications Vaur S, Feytout A, Vazquez S, Javerzat JP. Pds5 promotes cohesin acetylation and stable cohesin-chromosome interaction. EMBO Rep. 2012 Jun 29;13(7):645-52. Feytout A, Vaur S, Genier S, Vazquez S, Javerzat JP. Psm3 acetylation on conserved lysine residues is dispensable for viability in fission yeast but contributes to Eso1mediated sister chromatid cohesion by antagonizing Wpl1. Mol Cell Biol. 2011 Apr;31(8):1771-86. Dheur S, Saupe SJ, Genier S, Vazquez S, Javerzat JP. Role for cohesin in the formation of a heterochromatic domain at fission yeast subtelomeres. Mol Cell Biol. 2011 Mar;31(5):1088-97. Javerzat JP. Molecular biology. Directing the centromere guardian. Science. 2010 Jan 8;327(5962):150-1. Bernard P, Drogat J, Dheur S, Genier S, Javerzat JP. Splicing factor Spf30 assists exosome-mediated gene silencing in fission yeast. Mol Cell Biol. 2010 Mar;30(5):1145-57 Cell division is a common feature of all live forms by which new individuals are produced from their progenitors. During this process each cell duplicates its genome and transmits a copy to daughter cells during mitosis. At that time, the mitotic spindle must “know” which chromosomes are duplicates so as to segregate them from each other. The linkage of duplicated chromosomes by the protein complex cohesin enables this to occur by creating physically associated pairs. These chromosome pairs (called sister-chromatids) attach to microtubules of the mitotic spindle through a kinetochore protein complex that forms on the centromeric region of each chromatid. When all chromosome pairs are attached, cohesin is cleaved by the enzyme separase, triggering the sudden disjunction of sister chromatids at the metaphase to anaphase transition. and their movement to opposite spindle poles. Cohesin is an essential for chromosome segregation. Loss of function is lethal and subtle alterations lead to errors in chromosome segregation, generating cells with an abnormal number of chromosomes (aneuploids) which have been linked to cancer progression, infertility, and debilitating genetic diseases such as Down syndrome. Our main focus is to understand how sister-chromatid cohesion is created during S phase and maintained until the time of chromosome segregation. Cohesion maintenance is particularly striking as it can last from a few hours in actively dividing cells and up to many years as in human oocytes ! Besides its mitotic functions cohesin is involved in the control of gene expression, presumably by promoting higher order chromosome structures. In this regard, we investigate the relationship between cohesin, the heterochromatic domains of chromosomes and gene regulation. Experiments are carried out in the fission yeast Schizosaccharomyces pombe, a user-friendly model organism for which all genetic, biochemical and cytological techniques are available. 40 │Biochemistry - Genetics Mitochondria, stress and cell death (IGBC CNRS UMR 5095) www.ibgc.cnrs.fr/?page=equipe&eq=msmc Stéphen Manon • Research team Our research aims at understanding the molecular mechanisms underlying the role of mitochondria and the Bcl-2 family in apoptosis and mitophagy. This research is organized along three main themes: - Identification of the molecular mechanisms regulating the interaction of pro-apoptotic protein Bax with the outer mitochondrial membrane; - Regulation of autophagy by the anti-apoptotic protein Bcl-xL; - Regulation of mitophagy by alterations of the mitochondrial functions. Recent important results include: - We have demonstrated that anti-apoptotic protein are able to “prime” pro-apoptotic proteins, a phenomenon that maybe of crucial importance in many cancer cells. - We have provided evidences that functionnal alterations of the mitochondrial respiratory chain are a signal that triggers autophagy, in a way dependent on mitochondrial components and mitophagy actors. - We have unveiled how partial deamidation of Bcl-xL bestows cancer cells with additional survival advantage by stimulating their autophagic activity. We have also shown that Bcl-xL controls cancer cells ability to obtain food from their environment by interfering with the degradation of plasma membrane nutrient transporters. Axel Athané, AI-CDD UBS Nadine Camougrand, DR2 CNRS David Garenne, M2 student Cécile Gonzalez, MCf UBS Stéphen Manon, CR1 CNRS Bruno Manesse, M2 student Muriel Priault, CR1 CNRS Lilit Simonyan, IE-CDD ANR Dario Trindade, PhD student, Fundaçao Gulbenkian • Selected publications Deffieu M, Bhatia-Kissová I, Salin B, Klionsky DJ, Pinson B, Manon S, Camougrand N (2013) Increased cytochrome b reduction and mitophagy components are required to trigger nonspecific autophagy following induced mitochondrial dysfunction. J Cell Sci., in press Drullion C, Lagarde V, Gioia R, Legembre P, Priault M, Cardinaud B, Lippert E, Mahon FX, Pasquet JM (2013) Mycophenolic Acid overcomes imatinib and nilotinib resistance of chronic myeloid leukemia cells by apoptosis or a senescent-like cell cycle arrest. Leuk Res Treatment, in press Bhatia-Kiššová I, Camougrand N (2013) Mitophagy: a process that adapts to the cell physiology. Int J Biochem Cell Biol 45, 30-33 Renault TT, Teijido O, Antonsson B, Dejean LM, Manon S (2013) Regulation of Bax mitochondrial localization by Bcl2 and Bcl-x(L): keep your friends close but your enemies closer. Int J Biochem Cell Biol. 45, 64-67 Renault TT, Grandier-Vazeille X, Arokium H, Velours G, Camougrand N, Priault M, Teijido O, Dejean LM, Manon S (2012) The cytosolic domain of human Tom22 modulates human Bax mitochondrial translocation and conformation in yeast. FEBS Lett. 586, 116-121 Trocoli A, Mathieu J, Priault M, Reiffers J, Souquère S, Pierron G, Besançon F, Djavaheri-Mergny M (2011) ATRA-induced upregulation of Beclin 1 prolongs the life span of differentiated acute promyelocytic leukemia cells. Autophagy 7, 1108-1114 Biochemistry - Genetics │41 Cell Growth and Division (IGBC CNRS UMR 