|
Sortorder |
Family |
First |
Title |
| 1. Molecular bioenergetics |
| Poster session 1.1. Respiratory chain |
| P1.1.1 |
Abdrakhmanova |
Albina |
A proteomic study of complex I from the aerobic yeast Yarrowia lipolytica |
| P1.1.2 |
Cadenas |
Susana |
Inhibition of cytochrome c oxidase by nitric oxide in intact cells under normoxia and hypoxia |
| P1.1.3 |
Dachary-Prigent |
Jeanne |
Identification of tyrosine-phosphorylated proteins of the mitochondrial oxidative phosphorylation machinery |
| P1.1.4 |
Barquera |
Blanca |
EPR characterization of the flavin radicals in the Na+-pumping NADH: quinone oxidoreductase from Vibrio cholerae |
| P1.1.5 |
Belevich |
Galina |
Site specific mutagenesis of conserved arginine 274 and histidines 224 and 228 in the NuoCD subunit; studies of quinone reductase activity and EPR spectra in isolated Complex I from Escherichia coli |
| P1.1.6 |
Belevich |
Ilya |
The metastable H state is important for proton pumping by cytochrome c oxidase |
| P1.1.7 |
Benard |
Giovanni |
Utilization of excess cytochrome c and coenzyme Q for the maintenance of mitochondrial energy production in muscle and liver |
| P1.1.8 |
Bogachev |
Alexander |
Thermodynamic properties of the redox centers of Na+-translocating NADH: quinone oxidoreductase |
| P1.1.9 |
Giuffre |
Alessandro |
Nitric Oxide and the CuB-lacking Bacterial Terminal Oxidase Cytochrome bd |
| P1.1.10 |
Brasseur |
Gael |
Expression and characterisation of different quinol and cytochrome oxidases in the acidophilic chemolititrophic bacterium Acidithiobacillus ferrooxidans |
| P1.1.11 |
Capitanio |
Nazzareno |
Membrane potential-dependence of the metabolic flux control exerted by cytochrome c oxidase on the cellular respiration relies on assembly/disassembly of OXPHOS supercomplexes: possible role of cardiolipin |
| P1.1.12 |
Carneiro |
Patricia |
Characterization of P76, an external alternative NAD(P)H dehydrogenase from neurospora crassa |
| P1.1.13 |
Dobrynin |
Krzysztof |
Investigation of two accessory subunits of complex I from Yarrowia lipolytica |
| P1.1.14 |
Dowhan |
William |
Role of Cardiolipin and Phosphatidylglycerol in the Synthesis and Assembly of Mitochondrial Protein Complexes |
| P1.1.15 |
Duarte |
Margarida |
Neurospora crassa mutants as models to study complex I disease-associated mutations |
| P1.1.16 |
Eek |
Maria |
Complex I in Color - construction of micro-cytochrome c fusion proteins |
| P1.1.17 |
Euro |
Liliya |
Conformational changes of catalytic importance in isolated Complex I from Escherichia coli caused upon activation by phospholipids |
| P1.1.18 |
Fadeeva |
Maria |
Expression regulation of the nqr-operons in Vibrio harveyi and Klebsiella pneumoniae |
| P1.1.19 |
Flock |
Ulrika |
Proton transfer in the Paracoccus denitrificans nitric oxide reductase |
| P1.1.20 |
Francia |
Francesco |
The local structure of Zn binding sites in the bovine cytochrome c oxidase: an X-ray absorption spectroscopy study |
| P1.1.21 |
Frezza |
Christian |
OPA1 Controls Mitochondrial Cristae Remodelling Independently from Mitochondrial Fusion During Apoptosis |
| P1.1.22 |
Galkin |
Alexander |
Interaction of diphenyleneiodonium with complex I in bovine submitochondrial particles |
| P1.1.23 |
Gnaiger |
Erich |
High excess capacity of cytochrome c oxidase in permeabilized fibers of the mouse heart |
| P1.1.24 |
Giachini |
Lisa |
X-ray absorption studies of Zn2+ binding sites in bacterial, avian and bovine cytochrome bc1 complexes |
| P1.1.25 |
Gorbikova |
Elena |
Redox Properties of Cytochrome c Oxidase Resolved by FTIR Spectroscopy |
| P1.1.26 |
Gustavsson |
Tobias |
Azidoquinone photo-labeling and detection of the labeled peptides with mass spectrometry |
| P1.1.27 |
Hinchliffe |
Philip |
Purification, characterisation and crystallisation of the hydrophilic domain of respiratory complex I from thermus thermophilus |
| P1.1.28 |
Hollis |
Veronica |
Nitric oxide triggers the early reduction of mitochondrial cytochromes in respiring mammalian cells |
| P1.1.29 |
Horecky |
Jaromir |
Effect of transient ischemia on rat brain energy metabolism assessed in vivo by (31)P MRS and in vitro by mitochondrial OXPHOS |
| P1.1.30 |
Iwaki |
Masayo |
ATR-FTIR Characterisation of the Pm Intermediate of Paracoccus denitrificans Cytochrome c Oxidase |
| P1.1.31 |
Juhaszova |
Magdalena |
Effect of intracellular Ca2+ on mpt induction in excitable cells |
| P1.1.32 |
Azarkina |
Natalia |
The cyanide binding to cytochrome ba3 is controlled by an intraprotein protonation |
| P1.1.33 |
Kamensky |
Yury |
Structural and functional roles of histidine residues in cytochrome b561, a transmembrane electron transporter in adrenal chromaffin granules |
| P1.1.34 |
Zimanyi |
Laszlo |
Intra- and interprotein photoinduced electron transfer in respiratory chain redox proteins |
| P1.1.35 |
Kicinska |
Anna |
Mitochondrial potassium channel modulators influence mitochondrial function of Acanthamoeba castellanii |
| P1.1.36 |
Hellwig |
Petra |
