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Role of 5-azacytidine in therapy of myelodysplastic syndrome
Machalová, Veronika ; Hodný, Zdeněk (advisor) ; Indrová, Marie (referee)
The myelodysplastic syndrome (MDS) is a group of hematopoietic clonal disorders resulting in the inefficient production of myeloid lineage blood cells, with the prevalence of patients older than 65 years. One of the possible treatment options for MDS is 5- azacytidine and 5-aza-2'-deoxycytidine therapy. These compounds have been shown to cause the induction of cell-cycle arrest, cell differentiation and/or apoptosis. The in vitro experiments with 5-aza-2'-deoxycytidine indicated that this compound causes the premature cellular senescence, a state of the irreversible cell-cycle arrest. We have asked, whether 5-azacytidine, as a molecule with similar structure, is capable of causing the same effect. This treatment strategy could be beneficial in case that the negative pro- inflammatory effect of senescent cells on their surroundings can be nullified. In this thesis we have shown that 5-azacytidine induces DNA damage response, which is described as a fundamental event for the onset of the cell senescence. We tested 5- azacytidine treated HeLa cells for several markers of the cell senescence - the increase of the β-galactosidase activity, the PML and PML nuclear bodies and the formation of persistent DNA damage signaling lesions - albeit all these markers were positive, it was the very low increase in...
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DNA damage and signalling pathways in cellular senescence
Hubáčková, Soňa ; Hodný, Zdeněk (advisor) ; Dvořák, Michal (referee) ; Růžičková, Šárka (referee)
Organisms such as mammals need tissue renewal as an important process for maintenance of their viability. Because proliferation is essential also for tumourigenesis, cells need tumour-suppressor mechanisms to protect organism against cancer. Cellular senescence, the permanent state of cell-cycle arrest, features one of these intrinsic barriers against tumourigenesis after DNA damage and understanding of this process may lead to finding of novel therapeutic targets and to optimization of chemotherapy for patients with cancer. In the first part of the PhD thesis, we investigated activation of JAK/STAT signalling pathway in drug-induced senescence. We used genotoxic drugs like aphidicolin, camptothecine, 5-bromo- 2'-doexyuridin, etoposide or thymidine to induce premature senescence in normal and cancer cells. All this chemicals were able to persistently activate JAK/STAT signalling in monitored cells. Activation of STATs was accompanied with up-regulation of expression of interferon-stimulated genes (ISGs), such as MX1, IRF1, IRF7 and PML. Since IRF1 and IRF7 can be directly involved in stimulation of the IFN genes, we show activated expression as well as secretion of IFNbeta and IFNgamma, but not IFNalpha in drug-induced senescent cells. Furthermore, an inhibition of JAK1 as a major kinase of STAT...
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DNA damage and signalling pathways in cellular senescence
Hubáčková, Soňa
Organisms such as mammals need tissue renewal as an important process for maintenance of their viability. Because proliferation is essential also for tumourigenesis, cells need tumour-suppressor mechanisms to protect organism against cancer. Cellular senescence, the permanent state of cell-cycle arrest, features one of these intrinsic barriers against tumourigenesis after DNA damage and understanding of this process may lead to finding of novel therapeutic targets and to optimization of chemotherapy for patients with cancer. In the first part of the PhD thesis, we investigated activation of JAK/STAT signalling pathway in drug-induced senescence. We used genotoxic drugs like aphidicolin, camptothecine, 5-bromo- 2'-doexyuridin, etoposide or thymidine to induce premature senescence in normal and cancer cells. All this chemicals were able to persistently activate JAK/STAT signalling in monitored cells. Activation of STATs was accompanied with up-regulation of expression of interferon-stimulated genes (ISGs), such as MX1, IRF1, IRF7 and PML. Since IRF1 and IRF7 can be directly involved in stimulation of the IFN genes, we show activated expression as well as secretion of IFNbeta and IFNgamma, but not IFNalpha in drug-induced senescent cells. Furthermore, an inhibition of JAK1 as a major kinase of STAT...
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Vztah mezi genetickými polymorfismy DNA reparačních genů a jejich expresí u zdravé populace (s výhledem na stanovení u onkologických pacientů).
Hánová, Monika ; Vodička, Pavel (advisor) ; Bencko, Vladimír (referee) ; Černá, Marie (referee)
DNA damage response is a complex system responsible for protection of a cell against internal and external DNA damaging agents and in maintaining genome integrity. Many of genes participating in DNA damage response pathways are polymorphic. Genetic polymorphisms in coding and regulatory regions may have impact on the function of proteins encoded by the genes. Phenotypic effect of single nucleotide polymorphisms (SNPs) is subject of investigation in connection with the ability of a cell to manage genotoxic stress and subsequently, in relation to cancer susceptibility. The aim of this thesis was to evaluate the association between SNPs in DNA repair genes (hOGG1, XRCC1, XPC) and cell cycle genes (TP53, p21CDKN1A , BCL2 and BAX) and their mRNA expression in peripheral blood lymphocytes from individuals occupationally exposed to styrene and control individuals. The aim was extended to analyses of relationships between mRNA expression levels of the above-mentioned genes and markers of exposure to styrene (concentration of styrene in blood and in air), markers of DNA damage (single strand breaks - SSBs, and endonuclease III specific sites - Endo III sites) and the base excision repair (BER) capacity, by means of γ-irradiation specific DNA repair rates and oxidative repair. Study on the group of healthy...