5095) http://www.iecb.u-bordeaux.fr/teams/MCCUSKER/McCuskerlab/ Welcome.html Derek McCusker • Research team Derek McCusker - CR1 CNRS Mini Jose-Deepak - FRM Fellow Aurelie Massoni-Laporte - AI CNRS Romain Mitteau - UB2 Sylvain Tollis - ARC Fellow Cells grow and divide in a controlled fashion via a regulated series of events termed the cell cycle. Extensive structural rearrangements occur during the cell cycle that facilitate the efficient partitioning of the duplicated genome into a daughter cell. We study how cell cycle cues elicit these structural transitions at the molecular and cell biological level using high resolution imaging, biochemistry and mathematical modelling. In doing so, our aim is to understand how cell growth and cell division are coordinated, and how failure of these mechanisms contributes to cancer. • Selected publications Jose M, Tollis S, Nair D, Sibarita JB and McCusker D. 2013. Robust polarity establishment occurs via an endocytosis-based cortical corralling mechanism. J Cell Biol. 200(4):407418. Kellogg D*, Royou A, Velours C, McCusker D*. 2012. Cdk1-dependent control of membrane trafficking dynamics. Mol Biol Cell 3336-3347. (* equal contribution). McCusker D and Kellogg D. 2012. Membrane growth during the cell cycle: Unsolved mysteries and recent progress. Current Opinion in Cell Biology. 24: 845-851. Royou A, McCusker D, Kellogg DR, Sullivan W. 2008. Distinct pools of Cdk1 independently drive cytoplasmic and nuclear mitotic cycles. J Cell Biol. 183(1):63-75. McCusker D, Denison C, Anderson S, Egelhofer TA, Yates JR 3rd, Gygi SP, Kellogg DR. 2007. Cdk1 Coordinates cell surface growth with the cell cycle. Nat Cell Biol. 9(5):506-15. 42 │Biochemistry - Genetics Figure 1. Mathematical modelling and evanescent-field imaging illustrating the establishment of cell polarity. The cells on the left are non-polarized, wheras those on the right have established a polarity axis that is used for the ensuing cell cycle. Results of an in silico mathematical model show Rho GTPase activity in the top scheme while the bottom scheme shows in vivo data. Endocytic vesicles are shown in red while exoctic vesicles are shown in cyan. Figure 2. Individual Rho GTPase GAP domains (left) display a similar structure that is revealed when models of their structures are overlaid (right). The catalytic residue of the GAPs are shown in red while conserved phosphorylation sites are shown in grey. Phosphorylation of these residues contributes to the establishment of cell polarity shown in Figure 1. Mitochondrial organization and dynamics (IGBC CNRS UMR 5095) www.ibgc.u-bordeaux2.fr/?page=equipe&eq=odm Manuel Rojo Mitochondria fulfill several functions that are essential for cell life and death. They continuously move, fuse and divide and these dynamics are required for mitochondrial biogenesis, function and maintenance. Fusion and fission are governed by large GTPases of the dynamin-superfamily (Mfn1, Mfn2, OPA1, Drp1) that are conserved in all eukaryotes. Mutations of fusion factors Mfn2 or OPA1 are associated to Charcot-Marie-Tooth disease type 2A (CMT2A) or to autosomal dominant optic atrophy (DOA) and defects in dynamics have been also associated to degenerative neuropathies (Parkinson, Alzheimer). The dynamics and machineries of mitochondrial membranes differ in several aspects from those secretory and endocytic compartments. From the fundamental point of view, their characterization is expected to reveal mitochondria-specific features as well as mechanisms that are common to all endomembranes. From the biomedical perspective, the characterization of mitochondrial dynamics, and of the proteins involved, will allow the identification of genetic determinants and targets and open the way for the development of therapeutic strategies. Our team seeks to characterize the mechanisms of mitochondrial fusion, the role(s) of the dynamins involved, the functional consequences of pathogenic MFN2 and OPA1 mutations and the physiological consequences of fusion defects. The team develops two main projects: (1) the characterization of the fusion process (ex vivo and in vitro) and (2) the molecular and functional characterization of fusion factors (Mfn1, Mfn2 and OPA1). We develop novel assays for the precise and quantitative characterization of mitochondrial fusion. This will enable the study of fusion in different physiopathological situations and the search for pharmacological modulators. We have established strategies for the expression of fusion factors and investigate their capacity to deform and/or fuse membranes as well as the consequences of disease-associated mutations. Our experimental approaches include protein expression, purification and reconstitution, subcellular fractionation and fluorescence microscopy. Our team welcomes new researchers and is open to novel projects and collaborations. Fusion of differentially labeled mitochondria (mtEGFP, mtDsRed) in a HeLa cell polykaryon. • Research team Manuel Rojo (DR2 CNRS) Claudine David (IE1 CNRS) Marine Bouhier (IE CDD FRM) Paul Charron (Master 2) • Selected publications Sauvanet C, Duvezin-Caubet S, Salin B, David C, Massoni-Laporte A, di Rago JP, Rojo M. Mitochondrial DNA mutations provoke dominant inhibition of mitochondrial inner membrane fusion. PLoS One. 2012;7(11):e49639 Sauvanet, C., S. Duvezin-Caubet, J. P. di Rago, and M. Rojo. (2010), Energetic requirements and bioenergetic modulation of mitochondrial morphology and dynamics. Semin Cell Dev Biol. 21:558-565. Sauvanet C. , Arnauné-Pelloquin L. , David C. , Belenguer P., Rojo M. (2010) Dynamique et morphologie mitochondriales : acteurs, mécanismes et pertinence fonctionnelle, Médecine Sciences 26, 823-829. Gegg ME, Cooper JM, Chau KY, Rojo M, Schapira AH, Taanman JW. (2010) Mitofusin-1 and Mitofusin-2 are ubiquitinated in a PINK1/parkin dependent manner upon induction of mitophagy. Hum Mol Genet. 