FTIR spectroscopic characterization of the Qo binding site in mitochondrial and bacterial bc1 complex |
| P1.1.37 |
Klingen |
Astrid |
Redox-linked Protonation State Changes in Cytochrome bc1 Complex Identified by Poisson-Boltzmann Electrostatics Calculations |
| P1.1.38 |
Voskoboynikova |
Natalia |
Cytochrome bc complex of Rb. capsulatus: Protons that are liberated upon ubiquinol oxidation stay temporarily trapped in the catalytic pocket |
| P1.1.39 |
Klishin |
Sergey |
Ubiquinol oxidation by the cytochrome bc1 complex of Rb. capsulatus in the presence of Zn ions: Dependence on temperature and on DCCD |
| P1.1.40 |
Kotlyar |
Alexander |
A novel strong competitive inhibitor of mitochondrial NADH: ubiquinone reductase |
| P1.1.41 |
Kuznetsova |
Sofya |
Cytochrome c oxidase inhibition by zinc ions |
| P1.1.42 |
Leiding |
Thom |
Complex I in Color - spectroscopic characterization of micro-cytochrome c fusion proteins |
| P1.1.43 |
Lemieux |
Helene |
Temperature effects on the control and capacity of mitochondrial respiration in permeabilized fibers of the mouse heart |
| P1.1.44 |
Butler |
Clive |
The bioenergetics of selenate respiration in Thauera selenatis |
| P1.1.45 |
Lykova |
Natalya |
Bioenergetic evaluation of environmental factors in the rapid ecological crop trial |
| P1.1.46 |
Madej |
M. Gregor |
The ’E-Pathway Hypothesis’ of Transmembrane Electron Transfer Assisted by Transmembrane Proton Transfer in Dihaem-Containing Quinol:Fumarate Reductases |
| P1.1.47 |
Marques |
Isabel |
The role of the 11.5 kDa subunit of mitochondrial complex I in enzyme activity |
| P1.1.48 |
Marshall |
Douglas |
ATR-FTIR redox difference spectroscopy of Yarrowia lipolytica and bovine complex I |
| P1.1.49 |
Mathy |
Gregory |
The Saccharomyces cerevisiae mitoproteome plasticity in response to recombinant alternative ubiquinol oxidase |
| P1.1.50 |
Melo |
Ana |
The NHAD antiporter from the nqoB operon of Rhodothermus marinus complex I |
| P1.1.51 |
Mogi |
Tatsushi |
Probing the ubiquinol-binding site in cytochrome bd by site-directed mutagenesis |
| P1.1.52 |
Moparthi |
Vamsi Krishna |
The smallest functional unit of Complex I is composed of 11 protein subunits |
| P1.1.53 |
Serafim |
Teresa Laura |
Toxicity of Carbaryl on Hepatic Mitochondrial Bioenergetics – Selective Inhibition of the Mitochondrial Respiratory Chain |
| P1.1.54 |
Nohl |
Hans |
OH radical formation from the lysosomal electron carriers |
| P1.1.55 |
Obiozo |
Mirian |
Why is proton-translocating transhydrogenase a dimer? |
| P1.1.56 |
Peng |
Guohong |
Structural membrane proteomics on bioenergetically relevant protein complexes from the hyperthermophilic eubacterium Aquifex aeolicus |
| P1.1.57 |
Ponomarenko |
Sophia |
ATP synthase as a system for molecular folding of recombinant proteins |
| P1.1.58 |
Popov |
Vasily |
Pathways of noncoupled and uncoupled respiration in plant mitochondria |
| P1.1.59 |
Cherepanov |
Dmitry |
Calculation of midpoint redox potentials of cofactors in photosystem I and ferredoxins |
| P1.1.60 |
Reimann |
Joachim |
Proton transfer pathways in nitric oxide reductase (NOR) and cbb3-type oxidases |
| P1.1.61 |
Robinson |
Neal |
Differential Stability of Dimeric and Monomeric Cytochrome c Oxidase Exposed to Elevated Hydrostatic Pressure |
| P1.1.62 |
Rudenko |
Jacob |
Changes in the respiratory chain activity of mitochondria of frog olfactory epithelium under an exposure to odorants |
| P1.1.63 |
Sakamoto |
Junshi |
Substrate-binding sites on an extremophile-type (SoxB-type) cytochrome c oxidase studied by site-directed mutagenesis |
| P1.1.64 |
Schoenfeld |
Peter |
Does thiocyanate inhibit gastric juice secretion by protonophoric activity? |
| P1.1.65 |
Dencher |
Norbert |
3D-Architecture of the respiratory chain supercomplex I(1)III(2)IV(1) from bovine heart mitochondria |
| P1.1.66 |
Siletsky |
Sergey |
The intraprotein proton transfer in the D-channel mutants of Rhodobacter sphaeroides cytochrome c oxidase |
| P1.1.67 |
Sone |
Nobuhito |
Na+-pumping ATP synthase composed of Propionigenium Fo and the thermophilic Bacillus F1 |
| P1.1.68 |
Bamann |
Christian |
Temperature dependence of electron and proton transfer in cytochrome c oxidases |
| P1.1.69 |
Stepuro |
Ivan |
Interaction of thiamine with hemoprotein oxoferryl forms |
| P1.1.70 |
Stupnikova |
Irina |
Features of pea mitochondria operation depending on cold stress intensity |
| P1.1.71 |
Terpugov |
Evgeni |
Vibrational motions in photoactive biomolecules such as all-trans retinal and wild type bacteriorhodopsin: an infrared emission spectroscopic study |
| P1.1.72 |
Tocilescu |
Maja |
Exploring the environment of iron-sulfur clusters in complex I from Yarrowia lipolytica |
| P1.1.73 |
Salviati |
|
Characterization of the 5’ region of human COQ2, a gene causing primary CoQ10 deficiency |
| P1.1.74 |
Tveen Jensen |
Karina |
Intra-domain and inter-domain motions in proton-translocating transhydrogenase |
| P1.1.75 |
Mamedov |
Mahir |
Electrogenicity due to quinone-iron complex turnover |
