MiP2013: Difference between revisions
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| [[Bandmann O|Oliver Bandmann]]||Sheffield Institute for Translational Neuroscience, UK||''TigarB'' causes mitochondrial dysfunction and neuronal loss in PINK1 deficiency|| Oral | | [[Bandmann O|Oliver Bandmann]]||Sheffield Institute for Translational Neuroscience, UK||''TigarB'' causes mitochondrial dysfunction and neuronal loss in PINK1 deficiency|| Oral | ||
|- | |- | ||
| [[Beach A|Adam Beach]]||Concordia University, Montreal, CA||Lithocholic acid delays aging in yeast and exhibits an anti-tumor effect in human cells by altering mitochondrial composition, structure and function|| | | [[Beach A|Adam Beach]]||Concordia University, Montreal, CA||Lithocholic acid delays aging in yeast and exhibits an anti-tumor effect in human cells by altering mitochondrial composition, structure and function||Poster | ||
|- | |- | ||
| [[Bir A|Aritri Bir]]||Education & Research IPGMER, Kolkata, IN||α-Synuclein mediated alterations in mitochondrial oxidative phosphorylation system: implications in the pathogenesis of Parkinson’s disease|| | | [[Bir A|Aritri Bir]]||Education & Research IPGMER, Kolkata, IN||α-Synuclein mediated alterations in mitochondrial oxidative phosphorylation system: implications in the pathogenesis of Parkinson’s disease||Poster | ||
|- | |- | ||
| [[Blier PU|Pierre Blier]]||Université du Québec à Rimouski, CA||Holding our breath in our modern world: are mitochondria keeping the pace with global changes?||Oral | | [[Blier PU|Pierre Blier]]||Université du Québec à Rimouski, CA||Holding our breath in our modern world: are mitochondria keeping the pace with global changes?||Oral | ||
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| [[Brandt T|Tobias Brandt]]||Max-Planck-Institute of Biophysics, Frankfurt a. M., DE||Structure and function of aged mouse mitochondria|| Oral | | [[Brandt T|Tobias Brandt]]||Max-Planck-Institute of Biophysics, Frankfurt a. M., DE||Structure and function of aged mouse mitochondria|| Oral | ||
|- | |- | ||
| [[Calzia E|Enrico Calzia]]||Universitätsklinikum Ulm, DE||Studying mitochondrial effects of sulfide. Does the species matter?|| | | [[Calzia E|Enrico Calzia]]||Universitätsklinikum Ulm, DE||Studying mitochondrial effects of sulfide. Does the species matter?||Oral | ||
|- | |- | ||
| [[Cavalcanti de Albuquerque JP|Joao Paulo Cavalcanti de Albuquerque]]||Universidade Federal do Rio de Janeiro, BR||Skeletal muscle mitochondrial function in ovariectomized rats: a time course study and the role of estrogen replacement|| | | [[Cavalcanti de Albuquerque JP|Joao Paulo Cavalcanti de Albuquerque]]||Universidade Federal do Rio de Janeiro, BR||Skeletal muscle mitochondrial function in ovariectomized rats: a time course study and the role of estrogen replacement||Poster | ||
|- | |- | ||
| [[Chicco AJ|Adam Chicco]]||Colorado State University, Fort Collins, US||Comparative muscle mitochondrial physiology of the northern elephant seal; Poster: Remodeling of skeletal muscle mitochondria in response to exercise training in taz shRNA mouse model of human Barth syndrome||Oral | | [[Chicco AJ|Adam Chicco]]||Colorado State University, Fort Collins, US||Comparative muscle mitochondrial physiology of the northern elephant seal; Poster: Remodeling of skeletal muscle mitochondria in response to exercise training in taz shRNA mouse model of human Barth syndrome||Oral | ||
|- | |- | ||
| [[Chung D|Dillon Chung]]||University of British Columbia, Vancouver, CA||The effect of low-temperature acclimation on mitochondrial function in the common killifish (''Fundulus heteroclitus''), a top-down elasticity analysis ||'' | | [[Chung D|Dillon Chung]]||University of British Columbia, Vancouver, CA||The effect of low-temperature acclimation on mitochondrial function in the common killifish (''Fundulus heteroclitus''), a top-down elasticity analysis ||''see Patricia Schulte'' | ||
|- | |- | ||
| [[Christen F|Felix Christen]]||Université du Québec à Rimouski, CA||Modulation in ROS production in arctic charr heart mitochondria: Is Astaxanthine only good for the pink color?|| | | [[Christen F|Felix Christen]]||Université du Québec à Rimouski, CA||Modulation in ROS production in arctic charr heart mitochondria: Is Astaxanthine only good for the pink color?||Poster | ||
|- | |- | ||
| [[Darveau CA|Charles Darveau]]||University of Ottawa, CA||Diversity and evolution of mitochondrial metabolism: Proline as a metabolic reward for pollinators|| Oral | | [[Darveau CA|Charles Darveau]]||University of Ottawa, CA||Diversity and evolution of mitochondrial metabolism: Proline as a metabolic reward for pollinators|| Oral | ||
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| [[Dela F|Flemming Dela]]||University of Copenhagen, DK||Statins affects skeletal muscle mitochondrial respiration|| part-time | | [[Dela F|Flemming Dela]]||University of Copenhagen, DK||Statins affects skeletal muscle mitochondrial respiration|| part-time | ||
|- | |- | ||
| [[Dlaskova A|Andrea Dlaskova]]||Academy of Sciences of the Czech Rep., Prague, CZ||Distribution of nucleoids of mitochondrial DNA|| | | [[Dlaskova A|Andrea Dlaskova]]||Academy of Sciences of the Czech Rep., Prague, CZ||Distribution of nucleoids of mitochondrial DNA||Poster | ||
|- | |- | ||
| [[Dungel P|Peter Dungel]]||Ludwig Boltzmann Institute, Vienna, AT||Iron-mediated injury of mitochondria is attenuated by nitrite|| Oral | | [[Dungel P|Peter Dungel]]||Ludwig Boltzmann Institute, Vienna, AT||Iron-mediated injury of mitochondria is attenuated by nitrite|| Oral | ||
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| [[Dzialowski_EM|Edward Dzialowski]]||University of North Texas, US||Mitochondria Function and the Development of Endothermy in the Precocial Pekin Duck ''(Anas pekin)''||Oral | | [[Dzialowski_EM|Edward Dzialowski]]||University of North Texas, US||Mitochondria Function and the Development of Endothermy in the Precocial Pekin Duck ''(Anas pekin)''||Oral | ||