19(24):4861-70. Landes T, Emorine LJ, Courilleau D, Rojo M, Belenguer P, ArnaunéPelloquin L. (2010), The BH3-only Bnip3 binds to the dynamin Opa1 to promote mitochondrial fragmentation and apoptosis by distinct mechanisms. EMBO Rep. 11(6):459-65. Guillery O, Malka F, Landes T, Guillou E., Blackstone C, Lombès A, Belenguer P., Arnoult D., Rojo M (2008) Metalloprotease-mediated OPA1 processing is modulated by the mitochondrial membrane potential. Biol. Cell 100(5), 315-325. Biochemistry - Genetics │43 Control and Dynamics of Cell Division (IGBC CNRS UMR 5095) www.iecb.u-bordeaux.fr/index.php/fr/equipes/53-control-and-dynamics-of-cell-division Anne Royou • Research team Anne Royou – CR1 CNRS Marie-Charlotte Claverie – AI UB2 Nicolas Derive – Doctorant UB2 Nabia Founounou – Post-doc (ATIPAVENIR, Région Aquitaine) Damien Goutte-Gattat – Post-doc (ERC) Emilie Jamet – AI (ERC) Cédric Landmann –AI (ANR) Emilie Montembault – CR2 CNRS Cédric Soler – MCU Clermont-Ferrand The mechanisms that safeguard cells against aneuploidy are of great interest as aneuploidy contributes to tumorigenesis. Using live imaging approaches, we have identified two novel mechanisms that permit the accurate transmission of chromosomes during cell division of Drosophila neuronal stem cells. The first mechanism involves the faithful segregation of damaged chromosomes. We monitor cells entering mitosis with broken chromosomes. Our studies reveal that chromosome fragments segregate properly to opposite poles. This poleward motion is mediated through DNA tethers that connect the chromosome fragments. The second mechanism involves the coordination of chromosome segregation with cell cleavage. We found that cells can adapt to a four-fold increase in chromatid length by elongating transiently during anaphase. This mechanism ensures the clearance of chromosomes from the cleavage plane prior to completion of cell division. • Selected publications Kotadia, S.*, Montembault, E.*, Sullivan, W. Royou, A. (2012) Cell elongation is an adaptive response for clearing long chromatid arms from the cleavage plane. J. Cell Biol. 199(5): 745-53 *equal contribution McCusker D., Royou, A. Velours C., Kellogg D. (2012) Cdk1-dependent control of membrane trafficking dynamics. Mol Biol Cell. 23(17): 333647 Royou, A., Gagou, M., Karess, R., D., Sullivan, W. (2010) BubR1 and Polo-coated DNA tethers facilitate the segregation of acentric chromatids. Cell 140(2): 235-45. Royou, A., McCusker, D., Kellogg, D., Sullivan, W. (2008) Grapes(Chk1) prevents nuclear Cdk1 activation by delaying Cyclin B nuclear accumulation. J. Cell Biol. 183(1): 63-75 44 │Biochemistry - Genetics The research team was recently awarded an ERC starting Grant Cell Biology of Quiescence (IGBC CNRS UMR 5095) www.ibgc.u-bordeaux2.fr/?page=equipe&eq=sagot Isabelle Sagot Quiescence, a cellular state defined as a reversible absence of proliferation, concerns the vast majority of cells on earth, from microbes to stem cells. Quiescent cells not only have to survive and face aging, but they must also preserve their ability to re-enter the cell cycle in a tightly regulated manner and to give rise to a healthy and rejuvenated progeny. Therefore quiescence is central for two major biological issues: the control of cell proliferation and cell aging. Remarkably little is known about this specific cellular state and the mechanisms governing quiescence/proliferation transitions remain obscure. In fact, even the most recent genomic, transcriptomic and metabolomic approaches did not reveal any clear specific quiescence molecular signature, challenging thus the existence of a «program» that commit cell to the quiescent state. Few years ago, we have started to characterize quiescent yeast cells at the cellular level. We have shown that upon entry into quiescence two evolutionary distant yeast species, S. cerevisiae and S. pombe, reorganize drastically some of their intracellular machineries. Indeed, upon carbon starvation cells assemble two specific structures Actin Bodies (AB) and Proteasome Storage Granules (PSGs) that respectively result from the specific reorganization the actin cytoskeleton and the proteasome. Importantly, these structures are mobilized within seconds when cells exit quiescence upon re-feeding. More recently, using AB and PSGs as new specific markers of the quiescent state at the single cell level, we have demonstrated that quiescence entry and exit can occur not only in the G1 phase of the cell cycle, but also in other cell cycle stages. Additionally, we have established that the cell’s metabolic status rather than cell cycle regulators is critical for the control of quiescence/proliferation transitions. Our current project is to dress the cartography of all the cellular remodeling that occur upon transition from proliferation to quiescence and to use these specific cellular organization as tools to address central questions in the quiescence field such as: how do quiescent cells survive, what are the cascade of molecular switches that tightly control quiescence exit, and how can quiescent cell give rise to a rejuvenated progeny upon quiescence exit. • Research team Isabelle Sagot – CR1 CNRS Fabien Courtout - Technicien Damien Laporte – Post-Doc ANR/ Région Aquitaine Laure Jimenez – Doctorante MESR UBS • Selected publications Laporte D, Lebaudy A, Sahin A, Pinson B, Ceschin J, Daignan-Fornier B, Sagot I. 2011 Metabolic status rather than cell cycle signals control quiescence entry and exit. The Journal of Cell Biology. 192(6):949-57. Daignan-Fornier B, Sagot I. 2011Proliferation/quiescence : the controversial «aller-retour». Cell Division. 6(1):10. Daignan-Fornier B, Sagot I. 2011 Proliferation / Quiescence : When to start ? Where to stop? What to stock? Cell Division.6(1) :20. Laporte D, Salin B, Daignan-Fornier B, Sagot I. 2008 Reversible cytoplasmic localization of the proteasome in quiescent yeast cells. The Journal of Cell Biology. 