|
|
Biogenesis, structure and physiological functions of mitochondrial ATP synthase
Eliáš, Jan ; Mráček, Tomáš (advisor) ; Doležal, Pavel (referee)
Mammalian mitochondrial ATP synthase is an enzyme composed of 18 protein subunits, which is localised in the inner mitochondrial membrane. Its main function is to utilise proton gradient, produced by respiratory chain complexes (RCC), for the synthesis of ATP. Aside from the creation of ATP it is known that its dimers contribute to the correct mitochondrial morphology through the formation of cristae apexes. Furthermore, ATP synthase was proposed to have a role in the mitochondrial permeability transition phenomenon, which is important for regulation of programmed cell death. Over the recent years, our understanding of mammalian ATP synthase biogenesis has been tremendously improved. Its assembly process is now clarified, however the knowledge about assembly intermediates of its peripheral stalk and of subunit c are still not sufficient. We focused precisely on those unsolved questions in the fields of ATP synthase biogenesis and its secondary functions, by the production of a KO model of catalytic β subunit of mammalian ATP synthase F1 domain (βKO). This model was successfully prepared on the background of HEK293 cell line. Its characterisation revealed that disruption of the F1 structure resulted in the inability to assemble functional monomer and resulted in a decay of individual subunits. The only...
|
|
|
Molecular requirements of LACTB-induced tumor suppression
Jakoubě, Pavel ; Kečkéšová, Zuzana (advisor) ; Rohlenová, Kateřina (referee)
LACTB is a recently discovered mitochondrial tumour suppressor protein operating in many different types of tissues. Its mechanism-of-action seems to be context dependent as it has been shown to suppress carcinogenesis through the induction of cell cycle arrest, apoptosis, differentiation and suppression of EMT. These processes can be further dependent on alterations of lipid metabolism and interactions with additional tumour suppressors and signalling pathways. LACTB is derived from bacterial penicillin binding proteins, is localized to the mitochondrial intermembrane space and possesses enzymatic activity. It was shown to form filaments, which consist of two intertwined antiparallel chains, suggesting its role in the organisation of mitochondrial intermembrane space. In the first aim of my thesis, I wanted to examine in more detail the molecular requirement for LACTB's filament formation with the specific focus on the role of disulphide bonds in this process. In the second aim of my thesis, I intended to uncover the binding partners of LACTB, which might have a role in the filament formation. Realizing both aims will uncover important requirements for the proper folding and biological activity of LACTB. Key words: LACTB, tumour suppressor, cancer, structure, disulphide bonds, protein interactions
|
|
|
Characterization and modulation of MitoTam-induced cell death in breast carcinoma cells
Hrysiuk, Mariia ; Anděra, Ladislav (advisor) ; Dráber, Peter (referee)
Although recent years brought many breakthrough discoveries in anti-cancer research and therapy, malignant diseases such as breast cancer (BC) still present one of the major health threats worldwide. Cancer cells usually gain resistance to the activation of regulated cell death (RCD) modalities such as caspase-dependent apoptosis. Among novel RCD-inducing agents belongs to mitochondria-targeted tamoxifen - MitoTam, which is also the major focus of this Thesis. In a panel of BC cells, we determined the energetic (mitochondrial respiration vs. glycolysis) and major RCD-related proteins (Western blotting) profiles, and using Lumascope LS720-assisted time-lapse monitoring we analyzed their sensitivity to MitoTam-induced RCD. We found out that glycolysis-preferring BC cells as MDA-MB-231 are more resistant to MitoTam treatment than mitochondrial respiration-biased MDA-MB-453 cells. However,the majority of tested BC cells can be sensitized to MitoTam by BH3 mimetics such as BCL-XL targeting A1155463 and some cellular metabolism-modulating compounds such as lactate dehydrogenase inhibitor (R)-GNE-140, especially in the pre-treatment regime. Also, other metabolism-modulating compounds such as Pyruvate Dehydrogenase Kinases inhibitor JX06 potently enhanced the efficacy and kinetics of MitoTam-induced RCD....