| P1.1.76 |
Venturoli |
Giovanni |
Probing the local structure and dynamics of Fe site in cytochrome c embedded in a dry trehalose matrix: an X-ray absorption spectroscopy study |
| P1.1.77 |
Verissimo |
Andreia |
Characterisation of the redox behaviour of the cbb3 oxygen reductase from Bradyrhizobium japonicum |
| P1.1.78 |
Videira |
Arnaldo |
Characterization of NAD(P)H dehydrogenases of the mitochondrial respiratory chain from Neurospora |
| P1.1.79 |
Vygodina |
Tatiana |
Effect of calcium on the heme a reduction in mammalian cytochrome c oxidase |
| P1.1.80 |
Wenz |
Tina |
The role of conserved residues in the mitochondrial quinol: cytochrome c oxidoreductase for substrate binding, catalysis and proton transfer |
| P1.1.81 |
Whitehead |
Simon |
The use of Zn2+ ions to probe the proton-translocation reactions of transhydrogenase |
| P1.1.82 |
Yano |
Takahiro |
Site-directed mutagenesis study of NADH-ubiquinone oxidoreductase (NDH-1) from Rhodobacter capsulatus: a role of the highly conserved 51Asn-Val-Val-Gly-Ala-Phe56 sequence in Loop 1 of the NuoH (ND1) subunit in [transmembrane electrochemical H+ potential]-dependent electron transfer |
| P1.1.83 |
Yanyushin |
Mikhail |
A new class of bacterial membrane-bound oxidoreductases |
| P1.1.84 |
Zickermann |
Volker |
Functional implications from novel structural features in complex I from Yarrowia lipolytica |
| Poster session 1.2. Light-driven energy transducers |
| P1.2.1 |
Amunts |
Alexey |
The Crystal Structure of Plant Photosystem I – Towards Atomic Resolution |
| P1.2.2 |
Balashov |
Sergei |
Interaction of the carotenoid antenna with the retinal in xanthorhodopsin: pH dependent transitions and chirality of bound salinixanthin |
| P1.2.3 |
Carmeli |
Chanoch |
The Structure of Ligand-Modified Iron-Sulfur Cluster Fx in Photosystem I as Determined by EXAFS |
| P1.2.4 |
Cheap |
Helene |
Electron and proton transfer events in bacterial reaction centers : investigation of the role of the iron ligands |
| P1.2.5 |
Dezi |
Manuela |
Kinetics of charge recombination and distribution of the ubiquinone pool in reaction center – light harvesting complexes purified from Rhodobacter sphaeroides |
| P1.2.6 |
Elanskaya |
Irina |
Role of NAD(P)H:quinone oxidoreductase encoded by drgA gene in regulation of light-induced electron transport through Photosystem I in cyanobacterium Synechocystis 6803 |
| P1.2.7 |
Gabrielyan |
Lilit |
Molecular hydrogen production by Rhodobacter spheroides: phenomenon, redox potential and proton-coupled processes |
| P1.2.8 |
Gomes-Laranjo |
Jose |
Assessment to the high temperature effect on chestnut seedlings growth |
| P1.2.9 |
Gopta |
Oksana |
Analysis of charge recombination kinetics in cyanobacterial Photosystem I with site-specific substitutions in the vicinity of the phylloquinone molecules |
| P1.2.10 |
Kalaidzidis |
Yannis |
The Electrogenesis of Neurospora Rhodopsin Photocycle |
| P1.2.11 |
Husu |
Ivan |
Relations between structure and biological affectivity for Q(B) site inhibitors of bacterial photosynthetic reaction centers |
| P1.2.12 |
Kalaji |
Mohamed |
PS II bioenergetics of barley seedlings growing under abiotic stresses |
| P1.2.13 |
Khodonov |
Andrey |
Study of the spectral behavoir of the crowned retinals and bacteriorhodopsin analogs |
| P1.2.14 |
Klimov |
Vyacheslav |
Bicarbonate requirement for the water-oxidizing complex of photosystem II |
| P1.2.15 |
Medvedev |
Emile |
Protein dynamics control of electron transfer in reaction centers from Rps. viridis |
| P1.2.16 |
Kozlova |
Maria |
Proton transfer coupled to the ubiquinone reduction in the reaction center of Blastochloris viridis |
| P1.2.17 |
Krammer |
Eva-Maria |
The binding behavior of coenzyme Q to the photosynthetic reaction center |
| P1.2.18 |
Karapetyan |
Navassard |
Blue light-induced fluorescence quenching of phycobilisomes in the cyanobacterium Synechocystis sp. PCC 6803 in the absence of the IsiA protein |
| P1.2.19 |
Setif |
Pierre |
Reconstituting the electron transfer cascade from photosystem-I to ferredoxin-NADP+-reductase and nitrite reductase: Kinetics, energetics and catalysis |
| P1.2.20 |
Vitukhnovskaya |
Liya |
The interaction between photosystem 1 and cytochrome b(6)f complex in hybrid proteoliposomes studied by EPR method |
| Poster session 1.3. ATP-synthase/ATPase |
| P1.3.1 |
Haraux |
Francis |
Oligomerization and inhibitory power of the regulatory peptides of Saccharomyces cerevisiae ATP synthase |
| P1.3.2 |
Lippe |
Giovanna |
Functional role of subunit e of F(0)F(1) ATPsynthase in bovine heart mitochondria |
| P1.3.3 |
Corvest |
Vincent |
A bind-lock mechanism for the inhibitory peptide of mitochondrial atp synthase |
| P1.3.4 |
D'Alessandro |
Manuela |
Intrinsic uncoupling in the ATP synthase of E.coli |
| P1.3.5 |
Dmitriev |
Oleg |
A Model Structure of the Proton Channel of the E.coli ATP Synthase |
| P1.3.6 |
Drory |
Omri |
Crystal structure of yeast V-ATPase subunit C reveals its stator function |
| P1.3.7 |
Dudkina |