|- | |- | ||
| [[Eckert GP|Gunter Eckert]]||Goethe-University of Frankfurt am Main, DE||Rice bran extract protects from mitochondrial dysfunction in the brain|| | | [[Eckert GP|Gunter Eckert]]||Goethe-University of Frankfurt am Main, DE||Rice bran extract protects from mitochondrial dysfunction in the brain||Poster | ||
|- | |- | ||
| [[Eigentler A|Andrea Eigentler]]||Medical University Innsbruck, AT|| || | | [[Eigentler A|Andrea Eigentler]]||Medical University Innsbruck, AT|| || | ||
|- | |- | ||
| [[Eira da Costa AC|Ana Carina Eira da Costa]]||University of Leicester, UK||''Drosophila Trap1'' protects against mitochondrial dysfunction in a PINK1/parkin model of Parkinson’s disease|| | | [[Eira da Costa AC|Ana Carina Eira da Costa]]||University of Leicester, UK||''Drosophila Trap1'' protects against mitochondrial dysfunction in a PINK1/parkin model of Parkinson’s disease||Poster | ||
|- | |- | ||
| [[Fokin A|Andrej Fokin]]||Lithuanian Sports University, Kaunas, LT||H55N polymorphism is associated with impaired respiration in isolated mitochondria from liver and muscles of mice|| | | [[Fokin A|Andrej Fokin]]||Lithuanian Sports University, Kaunas, LT||H55N polymorphism is associated with impaired respiration in isolated mitochondria from liver and muscles of mice||Poster | ||
|- | |- | ||
| [[Persson MF|Malou Friederich-Persson]]||Uppsala University, SE||Potassium controls rat mitochondria function; in vivo and in vitro considerations|| | | [[Persson MF|Malou Friederich-Persson]]||Uppsala University, SE||Potassium controls rat mitochondria function; in vivo and in vitro considerations||Poster | ||
|- | |- | ||
| [[Galina A|Antonio Galina]]||Federal University of Rio de Janeiro, BR||Effects of antitumor alkylating agent 3-bromopyruvate on energy transducing pathways in hepatoma HepG2, liver mitochondria and SERCA: Is There Any Role for Mitochondrial Hexokinase Activity||Oral | | [[Galina A|Antonio Galina]]||Federal University of Rio de Janeiro, BR||Effects of antitumor alkylating agent 3-bromopyruvate on energy transducing pathways in hepatoma HepG2, liver mitochondria and SERCA: Is There Any Role for Mitochondrial Hexokinase Activity||Oral | ||
|- | |- | ||
| [[Garcia-Rives G|Gerardo Garcia-Rives]]||Medical School, Tec de Monterrey, MX||Regulation of mitochondrial permeability transition by Sirt3-catalyzed cyclophilin D deacetylation and its relevance for ventricular dysfunction in metabolic syndrome|| | | [[Garcia-Rives G|Gerardo Garcia-Rives]]||Medical School, Tec de Monterrey, MX||Regulation of mitochondrial permeability transition by Sirt3-catalyzed cyclophilin D deacetylation and its relevance for ventricular dysfunction in metabolic syndrome||Poster | ||
|- | |- | ||
| [[Garcia-Roves PM|Pablo Garcia-Roves]]||Institut d'Investigacions Biomediques August Pi Sunyer (IDIBAPS) Hospital Clinic de Barcelona, ES||Mitochondrial respiration in different mouse tissues under patho-physiological states||Oral | | [[Garcia-Roves PM|Pablo Garcia-Roves]]||Institut d'Investigacions Biomediques August Pi Sunyer (IDIBAPS) Hospital Clinic de Barcelona, ES||Mitochondrial respiration in different mouse tissues under patho-physiological states||Oral | ||
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| [[Gellerich FN|Frank Norbert Gellerich]]||Universitätsklinikum Magdeburg, DE||The mitochondrial gas pedal, a unique property of neurons exists also in heart and skeletal muscle but not in astrocytes. New evidences by in silico investigations and (patho-)physiological consequences|| Oral | | [[Gellerich FN|Frank Norbert Gellerich]]||Universitätsklinikum Magdeburg, DE||The mitochondrial gas pedal, a unique property of neurons exists also in heart and skeletal muscle but not in astrocytes. New evidences by in silico investigations and (patho-)physiological consequences|| Oral | ||
|- | |- | ||
| [[Gizatullina Z|Zemfira Gizatullina]]||Universitätsklinikum Magdeburg, DE||The mitochondrial gas pedal, a unique property of neurons exists also in heart and skeletal muscle but not in astrocytes. New evidences by in silico investigations and (patho-)physiological consequences|| | | [[Gizatullina Z|Zemfira Gizatullina]]||Universitätsklinikum Magdeburg, DE||The mitochondrial gas pedal, a unique property of neurons exists also in heart and skeletal muscle but not in astrocytes. New evidences by in silico investigations and (patho-)physiological consequences||''see Frank Gellerich'' | ||
|- | |- | ||
| [[Glaser V|Viviane Glaser]]||Federal University of Santa Catarina, BR||Methylglyoxal and advanced glycation end products disrupt mitochondrial dynamics and metabolism in c6 astroglioma cells|| | | [[Glaser V|Viviane Glaser]]||Federal University of Santa Catarina, BR||Methylglyoxal and advanced glycation end products disrupt mitochondrial dynamics and metabolism in c6 astroglioma cells||Poster | ||
|- | |- | ||
| [[Glick GD|Gary Glick]]||Lycera Corporation, Ann Arbor, MI, US|| || | | [[Glick GD|Gary Glick]]||Lycera Corporation, Ann Arbor, MI, US|| || | ||
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| [[Gnaiger E|Erich Gnaiger]]||Medical University Innsbruck, AT||The Mitochondrial Physiology Map - [[MiPMap]]||Oral | | [[Gnaiger E|Erich Gnaiger]]||Medical University Innsbruck, AT||The Mitochondrial Physiology Map - [[MiPMap]]||Oral | ||
|- | |- | ||
| [[Gorbacheva O|Olga Gorbacheva]]||Institute of Theoretical and Experimental Biophysics RAS, Pushchino, RU||Cyclization of potassium in rat liver mitochondria in the functioning mitochondrial ATP-dependent potassium channel and its possible role in cardioprotection|| | | [[Gorbacheva O|Olga Gorbacheva]]||Institute of Theoretical and Experimental Biophysics RAS, Pushchino, RU||Cyclization of potassium in rat liver mitochondria in the functioning mitochondrial ATP-dependent potassium channel and its possible role in cardioprotection||Poster | ||
|- | |- | ||
| [[Hansell P|Peter Hansell]]||Uppsala University, SE|||| | | [[Hansell P|Peter Hansell]]||Uppsala University, SE|||| | ||