181(5): 737-745 Sahin A, Daignan-Fornier B, Sagot I. 2008 Polarized growth in the absence of F-actin in Saccharomyces cerevisiae exiting quiescence. PLoS ONE. 3(7) e2556. Yeast cells can enter quiescence from all cell cycle stages. Quiescent cell’s contour is stained with concanavaline A – FITC (Green) ; Actin Bodies, actin structures that are specific of quiescent cells are stained with Alexa 548 phalloidine (Red). Round cells have entered quiescence from G1, budded cells from other cell cycle stages. Biochemistry - Genetics │45 Non-self recognition in fungi (IGBC CNRS UMR 5095) http://www.iecb.u-bordeaux.fr/index.php/fr/equipes/53-control-anddynamics-of-cell-division Sven J. Saupe • Research team Annick Breton - CR1 CNRS Corinne Clavé - Professeur UBS Asen Daskalov - Doctorant MESR Marina Lamacchia - Post-Doc ANR Frederique Ness - MCU UBS Mathieu Paoletti - CR1 CNRS Khalid Salamat - Post-Doc ANR Sven J. Saupe - DR2 CNRS Martine Sicault - TCE UBS • Selected publications Debets AJ, Dalstra HJ, Slakhorst M, Koopmanschap B, Hoekstra RF, Saupe SJ (2012) High natural prevalence of a fungal prion. Proc Natl Acad Sci U S A 109: 10432-10437 Daskalov A, Paoletti M, Ness F, Saupe SJ (2012) Genomic clustering and homology between HET-S and the NWD2 STAND protein in various fungal genomes. Plos One 7: e34854 Mathur V, Seuring C, Riek R, Saupe SJ, Liebman SW (2012) Localization of HET-S to the cell periphery, not to [Het-s] aggregates, is associated with [Het-s]-HET-S toxicity. Mol Cell Biol 32: 139-153 Saupe SJ, Daskalov A (2012) The [Het-s] Prion, an Amyloid Fold as a Cell Death Activation Trigger. PLoS Pathog 8: e1002687 Benkemoun L, Ness F, Sabate R, Ceschin J, Breton A, Clave C, Saupe SJ (2011) Two structurally similar fungal prions efficiently cross-seed in vivo but form distinct polymers when coexpressed. Mol Microbiol 82: 13921405 Saupe SJ (2011) The [Het-s] prion of Podospora anserina and its role in heterokaryon incompatibility. Semin Cell Dev Biol 22: 460-468 46 │Biochemistry - Genetics Our activity is centered on the study of non-self recognition in fungi. We want to improve our understanding of how fungi recognized and respond to non-self. We are focused on the description of a non-self recognition process termed heterokaryon incompatibility which takes place when two unlike individuals belonging to the same species fuse. But gradually we expand our studies to include other types of biotic interactions (between fungi belonging to different species, between fungi and bacteria). Our main model species is Podospora anserina. We are characterizing the genes controlling this process at different steps from the initial recognition event to the ensuing cellular response. In particular, we are interested in a large gene family encoding STAND proteins which show homology to animal NOD-like receptors and plant NBS-LRR proteins. We propose that these genes constitute the fungal counterpart of the pathogen recognition receptors controlling innate immunity in animals and plants. In addition, one of the proteins involved in this process is the HET-s prion protein. Recent studies have shown that the prion fold of HET-s serves as a trigger to induce the toxicity of the partner protein termed HET-S and that toxicity of HET-S can also be activated by a STAND protein termed NWD2. Rare diseases: Genetics and Metabolism (MRGM, EA4576) www.univ-bordeauxsegalen.fr/fr/recherche/acteurs-de-la-recherche/biologie-fondamentale-et-appliquee-a-la-medecine/ mrgm.html Didier Lacombe Our basic research concerns physiopathological studies of different orphan genetic diseases affecting developmental programs, energy metabolism (regulation of energy transducing processes at the level of proteins, organelle, genes and epigenetics, mitochondrial dynamics, mitophagy and biogenesis and metabolic flexibility) and lipid metabolism (implications in nervous system morphogenesis and function, syndromic obesity), using cellular and animals (e.g. zebrafish) models. Our group drives translational studies on rare monogenic disorders leading to developmental abnormalities including malformations, neurogenetic diseases, and inborn errors of lipid and mitochondrial metabolisms. Pharmacological research and preclinical drug screening is also in progress for different diseases (Rubinstein-Taybi syndrome, mitochondria dynamic disorders, hereditary spastic paraplegias). Our team includes complementary scientific (genetics, biochemistry and cell biology), technological (live microscopy, bioenergetics, molecular biology, genomics, zebrafish models, mice models, cell models) and clinical expertises (rare diseases, neurodegenerative disorders, heart dysfunction, anesthesia..). Our laboratory is tightly linked with the clinical department of clinical genetics and the reference center of mitochondrial diseases, so that an effective translational research can occur, based on a close proximity between scientists and clinicians working together in the same group. Our common objective is to understand the physiopathological mechanisms underlying new syndromes with multiple congenital abnormalities identified by the clinical departments associated to our research project at the university hospital. • Research team Didier Lacombe Patrick Babin Benoît Arveiler Rodrigue Rossignol Cyril Goizet Anja Knoll-Gellida Caroline Rooryck-Thambo Isabelle Coupry Karine Nouette-Gaulain Isabelle Vernhet • Selected publications Rheb regulates mitophagy induced by mitochondrial energetic status. Melser S, Chatelain EH, Lavie J, Mahfouf W, Jose C, Obre E, Goorden S, Priault M, Elgersma Y, Rezvani HR, Rossignol R, Bénard G. Cell Metab. 2013 May 7;17(5):719-30. doi: 10.1016/j. cmet.2013.03.014. Epub 2013 Apr 18. spectrum, and potential association with mitochondrial morphofunctional dysfunction. Hum Mutat. 