Natalya |
Structure of dimeric ATP synthase from mitochondria |
| P1.3.8 |
Boersch |
Michael |
Proton-driven c subunit rotation within the Fo motor of a single ATP synthase |
| P1.3.9 |
Feniouk |
Boris |
Regulation of F(0)F(1) ATP synthase: subunit epsilon C-terminal domain is involved in inhibition by ADP and in activation by protonmotive force |
| P1.3.10 |
Frasch |
Wayne |
Microsecond Time Scale Rotation Measurements of Single F(1) ATPase Molecules |
| P1.3.11 |
Galkin |
Mikhail |
The E. coli F(1)F(0)-ATPase: effect of different reconstitution and assay procedures on atp synthesis activity |
| P1.3.12 |
Galvez |
Eva |
Quantum dots as energy donors for fluorescence resonance energy transfer in a single membrane bound H+-ATPsynthase |
| P1.3.13 |
Ishizuka |
Morio |
Flagellar mortor from the thermophilic PS3 |
| P1.3.14 |
Kahar |
Prihardi |
A crucial clue to understand the molecular rotation of c-subunit ring coupled with proton translocation through F(0) of Thermophilic bacillus PS3 ATP synthase |
| P1.3.15 |
Trchounian |
Armen |
Proton ATPase in redox sensing by bacteria |
| P1.3.16 |
Kramarova |
Tatiana |
Overexpression of subunit c of the ATP synthase increases total ATP synthase amount and activity in brown-fat mitochondria |
| P1.3.17 |
Malyan |
Alexander |
Nucleotide binding properties of noncatalytic sites of thiol-modulated chloroplast ATP synthase |
| P1.3.18 |
Mitome |
Noriyo |
Essential Arg of subunit a in F(0)F(1)-ATP synthase plays a key role in c-ring rotation by preventing the futile proton shortcut |
| P1.3.19 |
Futai |
Masamitsu |
Stochastic high-speed rotation of Escherichia coli ATP synthase F(1) sector and its mutations in the ATP-binding region |
| P1.3.20 |
Bald |
Dirk |
ATP synthase-Regulation of a complex machine |
| P1.3.21 |
Rebecchi |
Alberto |
Effect of the gammaM23-K mutation on ATP synthase activation by the protonmotive force and on coupling ATP hydrolysis to proton translocation |
| P1.3.22 |
Grueber |
Gerhard |
Structural analysis of the coupling subunit F of the archaeal A(1)A(0) ATPsynthase from Methanosarcina mazei GO1 in solution |
| P1.3.23 |
Seelert |
Holger |
H+-ATP synthase dimers in the chloroplast of Chlamydomonas reinhardtii |
| P1.3.24 |
Suzuki |
Toshiharu |
Role of Propionigenium modestum uncI gene in F(0)F(1)-ATP synthase: UncI is a molecular chaperon that assists c11-ring assembly |
| P1.3.25 |
Wittig |
Ilka |
Subcomplexes and supercomplexes of mitochondrial ATP synthase |
| P1.3.26 |
Yokoyama |
Ken |
Rotation and Structure of Prokaryotic ATPase/synthase |
| Poster session 1.4. Porters and some other subjects |
| P1.4.1 |
Aliverdieva |
Dinara |
Endogenous respiration substrates levels in Saccharomyces cerevisiae cells |
| P1.4.2 |
Jolkver |
Elena |
Identification and characterization of excretory carriers in C. glutamicum |
| P1.4.3 |
Kanazawa |
Hiroshi |
An oligomer formation and conformational change of NhaA from Helicobacter pylori studied by FRET |
| P1.4.4 |
Kopustinskiene |
Dalia |
Molecular Modeling Insight into the K(ATP) Channel Openers-Mitochondrial Adenine Nucleotide Translocase Interaction |
| P1.4.5 |
Kovaleva |
Mariya |
Prooxidant-induced low-conductance channel in mitochondria from the Yarrowia lipolytica yeast |
| P1.4.6 |
Kuwabara |
Naoyuki |
Topology of residues and conformational change required for the pH dependent antiport activity for H. pylori NhaA |
| P1.4.7 |
Mamaev |
Dmitriy |
Inhibitory analysis of the rat liver mitochondrial dicarboxylate transporter by means of lipophilic derivatives of its substrates |
| P1.4.8 |
Zvyagilskaya |
Renata |
A mPTP-like pore in yeast mitochondria |
| Poster session 1.5. Mechanisms of energy coupling |
| P1.5.1 |
Akopyan |
Karen |
Bacterial membrane proton conductance: effects of growth conditions and osmotic stress |
| P1.5.2 |
Antonenko |
Yury |
Two-dimensional and three-dimensional proton diffusion along the bilayer lipid membrane |
| P1.5.3 |
Bagramyan |
Karine |
Coupled formate oxidation and ATP synthesis in fermenting Escherichia coli |
| P1.5.4 |
Karlsson |
Jenny |
Properties of the rigid PAPP-region in the linker connecting domain I and domain II in E. coli transhydrogenase |
| P1.5.5 |
Kirakosyan |
Gayane |
Disulfide-dithiol interchange in energy transfer for bacterial membrane proteins functioning: effects of copper ions |
| P1.5.6 |
Korovkina |
Nadezhda |
PKC and PMCA in regulation of the Ca2+ efflux in response to glutamate exposure in neurons |
| P1.5.7 |
Liu |
Shusen |
Non-ohmic Dependence of ROS Generation and Its Cycling Across Mitochondrial Membranes May Have a Regulatory Role in Balancing Between Energy Transduction and Cellular Redox Signalling |
| P1.5.8 |
Martinou |
J.-C. |
Physiological role of mitochondrial fission and fusion |
| P1.5.9 |
Dutton |
P. Leslie |
Advances and opportunities in Angstrom level electron tunneling simulations of natural photosynthetic and respiratory systems and de novo designed catalytic and energy converting proteins |
| P1.5.10 |
Nevo |
Yaniv |