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| [[Hand SC|Steven Hand]]||LSU, Baton Rouge, Lousiana, US||Defense against ATP depletion during the energy-limited state of diapause.||Oral | | [[Hand SC|Steven Hand]]||LSU, Baton Rouge, Lousiana, US||Defense against ATP depletion during the energy-limited state of diapause.||Oral | ||
|- | |- | ||
| [[Hashimi H|Hassan Hashimi]]||Academy of Sciences of the Czech Rep., Ceske Budejovice, CZ||Ancestral function of Letm1 as determined in the evolutionary diverged ''Trypanosoma brucei''|| | | [[Hashimi H|Hassan Hashimi]]||Academy of Sciences of the Czech Rep., Ceske Budejovice, CZ||Ancestral function of Letm1 as determined in the evolutionary diverged ''Trypanosoma brucei''||Poster | ||
|- | |- | ||
| [[Heidler J|Juliana Heidler]]||JW-Goethe University, Frankfurt, DE|| Functional plasticity of interfibrillary mitochondria (IFM) as cardiac response mechanism to stress||Oral | | [[Heidler J|Juliana Heidler]]||JW-Goethe University, Frankfurt, DE|| Functional plasticity of interfibrillary mitochondria (IFM) as cardiac response mechanism to stress||Oral | ||
|- | |- | ||
| [[Hendricks E|Eric Hendricks]]||Eastern Illinois University, Charleston, US||Bioenergetics of permeabilized and intact nerve cell terminals from ApoE deficient and wild type mice|| | | [[Hendricks E|Eric Hendricks]]||Eastern Illinois University, Charleston, US||Bioenergetics of permeabilized and intact nerve cell terminals from ApoE deficient and wild type mice||Poster | ||
|- | |- | ||
| [[Hickey AJ|Anthony Hickey]]||University of Auckland, NZ||Mitochondria in a changing climate? The role of mitochondrial in hyperthermic heart failure in different fish species||Oral | | [[Hickey AJ|Anthony Hickey]]||University of Auckland, NZ||Mitochondria in a changing climate? The role of mitochondrial in hyperthermic heart failure in different fish species||Oral | ||
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| [[Jezek P|Petr Jezek]]||Academy of Sciences of the Czech Rep., Prague, CZ||Antioxidant synergy of mitochondrial uncoupling protein UCP2 and phospholipase iPLA<sub>2</sub>γ||Oral | | [[Jezek P|Petr Jezek]]||Academy of Sciences of the Czech Rep., Prague, CZ||Antioxidant synergy of mitochondrial uncoupling protein UCP2 and phospholipase iPLA<sub>2</sub>γ||Oral | ||
|- | |- | ||
| [[Keijer J|Jaap Keijer]]||Wageningen University, NL||Three non-invasive methods to measure metabolic health in mice using indirect calorimetry|| | | [[Keijer J|Jaap Keijer]]||Wageningen University, NL||Three non-invasive methods to measure metabolic health in mice using indirect calorimetry||Poster | ||
|- | |- | ||
| [[Koopman WJ|Werner Koopman]]||Radboud University Medical Centre, Nijmegen, NL||Developing novel treatment strategies for mitochondrial disease||Oral | | [[Koopman WJ|Werner Koopman]]||Radboud University Medical Centre, Nijmegen, NL||Developing novel treatment strategies for mitochondrial disease||Oral | ||
|- | |- | ||
| [[Kotwica A|Aleksandra Kotwica]]||University of Cambridge, UK||Mitochondrial respiration in heart and soleus of ob/ob mice|| | | [[Kotwica A|Aleksandra Kotwica]]||University of Cambridge, UK||Mitochondrial respiration in heart and soleus of ob/ob mice||Oral | ||
|- | |- | ||
| [[Korotkov SM|Sergey Korotkov]]||Academy of Sciences, St Petersburg, RU||Thallium(I) induces the mitochondrial permeability transition pore in Ca<sup>2+</sup>-loaded rat liver mitochondria|| | | [[Korotkov SM|Sergey Korotkov]]||Academy of Sciences, St Petersburg, RU||Thallium(I) induces the mitochondrial permeability transition pore in Ca<sup>2+</sup>-loaded rat liver mitochondria|| Poster | ||
|- | |- | ||
| [[Kozlov A|Andrey Kozlov]]||Ludwig Boltzmann Institute, Vienna, AT||Regulatory role of mitochondrial ROS upon inflammation||Oral | | [[Kozlov A|Andrey Kozlov]]||Ludwig Boltzmann Institute, Vienna, AT||Regulatory role of mitochondrial ROS upon inflammation||Oral | ||
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| [[Lundby S|Stine Lundby]]||University of Zurich, CH|| || | | [[Lundby S|Stine Lundby]]||University of Zurich, CH|| || | ||
|- | |- | ||
| [[Lyabakh KG|Katherine Lyabakh]]||Glushkov Institute of Cybernetics National Academy of Sciences, Kiev, UA|| Changes in oxidative power and intracellular redistribution of mitochondria can regulate tissue pO<sub>2</sub> and oxygen consumption rate under circulatory hypoxia.|| | | [[Lyabakh KG|Katherine Lyabakh]]||Glushkov Institute of Cybernetics National Academy of Sciences, Kiev, UA|| Changes in oxidative power and intracellular redistribution of mitochondria can regulate tissue pO<sub>2</sub> and oxygen consumption rate under circulatory hypoxia.||Poster | ||
|- | |- | ||
| [[Makrecka M|Marina Makrecka]]||Riga Stradins University, Riga,LV|| The accumulation of long chain acyl-carnitines is a major cause of mitochondrial damage during ischemia|| | | [[Makrecka M|Marina Makrecka]]||Riga Stradins University, Riga,LV|| The accumulation of long chain acyl-carnitines is a major cause of mitochondrial damage during ischemia||Poster | ||
|- | |- | ||
| [[Mark FC|Felix Mark]]||Alfred Wegener Institute for Polar and Marine Search, Bremerhaven, DE|| || | | [[Mark FC|Felix Mark]]||Alfred Wegener Institute for Polar and Marine Search, Bremerhaven, DE|| || | ||
|- | |- | ||
| [[Matallo J|Jose Matallo]]||Universitätsklinikum Ulm, DE|| Effects of Mechanical Ventilation after Blunt Chest Trauma on Diaphragmatic Mitochondrial Respiration in Chronically Cigarette Smoke Exposed Mice; A Clinically Relevant Model?|| | | [[Matallo J|Jose Matallo]]||Universitätsklinikum Ulm, DE|| Effects of Mechanical Ventilation after Blunt Chest Trauma on Diaphragmatic Mitochondrial Respiration in Chronically Cigarette Smoke Exposed Mice; A Clinically Relevant Model?||Poster | ||
|- | |- | ||