2011; 32(10):1118-27. Alteration of fatty-acid-metabolizing enzymes affects mitochondrial form and function in hereditary spastic paraplegia. Rossignol R and Tesson C and Nawara M and Salih MA, Zaki MS, Al Balwi M, Schule R, Mignot C, Obre E, Bouhouche A, Santorelli FM, Durand CM, Oteyza AC, El-Hachimi KH, Al Drees A, Bouslam N, Lamari F, Elmalik SA, Kabiraj MM, Seidahmed MZ, Esteves T, Gaussen M, Monin ML, Gyapay G, Lechner D, Gonzalez M, Depienne C, Mochel F, Lavie J, Schols L, Lacombe D, Yahyaoui M, Al Abdulkareem I, Zuchner S, Yamashita A, Benomar A, Goizet C, Durr A, Gleeson JG, Darios F, Brice A, Stevanin G. Am J Hum Genet. 2012 Dec 7;91(6):1051-64. Nurden P et al. Thrombocytopenia resulting from mutations in filamin A can be expressed as an isolated syndrome. Blood 2011; 118(22):5928-37. Goizet C, et al. REEP1 mutations in SPG31: frequency, mutational Tingaud-Sequeira A, Ouadah N, Babin PJ. Zebrafish obesogenic test: a tool for screening molecules that target adiposity. J Lipid Res. 2011; 52(9):1765-72. Tingaud-Sequeira A et al. Vitellogenin expression in white adipose tissue in female teleost fish. Biol Reprod. 2012; 86(2):38. Benard G et al. Adaptative Capacity of Mitochondrial Biogenesis and of Mitochondrial Dynamics in Response to Pathogenic Respiratory Chain Dysfunction. Antioxid. Redox. Signal. 2012 Apr 19. Bénard G, et al. Mitochondrial CB1 receptors regulate neuronal energy metabolism. Nat Neurosci. 2012;15(4):558-64. Biochemistry - Genetics │47 cardio thoracic Bronchial remodelling (INserm U1045) www.univ-bordeauxsegalen.fr/fr/recherche/acteurs-dela-recherche/biologie-fondamentale-et-appliquee-a-lamedecine/centre-de-recherche-cardio-thoracique-debordeaux-crctb.html Patrick Berger The project of the team associates human and animal studies in a multidisciplinary approach (physiologists, chest physicians, radiologists, pharmacologists, and paediatricians) with strong interconnection between the team and the clinical investigation center in the hospital Research brief Asthma and chronic obstructive pulmonary disease (COPD) are very frequent inflammatory diseases that are characterized by different patterns of bronchial remodelling. However, characteristics and localization of the increased in Bronchial Smooth Muscle (BSM) mass are different. In COPD, there is a BSM cell hypertrophy which is only present in distal bronchi whereas in asthma, there are both BSM cell hypertrophy and hyperplasia within the entire bronchial tree. Anyhow, BSM remodelling has been associated with a poor prognosis, high morbidity, and deterioration of lung function. As a consequence BSM remodelling should be a target of innovative treatments. Mechanisms of BSM remodeling remain largely unknown even if we previously demonstrated the role of mitochondrial BSM biogenesis (T. Trian. J Exp Med 2007). Recently, we evaluated the relationship between bronchial epithelium and BSM. In particular, the epithelial chitinase YKL-40 induces the proliferation of BSM cells, through a PAR-2 dependant mechanism (Figure A). Moreover, YKL-40 induces BSM cell migration and pseudopods formation (Figure B). • Research team Heading: P Berger Lecturers: Choukroun, Dupin , Fayon, Girodet, Hilbert, Lederlin, Laurent, Marthan, Montaudon, Ozier, Trian, Vargas Post-doc: Carvallo PhD student: Allard, Dournes, Thumerel Eng : Cattiaux, Ousova Tech: Maurat Bara et al. AJRCCM 2012, 185 : 715-22 • Selected publications Girodet PO, Ozier A, Carvalho G, Ilina O, Ousova O, Gadeau AP, Begueret H, Wulff H, Marthan R, Bradding P, Berger P. Ca(2+)-activated K(+) channel-3.1 blocker TRAM-34 attenuates airway remodeling and eosinophilia in a murine asthma model. Am J Respir Cell Mol Biol. 2013 Feb;48(2):212-9 Lederlin M, Ozier A, Dournes G, Ousova O, Girodet PO, Begueret H, Marthan R, Montaudon M, Laurent F, Berger P.In vivo micro-CT assessment of airway remodeling in a flexible OVA-sensitized murine model of asthma. PLoS One. 2012;7(10):e48493. Bara I, Ozier A, Girodet PO, Carvalho G, Cattiaux J, Begueret H, Thumerel M, Ousova O, Kolbeck R, Coyle AJ, Woods J, Tunon de Lara JM, Marthan R, Berger P. Role of YKL-40 in bronchial smooth muscle remodeling in asthma. Am J Respir Crit Care Med. 2012 Apr 1;185(7):715-22 Lederlin M, Laurent F, Portron Y, Ozier A, Cochet H, Berger P, Montaudon M. CT attenuation of the bronchial wall in patients with asthma: comparison with geometric parameters and correlation with function and histologic characteristics. AJR Am J Roentgenol. 2012 Dec;199(6):1226-33. Lederlin M, Laurent F, Dromer C, Cochet H, Berger P, Montaudon M. Mean bronchial wall attenuation value in chronic obstructive pulmonary disease: comparison with standard bronchial parameters and correlation with function. AJR Am J Roentgenol. 2012 Apr;198(4):800-8 Girodet PO, Ozier A, Trian T, Begueret H, Ousova O, Vernejoux JM, Chanez P, Marthan R, Berger P, Tunon de Lara JM. Mast cell adhesion to bronchial smooth muscle in asthma specifically depends on CD51 and CD44 variant 6. Allergy. 2010 Aug;65(8):1004-12 CARDIO THORACIC │51 Endothelial cell Biology (INserm U1045) www.iecb.u-bordeaux.fr/teams/GENOT/ Elisabeth Génot • Research team Elisabeth Génot, DR2 INSERM IJsbrand Kramer, Pr Bordeaux 1 Thomas Daubon, post-doc Anne Leclercq, post-doc Véronique Veillat, post-doc Pirjo SPuul, post-doc Isabel Egaña, PhD student Filipa Curado, PhD student Paolo Ciufici, PhD student • Selected publications Génot E. et al., Fgd1 as a central regulator of extracellular matrix remodelling: Lessons from Faciogenital dysplasia J Cell Sci. 2012 Daubon T. et al,. Invadopodia and rolling-type motility are specific features of highly invasive p190(bcr-abl) leukemic cells. Eur J Cell Biol. 2012 Le Roux-Goglin E. et al., Helicobacter infection induces podosome assembly in primary hepatocytes in vitro. Eur J Cell Biol. 2012;91(3):161. Juin A. et al., Physiological type I collagen organization induces the formation of a novel class of linear invadosomes. Mol Biol Cell. 2012;23:297. Daubon T., et al., The Aarskog-Scott syndrome protein Fgd1 regulates podosome formation and extra-cellular matrix remodeling in transforming growth factor β-stimulated aortic endothelial cells. Mol Cell Biol. 2011;31:4430. Quideau S. et al., Binding of filamentous actin and winding into fibrillar aggregates by the polyphenolic C-glucosidic ellagitannin vescalagin. Angew Chem Int Ed Engl. 2011;50:5099. Saltel F., et al. Invadosomes: intriguing structures with promise. Eur J Cell Biol. 2011;90:100. Kremerskothen, J., et al., ZO-1 modulate podosome formation. FASEB J. 2011, 25(2):505-14. 