Site-directed mutagenesis of the metal-ion transporter DCT1 |
| P1.5.11 |
Pedersen |
Anders |
Structure determination of a transient complex by NMR using paramagnetic distance restraints - the complex of the soluble domains of Escherichia coli transhydrogenase |
| P1.5.12 |
Syrtsova |
Lidia |
Energy coupling in nitrogenase |
| P1.5.13 |
Voinova |
Vera |
Some characteristics of functional coupling between nucleoside diphosphate kinase of the outer mitochondrial compartment and oxidative phosphorylation |
| 2. Physiology and pathology of mitochondria(in vitro, ex vivo and in vivo studies) |
| Poster session 2.1. Uncoupling |
| P2.1.1 |
Affourtit |
Charles |
Control of ATP/ADP in pancreatic beta cells: the importance of mitochondrial proton leak |
| P2.1.2 |
Rupprecht |
Anne |
Effect of high membrane potential on the UCP- mediated electric conductance of planar bilayer membrane |
| P2.1.3 |
Belouze |
Maud |
Original regulation of energy balance in lean Lou/C rats |
| P2.1.4 |
Borovskii |
Gennadii |
Alternative oxidase and uncoupling protein expression in maize and wheat seedlings under varied stresses |
| P2.1.5 |
Brailovskaya |
Irina |
Distinctions between stimulation by cytochrome c of ascorbate (with TMPD) oxidation or NADH oxidation via external pathway in liver mitochondria in sucrose hypotonic media |
| P2.1.6 |
Porter |
Richard |
The effects of acute and endurance exercise on UCP 3 protein expression in mouse gastrocnemius, plantaris, soleus and EDL muscles |
| P2.1.7 |
Dedukhova |
Vera |
Suppression by dibucain and by cyclosporin A of inner mitochondrial membrane pore opening in liver mitochondria by acidification of high phosphate incubation medium |
| P2.1.8 |
Dutseva |
Elena |
Ion channels formed by mini-gramicidin in planar bilayer phospholipid membranes: sensitized photoinactivation versus single-channel analysis |
| P2.1.9 |
Fromme |
Tobias |
A single base exchange leads to tissue specific ablation of Ucp3 expression |
| P2.1.10 |
Grabelnych |
Olga |
The role of fatty acids in oxidative phosphorylation uncoupling of winter wheat mitochondria and the participation of ADP/ATP-antiporter and the plant uncoupling mitochondrial protein (PUMP) in this process |
| P2.1.11 |
Humphrey |
Dickon |
GDP and fatty acid interactions with UCP1 |
| P2.1.12 |
Jastroch |
Martin |
Introducing a mammalian cell system to study the function of evolutionary distant uncoupling proteins |
| P2.1.13 |
Yong |
Zhang |
Rapidly Up-regulated Expression of UCP3 and Its Effect on ROS Generation in Muscle Mitochondria during Prolonged Exercise in Rats |
| P2.1.14 |
Khailova |
Liudmila |
The ATP/ADP–antiporter is responsible for a GDP-sensitive oleic acid- and oleic acid hydroperoxide–induced uncoupling in kidney mitochondria |
| P2.1.15 |
Klingenspor |
Martin |
Uncoupling protein 1 is expressed in the brain of ectothermic vertebrates |
| P2.1.16 |
Korotkov |
Sergey |
Tl+ Effects on Rat Liver Mitochondria were stimulated in the presence of inorganic phosphate |
| P2.1.17 |
Lombardi |
Assunta |
UCP3 activation: mutual relationship between superoxides and polyunsaturated fatty acids |
| P2.1.18 |
Lou |
Phing How |
Butylated hydroxytoluene - a useful model for safer uncouplers in obesity treatments? |
| P2.1.19 |
Almsherqi |
Zakaria |
Tocopherylquinone Activates Uncoupling Protein in Myocardial Mitochondria: A Potential New Role of Vitamin E as an Antioxidant |
| P2.1.20 |
Mokhova |
Elena |
Starving Tetrahymena pyriformis responds to sound frequency irradiation of cells and mitochondria |
| P2.1.21 |
Opanasenko |
Vera |
The amine-induced proton outflow through the complex of photosystem ii of chloroplasts |
| P2.1.22 |
Parker |
Nadeene |
Specificity of GDP Inhibition of Proton Conductance in Energised Mitochondria |
| P2.1.23 |
Prikhodko |
Elena |
Fatty Acid-induced uncoupling in starving cells of Tetrahymena pyriformis |
| P2.1.24 |
Romestaing |
Caroline |
Mitochondrial adaptations to choline-methionine deficient diet, a model of Non Alcoholic SteatoHepatitis |
| P2.1.25 |
Samartsev |
Victor |
Oxidative stress induce formation in liver mitochondria of the complex of ADP/ATP and aspartate/glutamate antiporters at fatty acid uncoupling activity |
| P2.1.26 |
Shabalina |
Irina |
On the mechanism of non-shivering thermogenesis: UCP3 or ATP/ADP-antiporter cannot substitute for UCP1 in thermogenesis in mice lacking UCP1 |
| P2.1.27 |
Axelsson |
Rebecca |
Regulation of UCP1 activity by fatty acids, fatty acid analogues and nucleotides |
| P2.1.28 |
Sobko |
Alexander |
Colicin E1 ionic channels and lipid flip-flop |
| P2.1.29 |
Palmeira |
Carlos |
Decreased ANT content in Zucker fatty rats: relevance for altered hepatic mitochondrial bioenergetics in steatosis |
| P2.1.30 |
Wang |
Chunming |
Effects of starvation on heart mitochondrial proton leak and uncoupling protein expression in canary birds and mice |
| P2.1.31 |
Ricchelli |
Fernanda |
Species-specific stimulation of the mitochondrial permeability transition by norbormide and its derivatives |