| [[Menze MA|Michael Menze]]||Eastern Illinois University, Charleston, US||Group1 LEA protein ameliorates inhibition of mitochondrial respiration in Drosophila melanogaster Kc167 cells and isolated mitochondria||Oral | | [[Menze MA|Michael Menze]]||Eastern Illinois University, Charleston, US||Group1 LEA protein ameliorates inhibition of mitochondrial respiration in Drosophila melanogaster Kc167 cells and isolated mitochondria||Oral | ||
|- | |- | ||
| [[Muller AP|Alexandre Pastoris Muller]]||Universidade Federal do Rio Grande do Sul, Porto Alegre, BR||Insulin prevents mitochondrial generation of H<sub>2</sub>O<sub>2</sub> in rat brain || | | [[Muller AP|Alexandre Pastoris Muller]]||Universidade Federal do Rio Grande do Sul, Porto Alegre, BR||Insulin prevents mitochondrial generation of H<sub>2</sub>O<sub>2</sub> in rat brain ||Poster | ||
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| [[Munro D|Daniel Munro]]||Université du Québec à Rimouski, CA||Mitochondrial membrane of the longest-lived metazoan (''A.islandica'') are lipoxidation-resistant||Oral | | [[Munro D|Daniel Munro]]||Université du Québec à Rimouski, CA||Mitochondrial membrane of the longest-lived metazoan (''A.islandica'') are lipoxidation-resistant||Oral | ||
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| [[Oliveira MF|Marcus Oliveira]]||Universidade Federal do Rio de Janeiro, BR|| Comparative mitochondrial physiology in blood feeding insect vectors and parasites||Oral | | [[Oliveira MF|Marcus Oliveira]]||Universidade Federal do Rio de Janeiro, BR|| Comparative mitochondrial physiology in blood feeding insect vectors and parasites||Oral | ||
|- | |- | ||
| [[Olsen RE|Rolf Erik Olsen]]|| Institute of Marine Research Matre, Matredal, NO|| Comparative study of respiartion in Atlantic salmon (''Salmo salar'', L.) cells and mitochondria from blood, heart, liver, muscle and brain|| | | [[Olsen RE|Rolf Erik Olsen]]|| Institute of Marine Research Matre, Matredal, NO|| Comparative study of respiartion in Atlantic salmon (''Salmo salar'', L.) cells and mitochondria from blood, heart, liver, muscle and brain|| ''see Erik Slinde'' | ||
|- | |- | ||
| [[Paier Pourani J|Jamile Paier-Pourani]]||L. Boltzmann Institute für experimentelle und klinische Traumatologie, Vienna, AT||Feed forward iNOS-mitochondrial ROS loop in Hepatocytes. ||Oral | | [[Paier Pourani J|Jamile Paier-Pourani]]||L. Boltzmann Institute für experimentelle und klinische Traumatologie, Vienna, AT||Feed forward iNOS-mitochondrial ROS loop in Hepatocytes. ||Oral | ||
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| [[Pesta D|Dominik Pesta]]||Yale University School of Medicine, US|||| | | [[Pesta D|Dominik Pesta]]||Yale University School of Medicine, US|||| | ||
|- | |- | ||
| [[Pinkert C|Carl Pinkert]]||Auburn University, Alabama, US|| Murine Modeling of Human Mitochondrial Disease Pathogenesis|| | | [[Pinkert C|Carl Pinkert]]||Auburn University, Alabama, US|| Murine Modeling of Human Mitochondrial Disease Pathogenesis||Poster | ||
|- | |- | ||
| [[Persson P|Patrik Persson]]||Uppsala University, SE||The effects of Angiotensin II on mitochondrial respiration; a role of normoglycemia versus hyperglycemia||Poster | |||
| [[Persson P|Patrik Persson]]||Uppsala University, SE||The effects of Angiotensin II on mitochondrial respiration; a role of normoglycemia versus hyperglycemia|| | |||
|- | |- | ||
| [[Pichaud N|Nicolas Pichaud]]||Université du Québec à Rimouski, CA||Importance of mitochondrial haplotypes in the expression of metabolic phenotypes under different conditions||Oral | | [[Pichaud N|Nicolas Pichaud]]||Université du Québec à Rimouski, CA||Importance of mitochondrial haplotypes in the expression of metabolic phenotypes under different conditions||Oral | ||
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| [[Quistorff B| Björn Quistorff]]||University of Copenhagen, SE|| With type 2 diabetes mitochondrial dysfunction develops earlier in liver than in rat skeletal muscle.||Oral | | [[Quistorff B| Björn Quistorff]]||University of Copenhagen, SE|| With type 2 diabetes mitochondrial dysfunction develops earlier in liver than in rat skeletal muscle.||Oral | ||
|- | |- | ||
| [[Ramos Mendes D|Dionizio Ramos Mendes Filho]]||Federal University of Rio de Janeiro, BR||High intensity interval training (HIIT) induces different responses in respiration and H<sub>2</sub>O<sub>2</sub> production induced by different substrates in three types of permeabilized myofibers.|| | | [[Ramos Mendes D|Dionizio Ramos Mendes Filho]]||Federal University of Rio de Janeiro, BR||High intensity interval training (HIIT) induces different responses in respiration and H<sub>2</sub>O<sub>2</sub> production induced by different substrates in three types of permeabilized myofibers.|| Poster | ||
|- | |- | ||
| [[Rodrigues MF|Mariana Rodrigues]]||Federal University of Rio de Janeiro, BR|| Studies of Bioenergetics Alterations in Breast Cancer Lines Induced by Histone desacetylase inhibitors|| | | [[Rodrigues MF|Mariana Rodrigues]]||Federal University of Rio de Janeiro, BR|| Studies of Bioenergetics Alterations in Breast Cancer Lines Induced by Histone desacetylase inhibitors||Poster | ||
|- | |- | ||
| [[Rossignol R|Rodrigue Rossignol]]||Université Victor Segalen-Bordeaux 2, FR|| ||''part time'' | | [[Rossignol R|Rodrigue Rossignol]]||Université Victor Segalen-Bordeaux 2, FR|| ||''part time'' | ||
|- | |- | ||
| [[Salin K|Karine Salin]]||University of Glasgow, UK||Mitochondrial functioning, a proximate mechanism underlying the pace of life?|| | | [[Salin K|Karine Salin]]||University of Glasgow, UK||Mitochondrial functioning, a proximate mechanism underlying the pace of life?||Poster | ||
|- | |- | ||
| [[Schiffer TA|Tomas Schiffer]]||Karolinska Institute, Stockholm, SE||Dietary Inorganic Nitrate Reduces Basal Metabolic Rate in Man|| | | [[Schiffer TA|Tomas Schiffer]]||Karolinska Institute, Stockholm, SE||Dietary Inorganic Nitrate Reduces Basal Metabolic Rate in Man||Poster | ||
|- | |- | ||