|
|
|
Mitochondrial transfer-mediated modulatory action of stem cells on immune cells
Somova, Veronika ; Krulová, Magdaléna (advisor) ; Balounová, Jana (referee)
Stem cells use different mechanisms of intercellular communication to modulate an immune response. Mitochondrial transfer is one of the mechanisms which induce metabolic changes, support cell survival, and change the phenotype of immune cells. Nevertheless, little is known about the mechanism used for transfer of mitochondria between different cell populations and the faith of mitochondria inside the acceptor cell. This thesis aims to describe the mechanism of transfer and the provided modulation. Factors that could affect mitochondrial transfer including reactive oxygen species production, apoptosis and mitochondria function were analyzed. And the impact of mitochondrial transfer on cell survival and mitophagy was described. The next aim was to compare the ability of mesenchymal stem cells (MSC) and Sertoli cells (SC) to transfer mitochondria, with MSC being more productive in the transfer of mitochondria than SC. Significant differences in the presence of mitochondria from donor MSC or SC in individual populations of immune cells were also detected. To explain these findings, the impact of reactive oxygen species on the transfer of mitochondria was analyzed in detail, although it wasn't confirmed. However, it needs to be highlighted that mitophagy plays an important role before and after...
|
|
|
Evaluation of antibiotic-induced mitochondrial superoxide production in adherent cells
Ingrová, Kateřina ; Chmelíková, Larisa (referee) ; Zumberg, Inna (advisor)
The theoretical part of this bachelor´s thesis contains a description of the effect of reactive oxygen species on oxidative stress by mitochondria and the consequences of antibiotics use in cell line culturing. The cell line studied in this bachelor´s thesis is the mesenchymal stem cells (MSCs). The practical part describes the procedure of the experiment including cell culturing, passaging and cell labeling. The proposed experiment was repeated with sufficient number of repetitions. Finally, confocal microscopy images were processed in the MATLAB programming environment.
|
|
|
Mitochondrial production of reactive oxygen species and its role in physiological regulations
Holzerová, Eliška ; Mráček, Tomáš (advisor) ; Kalous, Martin (referee)
The production of mitochondrial reactive oxygen species and the resulting oxidative stress is an important phenomenon driving long-lasting research and intense discussions. Knowledge of exact mechanisms of reactive oxygen species production and pathways leading to their formation could help us to directly affect their production, a task with potential terapeutic implications. The molecular nature of the production of reactive oxygen species by some enzymes has already been well documented, but others still remain controversial and current theories are obviously far from the truth. Much more interesting is the question of physiological importace of this production. The reactive oxygen species were considered harmful factors clearly distorting the integrity of the organism for a long time. However, recent research suggest that their existence can also be beneficial and effective. Evidently they can serve as a signaling molecules in several metabolic and regulatory pathways occurring in the organism. This bachelor thesis offers insight into the current state of knowledge. It focuses on the most detailed description of the reactive oxygen species production by mitochondrial respiratory chain enzymes. Furthermore, it deals with some signaling cascades, where involvement of mitochondrially generated...
|
|
|
Bacterial proteins in the biogenesis of mitochondria of unicellular eukaryotes.
Petrů, Markéta ; Doležal, Pavel (advisor) ; Embley, Martin (referee) ; Hashimi, Hassan (referee)
in English Formation of mitochondria by the conversion of a bacterial endosymbiont is the fundamental moment in the evolution of eukaryotes. An integral part of the organelle genesis was the displacement of the endosymbiont genes to host nucleus and simultaneous creation of new pathways for delivery of proteins synthesized now in the host cytoplasm. Resulting protein translocases are complexes combining original bacterial components and eukaryote-specific proteins. In addition to these novel protein import machines, some components of the original bacterial secretory pathways have remained in the organelle. While the function of a widely distributed mitochondrial homolog of YidC, Oxa1, is well understood, the role of infrequent components of Sec or Tat translocases has not yet been elucidated. So far, more attention has been paid to their abundant plastid homologs, which assemble photosynthetic complexes in the thylakoid membrane. In the thesis, the structure and function of prokaryotic YidC, Sec and Tat machineries and their eukaryotic homologs are described. By comparing both organelles of the endosymbiotic origin, the hypothesis is drawn on why these translocases have been more "evolutionary successful" in plastids than in mitochondria.