| Poster session 2.2. ROS and redox regulations |
| P2.2.1 |
Andrukhiv |
Anastasia |
On the mechanism by which opening the mitochondrial ATP-dependent K+ channel increases mitochondrial production of reactive oxygen species |
| P2.2.2 |
Bizouarn |
Tania |
Study of the assembly of the bovine NADPH oxidase |
| P2.2.3 |
Hulya |
Bayir |
Phospholipid-mediated scavenging of pro-apoptotic cyt c by alpha synuclein: Role in neuroprotection |
| P2.2.4 |
Belyaeva |
Elena |
The role and mechanisms of mitochondrial dysfunction in necrosis and apoptosis induced by cadmium (II) in AS-30D rat ascites hepatoma cells |
| P2.2.5 |
Blier |
Pierre |
Does the fatty acid composition affect metabolic functions and oxidative stress status in rat heart mitochondria? |
| P2.2.6 |
Borutaite |
Vilmante |
S-nitrosothiols induce inhibition of complex I and ROS production by mitochondria |
| P2.2.7 |
Boveris |
Alberto |
Oxygen delivery to the tissues and mitochondrial respiration |
| P2.2.8 |
Chevtzoff |
Cyrille |
Involvement of Reactive Oxygen Species and Ras/ cAMP patway in the regulation of mitochondrial biogenesis |
| P2.2.9 |
Dlaskova |
Andrea |
Confocal microscopy application in monitoring of mitochondrial reactive oxygen species production within selected cell cultures |
| P2.2.10 |
Duvigneau |
Johanna |
Time course of inflammation markers and mitochondrial function in liver from rats subjected to endotoxic shock |
| P2.2.11 |
Peixoto |
Francisco |
Oxidative stress enzymes and mitochondrial bioenergetics in wild Liza saliens exposed to heavy metals |
| P2.2.12 |
Fernstrom |
Maria |
Skeletal muscle mitochondrial function and ROS production in response to extreme endurance exercise in athletes |
| P2.2.13 |
Gianotti |
Magdalena |
Sex-dependent control of oxidative homeostasis of rat brain mitochondria |
| P2.2.14 |
Godinot |
Catherine |
Role of hypoxia inducible factor and reactive oxygen species in oxidative phosphorylation down-regulation of renal cancer cells |
| P2.2.15 |
Hlavata |
Lydie |
Increased oxidative status in RAS2Val19 affects mitochondrial adenine nucleotide translocator function via ROS signaling in S. cerevisiae |
| P2.2.16 |
Ivanov |
Boris |
The role of plastoquinone pool in production and scavenging of reactive oxygen species in chloroplast thylakoids |
| P2.2.17 |
Izyumov |
Denis |
Photodynamic treatment with mitochondrial photosensitizer induces oxidative stress and cell death in HeLa cells |
| P2.2.18 |
Saraiva |
Ligia |
Escherichia coli YtfE, a novel di-iron protein involved in iron-sulphur biogenesis |
| P2.2.19 |
Kazakof |
Ruslan |
The dependence of H2O2 formation in mitochondria on succinate dehydrogenase activity |
| P2.2.20 |
Kudin |
Alexey |
Quantification of mitochondrial generation of reactive oxygen species in brain tissue |
| P2.2.21 |
Kuznetsov |
Andrey |
ROS and mitochondrial Ca2+ are critical targets for survival signaling by C-Raf |
| P2.2.22 |
Wen |
Li |
Increased SOD2 Expression is Responsible for Anti-oxidation in Muscle Mitochondria during Prolonged Exercise in Rats after Endurance Training |
| P2.2.23 |
Mathe |
Christelle |
Horseradish peroxidase and Myoglobin active site studies by ATR-FTIR Spectroscopy |
| P2.2.24 |
Musatov |
Andrej |
Ferricytochrome c Protects Cytochrome c Oxidase Against Structural and Functional Damage Induced by Hydrogen Peroxide |
| P2.2.25 |
Pashkovskaya |
Alina |
Mitochondria-targeted antioxidant mitoq protects gramicidin channels from photodynamic inactivation in planar phospholipid bilayers |
| P2.2.26 |
Kozlov |
Andrey |
Application of hydroxylamine-based spin probes to detect mitochondrial reactive oxygen species in tissues and mitochondrial suspension |
| P2.2.27 |
Popova |
Ekaterina |
MitoQ induced miofibroblast differentiation of human fibroblasts |
| P2.2.28 |
Reiser |
Georg |
Mechanism of toxicity of the branched-chain fatty acid phytanic acid, a marker of Refsum disease, in brain cells involves mitochondrial depolarisation and generation of reactive oxygen species (ROS), with ROS production in brain mitochondria by rotenone-like action |
| P2.2.29 |
Rey |
Benjamin |
Role of avian uncoupling protein in preventing reactive oxygen species production of skeletal muscle mitochondria |
| P2.2.30 |
Sarti |
Paolo |
Cells, mitochondria and nitrosative stress in health and disease |
| P2.2.31 |
Scacco |
Salvatore |
cAMP regulation of oxygen free radical balance in mammalian cells |
| P2.2.32 |
Nedergaard |
Jan |
Uncoupling proteins: do ROS or ROS products activate - and do the uncoupling proteins protect against oxidative damage? |
| P2.2.33 |
Toime |
Laurence |
Activation of uncoupling protein 3 by endogenous reactive oxygen species |
| P2.2.34 |
Guevara |
Rocio |
Caloric restriction decreases ros production in brown adipose tissue of old rats by uncoupling activity |
| P2.2.35 |
Wieckowski |
Mariusz |
The role of mitochondria in the controlling of calcium channels in the plasma membrane: PAM and MAM as a point of the control machinery |