| [[Schulte P|Patricia Schulte]]||University of British Columbia, Vancouver, CA||The effect of low-temperature acclimation on mitochondrial function in the common killifish (''Fundulus heteroclitus''), a top-down elasticity analysis||Oral | | [[Schulte P|Patricia Schulte]]||University of British Columbia, Vancouver, CA||The effect of low-temperature acclimation on mitochondrial function in the common killifish (''Fundulus heteroclitus''), a top-down elasticity analysis||Oral | ||
|- | |- | ||
| [[Selivanov V|Vitaly Selivanov]]||Universitat de Barcelona, ES||Analysis of bifurcation characteristics of the mitochondrial respiratory chain operation and factors determining its specificity for various tissues|| | | [[Selivanov V|Vitaly Selivanov]]||Universitat de Barcelona, ES||Analysis of bifurcation characteristics of the mitochondrial respiratory chain operation and factors determining its specificity for various tissues||Poster | ||
|- | |- | ||
| [[Severin F|Fedor Severin]]||Moscow State University, RU||Mitochondrially-encoded protein Var1 promotes loss of respiratory function in Saccharomyces cerevisiae under stressful conditions|| | | [[Severin F|Fedor Severin]]||Moscow State University, RU||Mitochondrially-encoded protein Var1 promotes loss of respiratory function in Saccharomyces cerevisiae under stressful conditions||Poster | ||
|- | |- | ||
| [[Shabalina IG|Irina Shabalina]]||Stockholm University, Stockholm, SE|| Comparative study of brown and white adipose tissue mitochondria in mice upon cold acclimation||Oral | | [[Shabalina IG|Irina Shabalina]]||Stockholm University, Stockholm, SE|| Comparative study of brown and white adipose tissue mitochondria in mice upon cold acclimation||Oral | ||
|- | |- | ||
| [[Shigaeva M|Maria Shigaeva]]||Insitute of Theoretical and Experimental Biophysics RAS, Pushchino, RU||The role of mitochondrial ATP-dependent potassium channel in the adaptation of organism to stress|| | | [[Shigaeva M|Maria Shigaeva]]||Insitute of Theoretical and Experimental Biophysics RAS, Pushchino, RU||The role of mitochondrial ATP-dependent potassium channel in the adaptation of organism to stress||Poster | ||
|- | |- | ||
| [[Silva Platas C|Christian Silva Platas]]||Medical School, Tec de Monterrey, MX||Modulation of Ca<sup>2+</sup> mitochondrial transport by sorcin|| | | [[Silva Platas C|Christian Silva Platas]]||Medical School, Tec de Monterrey, MX||Modulation of Ca<sup>2+</sup> mitochondrial transport by sorcin||Poster | ||
|- | |- | ||
| [[Skulachev VP|Vladimir Skulachev]]||Moscow State University, RU||SkQ1, the first tool to treat ROS-induced mitochondrial pathologies, which is available in drugstores||Oral | | [[Skulachev VP|Vladimir Skulachev]]||Moscow State University, RU||SkQ1, the first tool to treat ROS-induced mitochondrial pathologies, which is available in drugstores||Oral | ||
|- | |- | ||
| [[Slinde E|Erik Slinde]]||University of Life Science, As, NO|| Comparative study of respiartion in Atlantic salmon (''Salmo salar'', L.) cells and mitochondria from blood, heart, liver, muscle and brain|| | | [[Slinde E|Erik Slinde]]||University of Life Science, As, NO|| Comparative study of respiartion in Atlantic salmon (''Salmo salar'', L.) cells and mitochondria from blood, heart, liver, muscle and brain||Poster | ||
|- | |- | ||
| [[Sparks L|Lauren Sparks]] ||Burnham Institute for Medical Research, Orlando, US|| || | | [[Sparks L|Lauren Sparks]] ||Burnham Institute for Medical Research, Orlando, US|| || | ||
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| [[Tepp K|Kersti Tepp]]||National Institute of Chemical Physics and Biophysics, Tallin, EE|| Bioenergetic aspects of postnatal development of cardiac cells: formation of structure-function relationship||Oral | | [[Tepp K|Kersti Tepp]]||National Institute of Chemical Physics and Biophysics, Tallin, EE|| Bioenergetic aspects of postnatal development of cardiac cells: formation of structure-function relationship||Oral | ||
|- | |- | ||
| [[Treberg JR|Jason Treberg]]||University of Manitoba, Winnipeg, CA|| Consumption of H<sub>2</sub>O<sub>2</sub>: the other side of mitochondrial ROS metabolism|| | | [[Treberg JR|Jason Treberg]]||University of Manitoba, Winnipeg, CA|| Consumption of H<sub>2</sub>O<sub>2</sub>: the other side of mitochondrial ROS metabolism|| Poster | ||
|- | |- | ||
| [[Tretter L|Laszlo Tretter]]||Semmelweis University, Budapest, HU||The effects of methylmalonic acid on alpha-ketoglutarate supported oxidation in isolated brain, heart and liver mitochondria||Oral | | [[Tretter L|Laszlo Tretter]]||Semmelweis University, Budapest, HU||The effects of methylmalonic acid on alpha-ketoglutarate supported oxidation in isolated brain, heart and liver mitochondria||Oral | ||
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| [[Vercesi AE|Anibal Vercesi]]||State University of Campinas, BR||Mitochondrial calcium transport in animal, plant and trypanosomes||Oral | | [[Vercesi AE|Anibal Vercesi]]||State University of Campinas, BR||Mitochondrial calcium transport in animal, plant and trypanosomes||Oral | ||
|- | |- | ||
| [[Volska K|Kristine Volska]] ||Riga Stradins University, Riga, LV|| The inhibitor of L-carnitine biosynthesis protects brain mitochondria against anoxia-reoxygenation injury.|| | | [[Volska K|Kristine Volska]] ||Riga Stradins University, Riga, LV|| The inhibitor of L-carnitine biosynthesis protects brain mitochondria against anoxia-reoxygenation injury.|| Poster | ||
|- | |- | ||
| [[Votion DM|Dominique Votion]]||University of Liège, BE||The challenge of understanding myopathies in horses using permeabilized and cultured equine muscle cells||Oral | | [[Votion DM|Dominique Votion]]||University of Liège, BE||The challenge of understanding myopathies in horses using permeabilized and cultured equine muscle cells||Oral | ||
Line 225: | Line 221: | ||
| [[Wright L|Lauren Wright]]||Dipartimento di Scienze Biomediche, Padova, IT||Calcium regulation of metabolism in adipocytes||Oral | | [[Wright L|Lauren Wright]]||Dipartimento di Scienze Biomediche, Padova, IT||Calcium regulation of metabolism in adipocytes||Oral | ||