|
|
|
Mitochondrial cytochrome c oxidase: cyanide inhibition and role of assembly factor Surf1 defect
Nůsková, Hana ; Drahota, Zdeněk (advisor) ; Kalous, Martin (referee)
The activity of mitochondrial cytochrome c oxidase (COX) can be affected by either exogenous or endogenous factors. The most efficient and in the environment abundant compound that inhibits COX is cyanide. The very frequent cause of COX deficiency in humans is represented by a defect in the SURF1 gene. The mechanism of cyanide inhibitory effect on COX as well as the conditions for its recovery are not yet fully explained. Three parameters of COX function, namely the transport of electrons (oxygen consumption), the transport of protons (mitochondrial membrane potential, m) and the enzyme affinity to oxygen (p50 value), were studied with regard to the inhibition by KCN and its reversal by pyruvate. The function of COX was analysed in intact isolated rat liver mitochondria, both within the respiratory chain and as a sole enzyme, using succinate or an artificial electron donor ascorbate + TMPD as a substrate. 250 M KCN completely inhibited both electron- and proton-transporting function of COX, and this inhibition was reversible as proved with washing of mitochondria. The addition of 60 mM pyruvate induced the maximal recovery of both parameters to 60 - 80 % of original values. Using KCN in the low concentration range up to 5 M, a profound, 30-fold decrease of COX affinity to oxygen was observed....
|
|
|
The role of uncoupling proteins (UCP) in cardioprotection
Furmánková, Tereza ; Horníková, Daniela (advisor) ; Adamcová, Kateřina (referee)
Cardiovascular disease (CVD) is the world's leading cause of death. Almost 18 million people die of CVD each year, and the prevalence continues to rise for both men and women. It is now clear that the maintenance of mitochondrial membrane potential can play an important role in the pathophysiology of the heart and it is involved in cardioprotective mechanisms. Mitochondrial membrane potential can be affected in a various of ways, one of them is the stimulation of uncoupling proteins. An elaboration of previous findings in this work has shown that uncoupling proteins have the effect of reducing oxygen radicals, inhibiting apoptosis, affect the production of ATP and atherosclerotic plaques and protect the heart from lipid toxicity. There are several ways to regulate their gene expression, and influencing these pathways may be a way to achieve cardioprotection. Key words: uncoupling proteins, mitochondria, cardioprtoection, thyroid hormones, fatty acids, adipose tissue, reactive oxygen species, FGF21
|
|
|
Mitochondrion of Trimastix pyriformis
Novák, Lukáš ; Hampl, Vladimír (advisor) ; Kolísko, Martin (referee)
2013 DIPLOMOVÁ PRÁCE Lukáš Novák Abstract Free-living microaerophilic protist Trimastix pyriformis is closely related to oxymonads which are the largest eukaryotic group without any known mitochondrion. In contrast to oxymonads, an enigmatic reduced mitochondrion has been found in the cell of T. pyriformis. In EST data of T. pyriformis, a number of genes has been identified whose products are putatively localized in the mitochondrion. Among these are genes for all the components of the glycine cleavage system, [FeFe]hydrogenases and the mitochondrial marker Cpn60. We performed experiments in order to determine the cellular localization of these proteins. Our results show that the glycine cleavage system is localized in the mitochondrion. Results of the experiments carried out in order to localize two hydrogenases suggest also the mitochondrial localization but are not fully convincing. The attempt to localize Cpn60 has failed. We have also identified a set of new genes in transcripts of T. pyriformis and Monocercomonoides sp. (Oxymonadida). These genes code for some components of the SUF system of FeS cluster synthesis and a peroxidase rubrerythrin. Key words: Trimastix, Monocercomonoides, mitochondrion, hydrogenosome, mitosome, hydrogenase, glycine cleavage system, SUF system.
|
guest ::
