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Autophagy as a mechanism of adaptation the yeast
Zieglerová, Leona ; Váchová, Libuše (advisor) ; Zikánová, Blanka (referee)
Autophagy is a degradation pathway, conserved from yeast to mammals. The uniqueness of this pathway lies in its function, it is applied in the cell especially under the adverse conditions. It helps the cell to deliver essential nutrients for life, it removes the damaged or superfluous organelles, protein aggregates and helps with recycling and maintains a constant inner environment. These functions can prolong cell life and the cells survive the adverse conditions. Autophagy may induce the programmed cell death type II. This paper describes the basic of autophagy machinery, regulation and influence of yeast autophagy to adapt to the stressful conditions. Understanding the mechanism and regulation of autophagy in yeast may help with the study of autophagy in mammals. In mammals, this degradation pathway disorders cause many diseases (especially neurodegenerative), autophagy also effects the formation of tumors. Powered by TCPDF (www.tcpdf.org)
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Structure and physiological role of the mitochondrial permeability transition pore
Eliáš, Jan ; Mráček, Tomáš (advisor) ; Kalous, Martin (referee)
Mitochondrial permeability transition pore (mPTP) is Ca2+ dependent channel localised in the inner mitochondrial membrane. One of its defining characteristics is inhibition by nanomolar concentrations of immunosuppressant cyclosporine A (CsA). Together with additional interacting proteins, which regulate its opening, mPTP forms a permeability transition protein complex. Persistent opening of mPTP is accompanied by mitochondrial swelling and a subsequent collapse of organelle, which precedes release of proapoptotic proteins and programmed cell death. Channel forming unit of mPTP remains unknown, despite intense and long-lasting study. Numerous proteins were proposed to play a role of channel forming subunit of mPTP, including complex of ANT and VDAC, ANT alone, PiC or even ATP synthase. Despite the fact, that molecular structure remains elusive, mPTP seems to play a role in a range of pathophysiological processes or diseases associated with them. Among others this includes ischemia/reperfusion injury, neurological and muscle dystrophies, or tumorigenesis. Keywords: mitochondria, mitochondrial permeability transition pore, cyclosporine A, programmed cell death, ATP synthase, oxidative phosphorylation apparatus.
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Vegetative incompatibility in filamentous ascomycetes
Glässnerová, Kateřina ; Hubka, Vít (advisor) ; Sklenář, František (referee)
Vegetative incompatibility is a process occurring during vegetative growth in filamentous fungi which can prevent fusion of hyphae between individuals. In case of hyphal fusion between two individuals with genetically incompatible combination of alleles of vegetative incompatibility genes (i.e. het or vic genes), the newly-emerged heterokaryotic cell is destroyed via programmed cell death, which can be mediated in various ways. The purpose of this mechanism can be to preserve the genetic individuality of an individual or to prevent the transmission of a deleterious cytoplasmatic elements (e.g. mycoviruses). Exploring the vegetative incompatibility genes plays an important role for example in the induction of sexual state in vitro or in the study of speciation mechanisms in fungi. On the molecular-genetic level, vegetative incompatibility has been so far described in detail only in three ascomycete species. This thesis aims to summarize our knowledge concerning the significance of vegetative incompatibility and genetical mechanisms that underlie this process. Key words: vegetative incompatibility, het genes, vic genes, mat locus, programmed cell death, Neurospora crassa, Podospora anserina, Cryphonectria parasitica
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The role of potassium transporters in programmed cell death of yeasts
Cmunt, Denis ; Hodek, Petr (advisor) ; Bořek Dohalská, Lucie (referee)
The role of potassium transporters in programmed cell death of yeasts Abstract The programmed cell death was originally connected only to ontogenesis of metazoan. It was later shown that it plays an important role in physiological processes too. An insufficiency or an increased rate of the programmed cell death lead to many pathologies. The term apoptosis was taken as synonym for the term programmed cell death but it designates one of its types. Other types of the programmed cell death are not explored so far as apoptosis. The original classification was based on morphological features, however, there is an approach to distinguish them based on biochemical features. The programmed cell death was found in plants too, where its roles are similar to roles in metazoan and, surprisingly, it occurs in unicellular organisms. The prokaryotic mechanism is different but many common features with metazoan apoptosis exist in unicellular eukaryotes. Nevertheless, certain differences led to use of the term "apoptosis-like programmed cell death". One of the most studied unicellular eukaryotes is a yeast species Saccharomyces cerevisiae. There was found a range of metazoan homologues proteins and thus it can be used as a model organism to deepen our knowledge on metazoan apoptosis and to understand the occurrence of such a...
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Autophagy as a mechanism of adaptation the yeast
Zieglerová, Leona ; Váchová, Libuše (advisor) ; Zikánová, Blanka (referee)
Autophagy is a degradation pathway, conserved from yeast to mammals. The uniqueness of this pathway lies in its function, it is applied in the cell especially under the adverse conditions. It helps the cell to deliver essential nutrients for life, it removes the damaged or superfluous organelles, protein aggregates and helps with recycling and maintains a constant inner environment. These functions can prolong cell life and the cells survive the adverse conditions. Autophagy may induce the programmed cell death type II. This paper describes the basic of autophagy machinery, regulation and influence of yeast autophagy to adapt to the stressful conditions. Understanding the mechanism and regulation of autophagy in yeast may help with the study of autophagy in mammals. In mammals, this degradation pathway disorders cause many diseases (especially neurodegenerative), autophagy also effects the formation of tumors. Powered by TCPDF (www.tcpdf.org)
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