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Molecular mechanisms of checkpoint signalling and termination
Benada, Jan ; Macůrek, Libor (advisor) ; Brábek, Jan (referee) ; Truksa, Jaroslav (referee)
Cells employ an extensive signalling network to protect their genome integrity, termed DNA damage response (DDR). The DDR can trigger cell cycle checkpoints which prevent cell cycle progression and allow repair of DNA damage. The failures in these safeguarding mechanism are represented by serious human malignancies, most predominantly by cancer development. This work aims to contribute to the understanding of how do the cells negatively regulate DDR and cell cycle checkpoint signalling. We focused mainly on Wip1 (PPM1D) phosphatase, which is a major negative regulator of DDR and is indispensable for checkpoint recovery. Firstly, we have shown that Wip1 is degraded during mitosis in APC-Cdc20 dependent manner. Moreover, Wip1 is phosphorylated at multiple residues during mitosis, resulting in inhibition of its enzymatic activity. We suggest that the abrogation of Wip1 activity enables cells to react adequately even to low levels of DNA damage encountered during unperturbed mitosis. In the following publication, we have investigated why the mitotic cells trigger only early events of DDR and do not proceed to the recruitment of DNA repair factors such as 53BP1. We showed that 53BP1 is phosphorylated within its ubiquitination-dependent recruitment domain by CDK1 and Plk1. These phosphorylations prevents...
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Molecular mechanisms of G2/M checkpoint regulation
Kořínková, Klára ; Macůrek, Libor (advisor) ; Forman, Martin (referee)
Cell division is necessary for maintaining tissue homoeostasis, but at the same time its defects are closely related to the development of many diseases including cancer and premature ageing. Activation of oncogenes leads to replication stress and directly threatens genome stability. The right control of transition between interphase and mitosis is an important mechanism for the protection of genome integrity. Nuclear division is only possible with those cells in which flawless duplication of genetic information occurred. By contrast, cells with damaged DNA structure remain temporarily or permanently stopped at G2 phase of the cell cycle. The topic of this thesis is a detailed literature overview with the subject of molecular mechanisms of the G2/M transition regulation under unperturbed conditions and in the presence of damaged DNA.
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Role of Polo-like kinases in the cell cycle and DNA damage response
Kudláčková, Radmila ; Macůrek, Libor (advisor) ; Šolc, Petr (referee)
Within the process of cell division, genetic material must be equally distributed between the two daughter cells. In the next phase, the missing portion of the genome must be synthesized. The entire cycle is regulated by cyclin-dependent kinases (Cdks) in cooperation with cyclins. If the DNA is damaged during the cell cycle, signaling pathways of checkpoints supress cycle progression and enforce the cell cycle arrest until the damage is repaired. Malfunction of the checkpoints results in tumorigenesis. Polo-like kinases (Plks) are, much like Cdks, important regulators of the cell cycle. Plks play significant role mainly in the mitosis and also in a response to the DNA damage. This thesis is focused on human homologues, nevertheless conservation of homologues among organisms is considerable, thus presented findings are of general relevance. Human cells express five proteins from the family of Polo-like kinases, from which Plk1 corresponds to Polo-like kinases of lower eukaryotes. Knowledge on the remaining four kinases is still on the rise.
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Molecular mechanisms of checkpoint signalling and termination
Benada, Jan ; Macůrek, Libor (advisor) ; Brábek, Jan (referee) ; Truksa, Jaroslav (referee)
Cells employ an extensive signalling network to protect their genome integrity, termed DNA damage response (DDR). The DDR can trigger cell cycle checkpoints which prevent cell cycle progression and allow repair of DNA damage. The failures in these safeguarding mechanism are represented by serious human malignancies, most predominantly by cancer development. This work aims to contribute to the understanding of how do the cells negatively regulate DDR and cell cycle checkpoint signalling. We focused mainly on Wip1 (PPM1D) phosphatase, which is a major negative regulator of DDR and is indispensable for checkpoint recovery. Firstly, we have shown that Wip1 is degraded during mitosis in APC-Cdc20 dependent manner. Moreover, Wip1 is phosphorylated at multiple residues during mitosis, resulting in inhibition of its enzymatic activity. We suggest that the abrogation of Wip1 activity enables cells to react adequately even to low levels of DNA damage encountered during unperturbed mitosis. In the following publication, we have investigated why the mitotic cells trigger only early events of DDR and do not proceed to the recruitment of DNA repair factors such as 53BP1. We showed that 53BP1 is phosphorylated within its ubiquitination-dependent recruitment domain by CDK1 and Plk1. These phosphorylations prevents...
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