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Molecular mechanism of 14-3-3 protein dependent regulation of caspase-2
Kalábová, Dana ; Obšilová, Veronika (advisor) ; Pavlíček, Jiří (referee) ; Žáková, Lenka (referee)
Molecular mechanism of 14-3-3 protein dependent regulation of caspase-2 Abstract Caspase-2 is a protease standing apically in the cascade of reactions leading to apoptosis. Properly functional apoptosis eliminates damaged cells, autoreactive lymphocytes or redundant groups of cells in ontogeny. The process of caspase-2 activation must be precisely regulated. One of the described ways of caspase-2 regulation causing its inhibition is posttranslational modification phosphorylation with subsequent binding of the regulatory scaffold protein 14-3-3. The aim of this dissertation is to explain the molecular mechanism of this regulation. To understand the interaction between the proteins, it was necessary to first identify the phosphorylation sites in the caspase-2 molecule recognized by the 14-3-3 protein and then describe the detailed structure of the binding complex. The structure was characterized by a number of biochemical and biophysical methods, such as analytical ultracentrifugation, native electrophoresis in TBE buffer, polarization-fluorescence assay, hydrogen/deuterium exchange coupled to mass spectrometry, or crystallization; and the results led to stimulating conclusions. Activation of caspase-2 begins with its binding to adaptor proteins, cleavage and dimerization of the catalytic subunits. The...
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The role of caspase 2 in apoptosis induction in tumor cells.
Schmiedlová, Martina ; Kovář, Jan (advisor) ; Horníková, Lenka (referee)
Within the cell, caspase-2 probably fulfills several functions. Caspase-2 can be involved in apoptosis induction, DNA repair as well as cell cycle regulation. Caspase-2 has the character of initiator and also executioner caspase. A stimulus for caspase 2 activation can be oxidative stress or DNA damage. Caspase-2 is activated by cleavadge during an interaction with protein complexes. One of protein complexes,i.e. PIDDosome, is made of protein PIDD, RAIDD and pro-caspase-2. Withine the PIDDosome, caspase-2 is activated. Activated caspase-2 occures in a short S form and in long L form. L form of caspase-2 has proapoptotic effects and S form of caspase-2 has antiapoptotic effects. Caspase-2S has been only detected on mRNA level but not on protein level. The main role of caspase-2L is apoptosis induction in normal and tumor cells. Caspase-2 in tumour cells is activated by extrinstic as well as intristic apoptotic pathway. Apoptosis induction by caspase-2 is for example studied in connection with breast cancer treatment with taxanes. Caspase-2 ability of apoptosis induction in cancer cells independently of p53 protein is employed in cancer treatment including overcoming the resistance to apoptosis induction which is based on loosing p53 activity. Caspase-2 is involved in apoptosis induction by different...
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Cell death as a result of iron-induced cellular damage
Běhounek, Matěj ; Balušíková, Kamila (advisor) ; Truksa, Jaroslav (referee)
Iron is an essential trace element for almost all living organisms. Iron overload in cells and tissues, however, leads to their disruption. Most oftenly damaged are parenchymatic organs such as the liver, pancreas and heart. The aim of this thesis was to create cellular in vitro models for the investigation of effects of excess iron on hepatocytes and pancreatic beta cells and on these models to investigate cellular processes which lead to cellular damage during iron overload. We focused on examining the presence of oxidative and endoplasmic reticulum stress and the activation of apoptotic cell death. For our experiments, we used HEP-G2 cell line which represents human hepatocytes and NES2Y cell line which represents human pancreatic beta cells. To study the mechanisms of cellular damage during iron overload, we used two approaches by which we observed both acute and long-term effects of high levels of iron on damage of the tested cell lines. When studying the acute effect of excess iron on the cells, we applied high doses of iron (using 15 mM ferric citrate in medium) that led to the activation of cell death in hours. Long-term effects of iron overload were tested on cells regularly cultivated in the presence of 50 μM and 100 μM ferric citrate over a period of several months. Iron concentrations...
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Cell death as a result of iron-induced cellular damage
Běhounek, Matěj ; Balušíková, Kamila (advisor) ; Truksa, Jaroslav (referee)
Iron is an essential trace element for almost all living organisms. Iron overload in cells and tissues, however, leads to their disruption. Most oftenly damaged are parenchymatic organs such as the liver, pancreas and heart. The aim of this thesis was to create cellular in vitro models for the investigation of effects of excess iron on hepatocytes and pancreatic beta cells and on these models to investigate cellular processes which lead to cellular damage during iron overload. We focused on examining the presence of oxidative and endoplasmic reticulum stress and the activation of apoptotic cell death. For our experiments, we used HEP-G2 cell line which represents human hepatocytes and NES2Y cell line which represents human pancreatic beta cells. To study the mechanisms of cellular damage during iron overload, we used two approaches by which we observed both acute and long-term effects of high levels of iron on damage of the tested cell lines. When studying the acute effect of excess iron on the cells, we applied high doses of iron (using 15 mM ferric citrate in medium) that led to the activation of cell death in hours. Long-term effects of iron overload were tested on cells regularly cultivated in the presence of 50 μM and 100 μM ferric citrate over a period of several months. Iron concentrations...
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The role of caspase 2 in apoptosis induction in tumor cells.
Schmiedlová, Martina ; Horníková, Lenka (referee) ; Kovář, Jan (advisor)
Within the cell, caspase-2 probably fulfills several functions. Caspase-2 can be involved in apoptosis induction, DNA repair as well as cell cycle regulation. Caspase-2 has the character of initiator and also executioner caspase. A stimulus for caspase 2 activation can be oxidative stress or DNA damage. Caspase-2 is activated by cleavadge during an interaction with protein complexes. One of protein complexes,i.e. PIDDosome, is made of protein PIDD, RAIDD and pro-caspase-2. Withine the PIDDosome, caspase-2 is activated. Activated caspase-2 occures in a short S form and in long L form. L form of caspase-2 has proapoptotic effects and S form of caspase-2 has antiapoptotic effects. Caspase-2S has been only detected on mRNA level but not on protein level. The main role of caspase-2L is apoptosis induction in normal and tumor cells. Caspase-2 in tumour cells is activated by extrinstic as well as intristic apoptotic pathway. Apoptosis induction by caspase-2 is for example studied in connection with breast cancer treatment with taxanes. Caspase-2 ability of apoptosis induction in cancer cells independently of p53 protein is employed in cancer treatment including overcoming the resistance to apoptosis induction which is based on loosing p53 activity. Caspase-2 is involved in apoptosis induction by different...
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