| P2.2.36 |
Zaobornyj |
Tamara |
Involvement of heart mitochondrial nitric oxide synthase and time course of rat adaptation to high altitude |
| Poster session 2.3. Aging |
| P2.3.1 |
Jarmuszkiewicz |
Wieslawa |
Mitochondrial Functions in Acanthamoeba castellanii aging |
| P2.3.2 |
Leeuwenburgh |
Christiaan |
Central Role for Mitochondrial Mediated Apoptosos with Age |
| P2.3.3 |
Mitteldorf |
J. |
How Evolutionary Thinking Affects our Ideas about Ageing Interventions |
| P2.3.4 |
Shevtsova |
Elena |
Dimebon as mitoprotective and antiaging drug |
| P2.3.5 |
Llado |
Isabel |
Age-related differences on serum paraoxonase activity in male and female rats |
| P2.3.6 |
Vyssokikh |
Mikhail |
Age-dependent character of mitochondria targeted antioxidants (MTA) mediated protective effect on cardiolipin peroxidation and creatine kinase functioning in rat heart mitochondria |
| Poster session 2.4. Cancer, ischemia and degenerative disorders |
| P2.4.1 |
Arnold |
Susanne |
The effect of hypoxia upon the transcription pattern of isoforms of cytochrome c oxidase and oxidative energy production in astrocytes and neurons |
| P2.4.2 |
Bednarczyk |
Piotr |
Large conductance potassium ion channel from rat brain mitochondria |
| P2.4.3 |
Fernandez Moreira |
Daniel |
X-linked isolated complex i deficiency |
| P2.4.4 |
Gellerich |
Frank |
Energetic depression due to Ca2+ inducible mitochondrial dysfunction contributes to Huntinton’s disease in striatum, other brain regions and skeletal muscle of transgenic HD rats and mice |
| P2.4.5 |
Glab |
Marta |
Identification of the large conductance Ca2+-activated potassium channel in rat brain mitochondria |
| P2.4.6 |
Kalinina |
Elena |
Alteration of ROS production as well as bcl-2 and bcl-xl expression under development of cancer cells resistance |
| P2.4.7 |
Kervinen |
Marko |
Divergent effects of mutations that cause two different mitochondrial diseases, LHON and MELAS, on the bacterial NDH-1 |
| P2.4.8 |
Ryabchikov |
Nikolay |
Study in Mechanism of Diazoxide Effects on Ca2+-loaded Rat Heart Mitochondria |
| P2.4.9 |
Koszela-Piotrowska |
Izabela |
Ion channels from rat skeletal muscle mitochondria |
| P2.4.10 |
Kunz |
Wolfram |
Recombination of mitochondrial DNA in a double heteroplasmic family |
| P2.4.11 |
Marusich |
Michael |
Reduced levels of Frataxin in Friedreich’s Ataxia can be measured quickly and accurately with a simple dipstick immunoassay |
| P2.4.12 |
Matteucci |
Elena |
Erythrocyte membrane electron transfer, diet and lifestyle in healthy and in type 1 diabetic families |
| P2.4.13 |
Maximo |
Valdemar |
Mitochondrial DNA (mtDNA) mutations in Helicobacter pylori chronic gastritis and gastric carcinoma |
| P2.4.14 |
Plotnikov |
Egor |
Mitochondrial role in oxidative stress under ischemia/reperfusion in the rat kidney |
| P2.4.15 |
Schroder |
J. Michael |
Mitochondria in peripheral neuropathy: correlation of molecular genetic and fine structural changes |
| P2.4.16 |
Silakka |
Pilvi |
The LHON-associated mutations 4136, 4160 and 4171, affecting the ND1 subunit of complex I, and the conserved region in their vicinity studied in Escherichia coli |
| P2.4.17 |
Silva |
Bruno |
Phenolic compounds from Hypericum perforatum protect rat hippocampal neurons from excitotoxic and amyloid-beta toxicity: a role for mitochondria |
| P2.4.18 |
Tonshin |
Anton |
Development of new model for search and study of action mechanism of neuroprotecting compounds |
| P2.4.19 |
Ugalde |
Cristina |
Assembly of the oxidative phosphorilation system in x-linked isolated complex I deficiency |
| P2.4.20 |
Wasilewski |
Michal |
N-Arachidonoylethanolamine (anandamide) influences mitochondria in living cells |
| Poster session 2.5. Program death of cells and mitochondria |
| P2.5.1 |
Arokium |
Hubert |
Molecular mechanisms underlying Bax/mitochondria interactions during apoptosis: a study in yeast |
| P2.5.2 |
Avetisyan |
Armine |
Early changes in mitochondrial physiology during TNF-induced apoptosis of lymphoid U937 cells |
| P2.5.3 |
Bolshakov |
Alex |
Mechanism of a glutamate-indduced mitochondrial depolarization in cultured cortical neurons |
| P2.5.4 |
Dymkowska |
Dorota |
Involvement of reactive oxygen species in the mitochondrial pathway of arachidonic acid-induced apoptosis |
| P2.5.5 |
Dzubinskaya |
Elena |
Effect of protein synthesis inhibitors on the course of programmed cell death in pea guard cells |
| P2.5.6 |
Eliseev |
Roman |
The role of cyclophilin D in the resistance of brain mitochondria to induction of the mitochondrial permeability transition |
| P2.5.7 |
Emelyanova |
Larisa |
Suppression of liver energy metabolism as an attribute of lampreys (lampetra fluviatilis) during prespawning migration |
| P2.5.8 |
Gogvadze |
Vladimir |
Multiple mechanisms of cytochrome c release in arsenic-induced cells death |
| P2.5.9 |
Zhurkova |
Natalia |
Mitochondrial disoders: diagnosis and clinical spectrum |
| P2.5.10 |
Kiselevsky |
Dmitry |
Cyanide-induced apoptosis in pea leafs |
| P2.5.11 |