|- | |- | ||
| [[Zelenka J|Jaroslav Zelenka]]||Academy of Sciences, Prague, CZ||Response of cancer cells to mitochondrial DNA damage; Poster: Reverse carboxylation glutaminolysis in breast cancer cells|| | | [[Zelenka J|Jaroslav Zelenka]]||Academy of Sciences, Prague, CZ||Response of cancer cells to mitochondrial DNA damage; Poster: Reverse carboxylation glutaminolysis in breast cancer cells||Poster | ||
|- | |- | ||
|} | |} |
Revision as of 20:55, 6 June 2013
9th MiPconference - MiP2013
MiP2013: Comparative Mitochondrial Physiology
Obergurgl, Tyrol, Austria. 2013-Sep-23 to 27
Preliminary titles - max. 124 participants
Work in progress - preliminary assignement of oral/poster presentations
Name | Institution | Title | Presentation |
---|---|---|---|
Nobel laureate Sir John Walker | MRC Mitochondrial Biology Unit, Cambridge, UK | MiP2013 lecture on comparative mitochondrial physiology | Keynote |
Bengt Saltin | Copenhagen Muscle Research Centre, DK | Kjell Johansen lecture | Keynote |
Nivea Días Amoedo | Federal University of Rio de Janeiro, BR | Comparative biochemistry of tumorigenesis: role of mitochondria | Oral |
Odeta Arandarcikaite | Lithuanian University of Health Sciences, Kaunas, LT | The protective effect of NO against ischemia induced brain mitochondrial injury | Oral |
Oliver Bandmann | Sheffield Institute for Translational Neuroscience, UK | TigarB causes mitochondrial dysfunction and neuronal loss in PINK1 deficiency | Oral |
Adam Beach | Concordia University, Montreal, CA | Lithocholic acid delays aging in yeast and exhibits an anti-tumor effect in human cells by altering mitochondrial composition, structure and function | Poster |
Aritri Bir | Education & Research IPGMER, Kolkata, IN | α-Synuclein mediated alterations in mitochondrial oxidative phosphorylation system: implications in the pathogenesis of Parkinson’s disease | Poster |
Pierre Blier | Université du Québec à Rimouski, CA | Holding our breath in our modern world: are mitochondria keeping the pace with global changes? | Oral |
Vilma Borutaite | Kaunas University of Medicine, LT | Mitochondrial response to heart and brain ischemia | Oral |
Frédéric Bouillaud | Universite Paris Descartes, Paris, FR | Adaptation of colonocyte mitochondria to intense hydrogen sulfide exposure | Oral |
Robert Boushel | University of Copenhagen, Copenhagen, DK | O2 delivery, diffusion and mitochondrial respiration components of VO2 during exercise in health and disease | |
Tobias Brandt | Max-Planck-Institute of Biophysics, Frankfurt a. M., DE | Structure and function of aged mouse mitochondria | Oral |
Enrico Calzia | Universitätsklinikum Ulm, DE | Studying mitochondrial effects of sulfide. Does the species matter? | Oral |
Joao Paulo Cavalcanti de Albuquerque | Universidade Federal do Rio de Janeiro, BR | Skeletal muscle mitochondrial function in ovariectomized rats: a time course study and the role of estrogen replacement | Poster |
Adam Chicco | Colorado State University, Fort Collins, US | Comparative muscle mitochondrial physiology of the northern elephant seal; Poster: Remodeling of skeletal muscle mitochondria in response to exercise training in taz shRNA mouse model of human Barth syndrome | Oral |
Dillon Chung | University of British Columbia, Vancouver, CA | The effect of low-temperature acclimation on mitochondrial function in the common killifish (Fundulus heteroclitus), a top-down elasticity analysis | see Patricia Schulte |
Felix Christen | Université du Québec à Rimouski, CA | Modulation in ROS production in arctic charr heart mitochondria: Is Astaxanthine only good for the pink color? | Poster |
Charles Darveau | University of Ottawa, CA | Diversity and evolution of mitochondrial metabolism: Proline as a metabolic reward for pollinators | Oral |
Flemming Dela | University of Copenhagen, DK | Statins affects skeletal muscle mitochondrial respiration | part-time |
Andrea Dlaskova | Academy of Sciences of the Czech Rep., Prague, CZ | Distribution of nucleoids of mitochondrial DNA | Poster |
Peter Dungel | Ludwig Boltzmann Institute, Vienna, AT | Iron-mediated injury of mitochondria is attenuated by nitrite | Oral |
Edward Dzialowski | University of North Texas, US | Mitochondria Function and the Development of Endothermy in the Precocial Pekin Duck (Anas pekin) | Oral |
Gunter Eckert | Goethe-University of Frankfurt am Main, DE | Rice bran extract protects from mitochondrial dysfunction in the brain | Poster |
Andrea Eigentler | Medical University Innsbruck, AT | ||
Ana Carina Eira da Costa | University of Leicester, UK | Drosophila Trap1 protects against mitochondrial dysfunction in a PINK1/parkin model of Parkinson’s disease | Poster |
Andrej Fokin | Lithuanian Sports University, Kaunas, LT | H55N polymorphism is associated with impaired respiration in isolated mitochondria from liver and muscles of mice | Poster |
Malou Friederich-Persson | Uppsala University, SE | Potassium controls rat mitochondria function; in vivo and in vitro considerations | Poster |
Antonio Galina | Federal University of Rio de Janeiro, BR | Effects of antitumor alkylating agent 3-bromopyruvate on energy transducing pathways in hepatoma HepG2, liver mitochondria and SERCA: Is There Any Role for Mitochondrial Hexokinase Activity | Oral |
Gerardo Garcia-Rives | Medical School, Tec de Monterrey, MX | Regulation of mitochondrial permeability transition by Sirt3-catalyzed cyclophilin D deacetylation and its relevance for ventricular dysfunction in metabolic syndrome | Poster |
Pablo Garcia-Roves | Institut d'Investigacions Biomediques August Pi Sunyer (IDIBAPS) Hospital Clinic de Barcelona, ES | Mitochondrial respiration in different mouse tissues under patho-physiological states | Oral |
Bronislav Gavenauskas | Bogomoletz Institute of Physiology, Kiev, UA | Effect of ATP-dependent potassium uptake on reactive oxygen species production in rat brain mitochondria | Oral |