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Dynamics of selected DNA damage response proteins
Benada, Jan ; Hodný, Zdeněk (advisor) ; Kuthan, Martin (referee)
DNA damage response (DDR) represents a vital signaling network that protects genome integrity and prevents development of cancer. Therefore the study of DDR is of a crucial clinical importance and DDR proteins are promising therapeu- tic targets. Although the great advances have been made mapping out interac- tions between individual DDR proteins, better understanding of complex behav- ior of this network is still needed. One approach, which might help us in this task, is to describe the dynamics of key proteins under different conditions. The first objective of this study was to investigate whether the temporal dynamics of selected DDR proteins differ upon different genotoxic insults, particularly upon γ- irradiation and UV-C irradiation. We showed that under certain insult some DDR proteins exhibit a monotone continuous activation pulse, while the activation of others triggers a series of pulses. We observed a previously described pulsative dynamics of p53 after γ-irradiation in MCF7 cells. Interestingly, we detected a monotone increase of p53 in U2OS after γ-irradiation and similar dynamics upon UV-C irradiation. We suggest that p53 dynamics depends on the presence or ab- sence of effective negative feedback loops between the upstream p53-activating kinases and Wip1 phosphatase. In the second...
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Posttranlational protein modifications in response to DNA damage
Kroupa, Michal ; Hodný, Zdeněk (advisor) ; Novotný, Marian (referee)
- 5 - Abstract Thousands of DNA lessions occur in each cell every day of which the most toxic are double-strand breaks (DSBs). Signaling of their presence and subsequent repair are mediated by so-called DNA-damage response mechanism (DDR), which involves accumulation of many effector proteins into DSBs sites. These molecular accumulation at DSBs are termed DNA damage foci. Depending on presence of sister chromatid, DSBs are repaired by two major mechanisms: by homologous recombination and by non-homologous end joining. Both pathways lead to activation of checkpoint kinases (Chk1 or Chk2) which iniciate checkpoints in cell cycle and allow repair of damaged DNA. Signaling of DNA damage and activation of these pathways are regulated by posttranslational protein modifications. These enzymatic reactions involve mainly phosphorylation, ubiquitination and sumoylation. Recently it was shown that ubiquitination of damaged chromatin is a prerequisite for sumoylation of tumor supressors BRCA1 and 53BP1. Failure in DNA damage recognizing mechanisms caused by disorders such as modifications or mutations of 53BP1 and BRCA1 genes can lead to subsequent disruption of genomic integrity and then a high risk for selection of cell clones with tumorigenic potencial. Current research is focused on regulation of posttranslational...
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Implication of eukaryotic DNA repair machinery in viral replication
Hron, Tomáš ; Španielová, Hana (advisor) ; Harant, Karel (referee)
Eukaryotic DNA damage response is an important mechanism which ensures genome stability. Its components are also mobilized during viral infection as a reaction against extraneous nucleic acid. Additionally, DNA repair machinery seems to be activated by some viruses purposely to provide their replication. This activation is mediated mainly by viral proteins which are able to interact with cellular factors. In many cases, key components of DNA damage mechanisms are associated with viral replication centre and likely participate in this process. Furthermore, cellular DNA damage signaling is exploited to provide competent environment for viral reproduction. However, particular mechanisms how these cellular factors participate in viral infection are still largely unclear. In this thesis, the principles of relationship between viral infection and eukaryotic DNA damage response are summarized and main viral families which are known to activate and utilize these mechanisms for its genom replication are described.
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Role of the tumour suppressor PML in DNA damage response and cellular senescence after genotoxic stress
Knoblochová, Lucie ; Hodný, Zdeněk (advisor) ; Horníková, Lenka (referee)
The promyelocytic leukemia protein (PML) is a tumour suppressor. It has been reported that PML interaction with the p53 protein is involved in the activation of cell cycle checkpoints and, when persistent, may lead to the premature onset of cellular senescence. Cellular senescence is a state of permanent cell growth arrest that is associated with characteristic morphological and metabolic changes and persistent DNA damage signalling. Importantly, PML nuclear bodies coassociate with persistent DNA damage foci in senescent cells; however, the role of this interaction is still obscure. My goal was to characterize the role of PML in DNA damage response (DDR) and the induction of premature cellular senescence after genotoxic stress, namely X-radiation, using both siRNA-mediated PML knock down (PML KD) and complete PML knock out (PML KO) in human cells. The dynamics of DNA damage foci, levels of various proteins involved in DDR, and proliferation rate were measured in both PML KD and KO cells. No significant changes in the formation of DNA damage foci, activated DDR (p53 and Chk2), activated p21CIP1/WAF1 cyclin-dependent kinase inhibitor, senescent morphology, and SA-β-galactosidase activity in PML KO cells were observed. However, PML KO cells displayed higher levels of retinoblastoma protein (Rb) and...
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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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Role of PML in nucleolar functions
Kučerová, Alena ; Hodný, Zdeněk (advisor) ; Skalníková, Magdalena (referee)
Promyelocytic leukemia protein (PML) is a tumour suppressor which is frequently downregulated in human tumours. PML plays a role in many cellular processes including DNA damage response, senescence and apoptosis and is mainly localized in special structures called PML nuclear bodies (PML NBs). The nucleolus is a key nuclear compartment, where transcription of ribosomal DNA and biogenesis of ribosomes take place. The nucleolus is also called a stress sensor because of its role, for instance, in stabilization of tumour suppressor p53. Localization of PML to the nucleolar periphery appears to be prominent after disturbance of nucleolar functions - for example inhibition of rRNA transcription or processing. Thus the relationship between the nucleolus and PML nuclear bodies may be important for cellular response to stress. However, the role of PML nucleolar associations in nucleolar function including mechanism of formation of these structures remain unclear. Here we characterised PML nucleolar structures and mechanism of their formation. We showed that formation of PML nucleolar structures is not caused by replication stress, is not dependent on any specific phase of cell cycle and is not caused by DNA damage response but is induced by topological stress due to inhibition of toposiomerase function....
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