Knorre |
Dmitry |
Superoxide as a mediator of acetate-induced apoptosis in yeast |
| P2.5.12 |
Lin |
Tong-Jun |
Pseudomonas aeruginosa-induced human mast cell apoptosis involves mitochondrial-dependent and caspase 8 pathways |
| P2.5.13 |
Hassinen |
Ilmo |
Bisphosphonate-induced apoptosis of osteoclasts. Role of mitochondrial ADP/ATP translocator |
| P2.5.14 |
Nowikovsky |
Karin |
Mitochondrial K+/H+ exchanger in Mitophagy and Apoptosis |
| P2.5.15 |
Pardo |
Julian |
Mitochondria mediate host and pathogen induced apoptosis |
| P2.5.16 |
Pavlovskaya |
Natalya |
Cyclosporin A-sensitive swelling of winter wheat mitochondria in the presence of Ca2+ ions and fatty acids |
| P2.5.17 |
Petit |
Patrice |
Cloning of the human cardiolipin synthase and effects of its knowkdown on cell death progression : a switch between apoptosis and necrosis |
| P2.5.18 |
Pinelis |
Vsevolod |
On the origin of glutamate-induced neuronal Cà2+ overload and mitochondrial depolarization |
| P2.5.19 |
Sadauskaite |
Ausra |
On cellular effects of photosensitized damage by cationic dyes |
| P2.5.20 |
Shoshan-Barmatz |
Varda |
The voltage-dependent anion channel controls life and death of the cell |
| Poster session 2.6. Mitochondrial dynamics |
| P2.6.1 |
Bellance |
Nadege |
Importance of mitochondrial network organization in the regulation of energy production |
| P2.6.2 |
Beraud |
Nathalie |
Comparative bioeneregetics of isolated cardiomyocytes and HL-1 cells: Mitochondrial dynamics, respiration regulation and creatine kinase expression |
| P2.6.3. |
Cereghetti-De Marchi |
Grazia |
The cytosolic phosphatase calcineurin (pp2b) regulates drp-1 dependent mitochondrial fission |
| P2.6.4 |
Cipolat |
Sara |
Mitochondrial rhomboid PARL regulates cytochrome c release during apoptosis via OPA1 dependent cristae remodeling |
| P2.6.5 |
Froschauer |
Elisabeth |
Electroneutral K+/H+ exchange in mitochondrial membrane vesicles involves Mkh1/Letm1 proteins |
| P2.6.6 |
Hoppel |
Charles |
Metabolic State-Related Structure of Isolated Cardiac Mitochondria as seen by High Resolution Scanning Electron Microscopy (HRSEM) |
| P2.6.7 |
Liesa |
Marc |
Mitochondrial fusion and fission in myogenic differentiation |
| P2.6.8 |
Lyamzaev |
Konstantin |
Selective elimination of mitochondria in hela cells during treatment with mitochondrial inhibitors |
| P2.6.9 |
Martins De Brito |
Olga |
Mitofusin-2, mutated in Charcot-Marie-Tooth type IIa, links endoplasmic reticulum to mitochondria |
| P2.6.10 |
Murugova |
Tatiana |
Detection of new type of membrane structure in mitochondria under low-amplitude swelling by small angle neutron scattering |
| P2.6.11 |
Nepryakhina |
Olga |
Intramitochondrial reactive oxygen species are important for dynamics of mitochondrial reticulum in living cells |
| P2.6.12 |
Landes |
Thomas |
Effects of OPA1 mutations on mitochondrial morphology and apoptosis: relevance to adoa pathogenesis |
| P2.6.13 |
Hajnoczky |
Gyorgy |
Mitochondrial conjugation |
| P2.6.14 |
Kondrashova |
M. |
Responses of mitochondrion in immobilized lymphocyte |
| Poster session 2.7. Therapeutic approach |
| P2.7.1 |
Bachurin |
Sergey |
Mitochondrial study as the important step in the seaching of neuroprotectors |
| P2.7.2 |
Dassa |
Emmanuel |
Alternative oxidase, a potential therapy for mitochondrial diseases |
| P2.7.3 |
Maevsky |
Evgeny |
Signal, sympathetic action of succinate in experimental and clinical studies |
| P2.7.4 |
Matsuno-Yagi |
Akemi |
The single subunit NADH dehydrogenase reduces generation of reactive oxygen species from complex I |
| P2.7.5 |
Gambalunga |
Alberto |
The mitochondrial effects of small organic ligands of BCL-2 at the BH3 domain. Sensitization of BCL-2 overexpressing cells to apoptosis without mitochondrial toxicity by a pyrimidine-2,4,6-trione derivative |
| P2.7.6 |
Sozanska |
Agnieszka |
Correlation of sperm motility with changes of mitochondrial membrane potential |
| 3. Miscellaneous (Other topics) |
| P.3.1 |
Alcolea |
Maria |
Increase in oxidative phosphorilation system activities is related to mitochondrial differentiation in rat embryo during placentation |
| P.3.2 |
Friedrich |
Thorsten |
Substrate crosstalk in E. coli complex I mediated by long-range conformational changes |
| P.3.3 |
Krasnovsky |
Alexander |
Activation of molecular oxygen by infrared laser radiation in pigment-free aerobic systems |
| P.3.4 |
Marusich |
Michael |
Quantitative analysis of mitochondrial protein levels, post-translational modifications and enzyme activities with rapid immunoassays suitable for basic research, pharmaceutical drug safety screening and diagnosis of mitochondrial disease |
| P.3.5. |
Moreno |
Antonio |
Hepatic mitochondria from nimesulide-treated animals have unchanged oxidative phosphorylation and permeability transition: relevance for nimesulide hepatotoxicity |
| P.3.6 |
Sardanelli |
Anna Maria |
cAMP-dependent protein kinase and A-kinase anchor proteins in the inner compartment of mammalian heart mitochondria |