Frank Norbert Gellerich | Universitätsklinikum Magdeburg, DE | The mitochondrial gas pedal, a unique property of neurons exists also in heart and skeletal muscle but not in astrocytes. New evidences by in silico investigations and (patho-)physiological consequences | Oral |
Zemfira Gizatullina | Universitätsklinikum Magdeburg, DE | The mitochondrial gas pedal, a unique property of neurons exists also in heart and skeletal muscle but not in astrocytes. New evidences by in silico investigations and (patho-)physiological consequences | see Frank Gellerich |
Viviane Glaser | Federal University of Santa Catarina, BR | Methylglyoxal and advanced glycation end products disrupt mitochondrial dynamics and metabolism in c6 astroglioma cells | Poster |
Gary Glick | Lycera Corporation, Ann Arbor, MI, US | ||
Erich Gnaiger | Medical University Innsbruck, AT | The Mitochondrial Physiology Map - MiPMap | Oral |
Olga Gorbacheva | Institute of Theoretical and Experimental Biophysics RAS, Pushchino, RU | Cyclization of potassium in rat liver mitochondria in the functioning mitochondrial ATP-dependent potassium channel and its possible role in cardioprotection | Poster |
Peter Hansell | Uppsala University, SE | ||
Steven Hand | LSU, Baton Rouge, Lousiana, US | Defense against ATP depletion during the energy-limited state of diapause. | Oral |
Hassan Hashimi | Academy of Sciences of the Czech Rep., Ceske Budejovice, CZ | Ancestral function of Letm1 as determined in the evolutionary diverged Trypanosoma brucei | Poster |
Juliana Heidler | JW-Goethe University, Frankfurt, DE | Functional plasticity of interfibrillary mitochondria (IFM) as cardiac response mechanism to stress | Oral |
Eric Hendricks | Eastern Illinois University, Charleston, US | Bioenergetics of permeabilized and intact nerve cell terminals from ApoE deficient and wild type mice | Poster |
Anthony Hickey | University of Auckland, NZ | Mitochondria in a changing climate? The role of mitochondrial in hyperthermic heart failure in different fish species | Oral |
Graham Holloway | University of Guelph, CA | tentative | |
Charles Hoppel | Cleveland, Ohio, US | ||
Brian Irving | Geisinger Health System, Danville, US | Sex differences in murine mitochondrial oxidative capacity following a 24 week high-fat diet | Oral |
Robert Jacobs | University of Zurich, CH | Improvements in exercise performance with high-intensity interval training are facilitated by an increase in skeletal muscle mitochondria content | Oral HypoxiaNet |
Petr Jezek | Academy of Sciences of the Czech Rep., Prague, CZ | Antioxidant synergy of mitochondrial uncoupling protein UCP2 and phospholipase iPLA2γ | Oral |
Jaap Keijer | Wageningen University, NL | Three non-invasive methods to measure metabolic health in mice using indirect calorimetry | Poster |
Werner Koopman | Radboud University Medical Centre, Nijmegen, NL | Developing novel treatment strategies for mitochondrial disease | Oral |
Aleksandra Kotwica | University of Cambridge, UK | Mitochondrial respiration in heart and soleus of ob/ob mice | Oral |
Sergey Korotkov | Academy of Sciences, St Petersburg, RU | Thallium(I) induces the mitochondrial permeability transition pore in Ca2+-loaded rat liver mitochondria | Poster |
Andrey Kozlov | Ludwig Boltzmann Institute, Vienna, AT | Regulatory role of mitochondrial ROS upon inflammation | Oral |
Bernard Korzeniewski | Jagiellonian University, Krakow, PL | 'Regulation of oxidative phosphorylation during work transitions in various tissues results from its kinetic properties | Oral |
Verena Laner | OROBOROS INSTRUMENTS, Innsbruck, Austria | Local organizer | |
Steen Larsen | University of Copenhagen, DK | Skeletal muscle respiration after high intensity training | Oral |
Filip J Larsen | Karolinska Institut, Stockholm, SE | Human mitochondria has a unique response to ischemia reperfusion injury compared to mitochondria from rat, mouse and pig | Oral |
Hong Kyu Lee | Eulji University College of Medicine, Seoul, KR | Building the mitochondrial medicine; need to define mtDNA variations and its function | Oral |
Hélène Lemieux | University of Alberta, CA | Early mitochondrial dysfunction associated with type 2 diabetes mellitus in the heart and skeletal muscle | Oral |
Carsten Lundby | University of Zurich, CH | The effects of hypoxic training on aerobic performance in normoxia and moderate hypoxia: a randomized, double blind, placebo controlled study. | Oral HypoxiaNet |
Stine Lundby | University of Zurich, CH | ||
Katherine Lyabakh | Glushkov Institute of Cybernetics National Academy of Sciences, Kiev, UA | Changes in oxidative power and intracellular redistribution of mitochondria can regulate tissue pO2 and oxygen consumption rate under circulatory hypoxia. | Poster |
Marina Makrecka | Riga Stradins University, Riga,LV | The accumulation of long chain acyl-carnitines is a major cause of mitochondrial damage during ischemia | Poster |
Felix Mark | Alfred Wegener Institute for Polar and Marine Search, Bremerhaven, DE | ||
Jose Matallo | Universitätsklinikum Ulm, DE | Effects of Mechanical Ventilation after Blunt Chest Trauma on Diaphragmatic Mitochondrial Respiration in Chronically Cigarette Smoke Exposed Mice; A Clinically Relevant Model? | Poster |
Michael Menze | Eastern Illinois University, Charleston, US | Group1 LEA protein ameliorates inhibition of mitochondrial respiration in Drosophila melanogaster Kc167 cells and isolated mitochondria | Oral |
Alexandre Pastoris Muller | Universidade Federal do Rio Grande do Sul, Porto Alegre, BR | Insulin prevents mitochondrial generation of H2O2 in rat brain | Poster |
Daniel Munro | Université du Québec à Rimouski, CA | Mitochondrial membrane of the longest-lived metazoan (A.islandica) are lipoxidation-resistant | Oral |
Marcus Oliveira | Universidade Federal do Rio de Janeiro, BR | Comparative mitochondrial physiology in blood feeding insect vectors and parasites | Oral |
Rolf Erik Olsen | Institute of Marine Research Matre, Matredal, NO | Comparative study of respiartion in Atlantic salmon (Salmo salar, L.) cells and mitochondria from blood, heart, liver, muscle and brain | see Erik Slinde |