52 │CARDIO THORACIC TGFß plays an important role in the homeostasis of the vascular system. Analysing the effects of TGFß on the cytoskeleton organization of aortic endothelial cells led us to discover actin-rich structures named podosomes. These are dynamic actin-rich adhesion plasma membrane microdomains endowed with extracellular matrix-degrading activities. Ongoing projects aim at demonstrating the occurrence of podosomes in tissues and determine their role in (patho)physiology. We are also exploring the conditions (cytokine, matrix…), which favor podosome formation. We are working on the elucidation of the molecular mechanisms involved in podosome formation. The RhoGTPase Cdc42 plays a key role in this Figure 1 : TGFβ signaling pathways for podosome formation in endothelial cells. Both canonical (smad) and non canonical (Fgd1) pathways contribute to podosome assembly. process. We have now identified Fgd1 as the guanine exchange factor regulating Cdc42 activation downstream of TGFβ receptors : Fgd1 undergoes Srcdependent tyrosine phosphorylation, translocates to the membrane and works in a complex with cortactin to activate Cdc42 and induce actin polymerization for podosome formation (Fig.1). These findings reveal the involvement of Fgd1 in endothelial cell biology and open up new avenues to study its role in vascular pathophysiology. TGFß is also an inflammatory mediator. In collaboration with C. Varon’s team at U853, we showed that TGFß may induce podosomes in other cells. We demonstrated that Helicobacter pylori promotes podosome formation in murine primary hepatocytes in vitro, and this occurs through the release of TGFβ. Liver cells with podosomes have reduced selfhealing capacities. Helicobacter pylori which colonizes the stomach in about 50% of all humans is well known as a key risk factor in gastric diseases, it may also damage liver, causing cirrhosis and liver cancer. Although it is not yet clear which role podosomes play in the response to bacterial infection, one may expect that in vivo, podosomes in liver cells infected with Helicobacter pylori contribute to the pathological state. Figure 2: A ring of podosomes (at the center of the image) induced by Helicobacter pylori infection in Hepatocellular carcinoma cells. F-actin (red), cortactin (green), vinculin (white), and nuclei (bue). (image, Pirjo Spuul). Pathophysiology of pulmonary circulation (INserm U1045) www.univ-bordeauxsegalen.fr/fr/recherche/acteurs-dela-recherche/biologie-fondamentale-et-appliquee-a-lamedecine/centre-de-recherche-cardio-thoracique-debordeaux-crctb.html Jean Pierre Savineau The main scope of the research of the team relates to pulmonary arterial wall biology, pulmonary arterial hypertension (cellular mechanisms and pharmacological treatment) and the impact of the environment (air pollution) on the pulmonary circulation. Focused on the pathophysiology of the pulmonary circulation, the team works on a real interface between cardiac and pulmonary diseases. It is multidisciplinary constituted by colleagues of diverse trainings (basic scientists, physicians, pharmacists) and of varied disciplines (cellular biology, physiology, pharmacology, toxicology). • Research team C. Guibert, CR1 INSERM B. Muller, JF. Quignard (Prof.) I. Baudrimont, A. Courtois, M. Dubois, T. Ducret, F. Delom, V. Freund-Michel (Lecturers) E Dumas de la Roque (PH) D. Fessart (Post doctoral researcher) G. Gilbert, N. Khoyrattee, T. Papaite (PhD students) J. Cattiau (engineer), H. Crevel (technician) The specific objectives of the team are the followings: 1. To characterize the calcium signalling (TRP, RyR, IP3R channels) in endothelial and smooth muscle cells in physiological conditions and during pulmonary arterial hypertension. 2. To study the cross talk between endothelial and smooth muscle cells in the pulmonary arterial wall through myoendothelial junctions (connexins). 3. To assess innovative treatment in pulmonary arterial hypertension. 4. To study the impact of nanoparticles from air pollution on the pulmonary circulation • Selected publications Billaud M, Marthan R, Savineau JP, Guibert C. Vascular smooth muscle modulates endothelial control of vasoreactivity via reactive oxygen species production through myoendothelial communications. PLoS One. 2009 4(7):e6432. Methodologies used Experiments are conducted (i) on freshly isolated or cultured vascular cells and tissues (fragments of PA) for molecular biology (PCR, real-time PCR), cellular biology (electron microscopy, Western blotting, flow cytometry, siRNA, proliferation, migration and apoptosis assays), electrophysiology (patch clamp), calcium imaging (fura2, fluo3), immunochemistry, quantitative proteomic (label-Free); (ii) on isolated and more integrated vascular preparations (arterial rings, cannulated and pressurized micro vessels) from both animal and human tissues for reactivity experiments and electron paramagnetic resonance measurements for NO and superoxyde anion; (iii) in whole animal for in vivo investigations (Doppler echocardiography) both wild type and transgenic animals. The team has developed animal models for pulmonary arterial hypertension (chronically hypoxic rat and mice, monocrotaline-treated rat) and also performs experiments on human tissues (pulmonary vessels) through a collaborative project with the university hospital of Bordeaux. Delannoy E, Courtois A, Freund-Michel V, Leblais V, Marthan R, Muller B. Hypoxiainduced hyperreactivity of pulmonary arteries: role of