Jamile Paier-Pourani | L. Boltzmann Institute für experimentelle und klinische Traumatologie, Vienna, AT | Feed forward iNOS-mitochondrial ROS loop in Hepatocytes. | Oral |
Fredrik Palm | Uppsala University, SE | Role of mitochondria function for the onset and progression of kidney disease. | Oral |
Dominik Pesta | Yale University School of Medicine, US | ||
Carl Pinkert | Auburn University, Alabama, US | Murine Modeling of Human Mitochondrial Disease Pathogenesis | Poster |
Patrik Persson | Uppsala University, SE | The effects of Angiotensin II on mitochondrial respiration; a role of normoglycemia versus hyperglycemia | Poster |
Nicolas Pichaud | Université du Québec à Rimouski, CA | Importance of mitochondrial haplotypes in the expression of metabolic phenotypes under different conditions | Oral |
Lydie Plecita-Hlavata | Academy of Sciences of the Czech Rep., Prague, CZ | Mitochondrial network and cristae remodeling upon hypoxia | Oral |
Björn Quistorff | University of Copenhagen, SE | With type 2 diabetes mitochondrial dysfunction develops earlier in liver than in rat skeletal muscle. | Oral |
Dionizio Ramos Mendes Filho | Federal University of Rio de Janeiro, BR | High intensity interval training (HIIT) induces different responses in respiration and H2O2 production induced by different substrates in three types of permeabilized myofibers. | Poster |
Mariana Rodrigues | Federal University of Rio de Janeiro, BR | Studies of Bioenergetics Alterations in Breast Cancer Lines Induced by Histone desacetylase inhibitors | Poster |
Rodrigue Rossignol | Université Victor Segalen-Bordeaux 2, FR | part time | |
Karine Salin | University of Glasgow, UK | Mitochondrial functioning, a proximate mechanism underlying the pace of life? | Poster |
Tomas Schiffer | Karolinska Institute, Stockholm, SE | Dietary Inorganic Nitrate Reduces Basal Metabolic Rate in Man | Poster |
Patricia Schulte | University of British Columbia, Vancouver, CA | The effect of low-temperature acclimation on mitochondrial function in the common killifish (Fundulus heteroclitus), a top-down elasticity analysis | Oral |
Vitaly Selivanov | Universitat de Barcelona, ES | Analysis of bifurcation characteristics of the mitochondrial respiratory chain operation and factors determining its specificity for various tissues | Poster |
Fedor Severin | Moscow State University, RU | Mitochondrially-encoded protein Var1 promotes loss of respiratory function in Saccharomyces cerevisiae under stressful conditions | Poster |
Irina Shabalina | Stockholm University, Stockholm, SE | Comparative study of brown and white adipose tissue mitochondria in mice upon cold acclimation | Oral |
Maria Shigaeva | Insitute of Theoretical and Experimental Biophysics RAS, Pushchino, RU | The role of mitochondrial ATP-dependent potassium channel in the adaptation of organism to stress | Poster |
Christian Silva Platas | Medical School, Tec de Monterrey, MX | Modulation of Ca2+ mitochondrial transport by sorcin | Poster |
Vladimir Skulachev | Moscow State University, RU | SkQ1, the first tool to treat ROS-induced mitochondrial pathologies, which is available in drugstores | Oral |
Erik Slinde | University of Life Science, As, NO | Comparative study of respiartion in Atlantic salmon (Salmo salar, L.) cells and mitochondria from blood, heart, liver, muscle and brain | Poster |
Lauren Sparks | Burnham Institute for Medical Research, Orlando, US | ||
James Staples | University of Western Ontario, London, CA | Mechanisms of mitochondrial metabolic depression in hibernation | Oral |
Karolina Subrtova | Biology Centre, ASCR, Ceske Budejovice, CZ | Hypothetical trypanosoma protein helps to anchor the F1-ATPase moiety to the mitochondrial membrane | Oral |
Marten Szibor | University of Helsinki, FI | Expression of Ciona intestinalis alternative oxidase (AOX) in mouse | Oral |
Kersti Tepp | National Institute of Chemical Physics and Biophysics, Tallin, EE | Bioenergetic aspects of postnatal development of cardiac cells: formation of structure-function relationship | Oral |
Jason Treberg | University of Manitoba, Winnipeg, CA | Consumption of H2O2: the other side of mitochondrial ROS metabolism | Poster |
Laszlo Tretter | Semmelweis University, Budapest, HU | The effects of methylmalonic acid on alpha-ketoglutarate supported oxidation in isolated brain, heart and liver mitochondria | Oral |
Anibal Vercesi | State University of Campinas, BR | Mitochondrial calcium transport in animal, plant and trypanosomes | Oral |
Kristine Volska | Riga Stradins University, Riga, LV | The inhibitor of L-carnitine biosynthesis protects brain mitochondria against anoxia-reoxygenation injury. | Poster |
Dominique Votion | University of Liège, BE | The challenge of understanding myopathies in horses using permeabilized and cultured equine muscle cells | Oral |
Mariusz Wieckowski | Nencki Institute of Experimental Biology, Warsaw, PL | Mitochondrial parameters and ROS production can be used to differentiate mitochondrial defects in fibroblasts from patients with mitochondrial defects | Oral |
Aleksandra Wojtala | Nencki Institute of Experimental Biology, Warsaw, PL | Comparative studies of reactive oxygen species production and the level of antioxidant defense system in the fibroblasts derived from patients with defined mitochondrial disorders | Oral |
Lauren Wright | Dipartimento di Scienze Biomediche, Padova, IT | Calcium regulation of metabolism in adipocytes | Oral |
Jaroslav Zelenka | Academy of Sciences, Prague, CZ | Response of cancer cells to mitochondrial DNA damage; Poster: Reverse carboxylation glutaminolysis in breast cancer cells | Poster |
Session on high-altitute mitochondrial physiology and hypoxia
- Supported by COST project HypoxiaNet for members of this network.
Pre-conference Workshop
- OROBOROS Oxygraph-2k Workshop IOC78 - limited to 30 participants (6 O2k)