cyclooxygenase-2, isoprostanes, and thromboxane receptors. Cardiovasc Res. 2010, 85(3):582-92. Ducret T, El Arrouchi j, Courtois A, Quignard JF, Marthan R, Savineau JP. Characterization of stretch-activated channels in rat intrapulmonary arterial smooth muscle cells. Cell Calcium, 2010, 2251-259. Chevalier M, Gilbert G, Lory P, Marthan R, Quignard JF, Savineau JP. Dehydroepiandrosterone (DHEA) inhibits voltage-gated T-type calcium channels. Biochemical Pharmacology, 2012, 83(11):1530-1539. Below: diffusion of a green fluorescent dye from the endothelium to the smooth muscle via cell-to-cell communications in basal conditions (left) and such diffusion was blocked following one hour incubation with a specific connexion peptide blocker 37-43Gap 27 (right). Scale bars are 15 µm. (from Billaud et al, 2009, Plos one) Dumas de La Roque E, Bellance N, Rossignol R, Begueret H, Billaud M, dos Santos P, Ducret T, Marthan R, Dahan D, Ramos-Barbón D, Amor-Carro Ó, Savineau JP, Fayon M. Dehydroepiandrosterone reverses chronic hypoxia/reoxygenationinduced right ventricular dysfunction in rats. European Respiratory Journal. 2012;40(6):1420-9 CARDIO THORACIC │53 Cardiovascular adaptation to ischemia (INserm U1034) www.u1034.bordeaux.inserm.fr/ Thierry Couffinhal Our team combines tools of genetics and of in vivo and in vitro imagery to characterize and follow in time and space the role of target genes in the vascular morphogenesis. • Research team Researchers: JM Daniel-Lamazière, C. Duplaa, A. Gadeau, MA Renault ATIP-AVENIR : C. James University Bordeaux Segalen : L. Barandon, D. Breilh, T. Couffinhal, P. Dufourcq, K. Latry, A. Ouattara, E. Roux, MC Saux, F. Sztarck, JF Viallard Postdoc fellows: F. Larrieu, A. Gourgues, J. Vieira-Dias Technicians: 5 PhD students: 6 • Selected publications Normal tissue functioning depends on adequate supply of oxygen through blood vessels. Atherosclerosis (i.e. lesion of large vessels or macroangiopathy) or diabetes, and hypertension (i.e. lesions of small vessels or microangiopathy) reduce vessel lumen diameter and blood perfusion, leading to tissue ischemia. There are major causes of mortality by myocardial angina, infarction, or stroke as well as morbidity by hindlimb arteriopathy, nephropathy, blindness, pre-eclampsia, neurodegeneration and osteoporosis. Our project focuses on 4 complementary aspects of vessel formation: • Understand the mechanisms that maintain or favor formation of vessels in post-ischemic tissue. In response to ischemia, new blood vessels form and a collateral circulation are established in order to compensate for the lack of perfusion. During the regeneration and renewal of adult tissue, the formation of the vessels is regulated by a combination of signaling factors, of guidance proteins and by local mechanical interactions between cells. A new concept is proposed that the need for regeneration reactivates embryonic processes, redeploying many of the same molecular regulators. Over the past few years, our team showed that the Hedgehog (Hh) and the Wnt/Frizzled pathways take a center stage position. We showed that Wnt and Hh signaling pathways, reactivated in adult ischemic tissues, play a key role in coordinating vessel formation, maturation, remodeling and 3D organization of the vascular network and in controlling cardio protective response after ischemic events. Our aim is to characterize how these two pathways modulate vascular network formation and organization and to identify how to modulate them to improve ischemic tissue repair. • Platelets and endothelium are important players in the regulation of hemostasis and angiogenesis and it has been reported that platelets can influence the properties of endothelial cells. We hypothesize that endothelial cells can be abnormal in patients with platelet disorders, i.e.hyperactivated, leaky or hyperproliferative. They would be responsible for pathological plateletendothelium interactions, thus giving rise to inappropriate thrombosis, bleeding or neoangiogenesis. Using pharmacological and experimental approaches, we explore general vascular side effects of drugs that may impair angiogenic pathways. Using an epidemiological approach, we propose to study the cardiovascular side effects of these newly delivered treatments. Pre-clinical experiments of stem cell angiogenic therapy are developed in large animal, using pre-conditioned stem cells and human clinical tools of evaluation. Effective organ blood flow, perfusion and bio-energetic status in situation of ischemic heart hemodynamic failure are studied in experimental model and human clinical trial. Renault MA, Chapouly C, Yao Q, Larrieu-Lahargue F, Vandierdonck S, Reynaud A, Petit M, Jaspard-Vinassa B, Belloc I, Traiffort E, Ruat M, Duplàa C, Couffinhal T, Desgranges C, Gadeau AP. Desert hedgehog promotes ischemia-induced angiogenesis by ensuring peripheral nerve survival. Circ Res. 2013 Mar 1;112(5):762-70 Descamps, B., R. Sewduth, N. Ferreira Tojais, B. Jaspard, A Reynaud, F. Sohet, P. Lacolley, C. Allieres, J.M. Lamaziere, C. Moreau, P. Dufourcq, T. Couffinhal, and C. Duplaa Frizzled 4 Regulates Arterial Network Organization Through Noncanonical Wnt/Planar Cell Polarity Signaling. Circulation Research, 2012 ;110, 47-58 Barandon L, Casassus F, Leroux L, Moreau C, Allières C, Daniel Lamazière JM, Dufourcq P, Couffinhal T, Duplàa C. Secreted Frizzled-Related Protein-1 Improves Postinfarction Scar 54 │CARDIO THORACIC Formation Through a Modulation of Inflammatory Response. Arterioscler Thromb Vasc Biol, 2011;31, e80-e87 Josefsson EC, James C, Henley KJ, Debrincat MA, Rogers KL, Dowling MR, White MJ, Kruse EA, Lane RM, Ellis S, Nurden P, Mason KD, O’Reilly LA, Roberts AW, Metcalf D, Huang DC, Kile BT. Megakaryocytes possess a functional intrinsic apoptosis pathway that must be restrained to survive and produce platelets. J Exp Med. 2011. 208:2017-31. Renault MA, Robbesyn F, Réant P, Douin V, le Daret D, Allières C, Belloc I, Couffinhal T, Arnal JF, Klingel K, Desgrange C, Dos Santos P, Charpentier F and Gadeau AP. Osteopontin Expression in Cardiomyocytes Induces Dilated Cardiomyopathy. Circ Heart Failure, 2010.14(3), 431-439 Technology Platforms cytometry • Research team Flow cytometry core facility with high speed cell sorter www.transbiomed.u-bordeaux2.fr/pages/cytometrieplateforme. html The flow cytometry core facility provides three multicolor flow cytometer analysers with high throughput samplers and a four way high speed cell sorter with an automated cell deposit unit. Available lasers are 375, 405, 488, 560 and 640nm (see table) giving acces to all the flow cytometry applications. A dedicated engineer and a technician operate the service. Scientific manager Julie Déchanet-Merville DR Services High speed four way sorting and cloning on BD FACSAria Multicolor flow cytometer analysis with high throughput samplers on Canto, CantoII and Fortessa Individual training for the use of the analysers and Diva software Advice on the preparation of samples for analysis or sorting for all applications : surface or intracellular immunophenotyping, cell cycle, apotosis, viability, calcium flux, cytokine mutiplexing, GFP and reporter genes, phosphoflow... Daylong scientific conferences focused on topics involving flow cytometry techniques. Equipment Technical officer Vincent Pitard IR Technician Santiago Gonzalez Laboratory • Contact : Vincent Pitard Santiago Gonzalez : [email protected] Main lab with 3 cytometers and 4 computers for data analysis. All the computers are connected on a server for data storage and file sharing. Tel : 05 57 57 57 05 Cell sorter in a biological safety laboratory adapted for sterile cell culture. 58 │cytometry histopathology The histopathology platform www.transbiomed.u-bordeaux2.fr/pages/Histologie.html • Contact : Nathalie Dugot-Senant [email protected] • Location The platform is hosted by the INSERM U1053 “Physiopathologie du cancer du foie” 60 │histopathology The purpose of this platform is to provide the scientists with an access to the equipment and know-how for processing tissue samples for histology and immunohistochemistry. Available equipment includes notably a Shandon Citadel 1000 tissue processor, a TBS 88-MEDITE paraffin inclusion system, several microtomes and a DAKO Autostainer. The offer includes counseling, training of the users as well as the realization of a whole range of services: help with sampling the tissues, freezing, fixation, inclusion, sectioning, histology and immunohistochemistry. Laboratory P3 Level 3 safety laboratory www.transbiomed.u-bordeaux2.fr/pages/P3/labop3.html • Research team Michel Ventura Directeur de recherche CNRS • Contact Michel Ventura [email protected] 62 │Laboratory P3 The level 3 safety laboratory offers the possibility to work with class 3 pathogens under adequate safe conditions. University scientific research groups but also external users are welcomed to use this facility after a specific training. Analysis and screening of inhibitors, development of lentiviral vectors as well as fundamental studies on the mechanisms of replication of some of these pathogens can be performed in this L3 lab. Four boxes are located around a central room containing 3 freezers, two at -80°C and one at -135°C freezer. They ensure the conservation of the samples and the different infected cell lines. An ultracentrifuge is also available. Each one of the boxes contains the necessary equipment for pathogens manipulation (class II PSM, microscope and incubators). The working areas, separated by a double SAS which ensures the pathogens containment, are classified under ZRR (Zone à Régime Restrictif) conditions for safety purposes. Safe processing of the waste is ensured by a double entries autoclave. Vectorology Vectorology platform www.transbiomed.u-bordeaux2.fr/pages/vectorologie.html • Research team Technical officer : Véronique GUYONNET DUPERAT (IE1 INSERM- US005) Scientific manager : François MOREAU-GAUDRY (PU-PH-U1035) Technician : Alice Bibeyran (AI INSERM – US005) • Contact [email protected] [email protected] Tel 0557571602 • Location The platform is hosted by the INSERM U1035 “Biothérapies des maladies génétiques et du cancer” 64 │Vectorology The vectorology platform is an academic structure for the production of Lentiviral particles. Lentiviral vectors are tools of choice for gene transfer. They have the particularity to transduce efficiently a large type of cells including primary stem cells (neurons, retina, HSC). They allow stable and efficient integration of DNA sequences (reporter genes, cDNA, Sh/ miRNA). The power of this approach and its plasticity explain the success of this platform. The main activities of the vectorology platform are the production of lentiviral vectors for over-expression of gene or knock-down of gene expression. The platform offer a large choice of lentiviral vectors for constitutive or inducible expression. Offered Services • Advice and assistance in gene transfer (choice of vector, technical support for cloning and lentiviral infection) • Production of defective lentiviral particules (batch of 107 to 109 particules/ml). • Titration of lentiviral particules. The infectious titer is determined by FACS for various fluorescent genes (GFP, CFP, dsRed).The quantification of physical particles was made using P24 ELISA. • Bio-safety test. A PCR-test is achieved to verify the absence of replicative virus on each batch of virus encoding for an insert of type B to scale down the vector preparation to safety level 2, according to the HCB guidelines. • Development of new lentiviral vectors to propose innovative tools. • Quantitative PCR technique for estimation of provirus integrated copies number after gene transfer. • LAM (linear amplification–mediated) - PCR technique for sequencing proviral integration sites. Equipment L2, L3 laboratory SFR TransBioMed www.transbiomed.u-bordeaux2.fr