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Identification of novel substrates of PKN3 kinase and characterization of the role of phosphorylation in the regulation of Rho GAP activity
Dibus, Michal ; Rösel, Daniel (advisor) ; Vomastek, Tomáš (referee) ; Petrák, Jiří (referee)
Protein phosphorylation represents one of the most important posttranslational modifications in signal transduction and plays a crucial role in regulation of most of the cellular processes including cell cycle, communication with extracellular environment, cell migration or apoptosis. Phosphorylation is mediated by protein kinases, deregulation of which often negatively affects development and overall homeostasis and leads to development of several diseases, including cancer. In the first part of this work we focused on identification of new substrates of PKN3 kinase, which is a known player in regulation of cytoskeletal organization and pro-malignant tumor growth. Using an analog-sensitive mutant of PKN3 we performed a phosphoproteomic screen and identified 281 proteins that could potentially be phosphorylated by PKN3. Among these, we selected ARHGAP18, a protein from Rho GAP family, for further study. We confirmed PKN3 is able to phosphorylate ARHGAP18 on Thr154, Ser156 and Thr158 and that the two proteins are able to interact with one another in an ARHGAP18 isoform-specific manner. We further showed that substitution of the three candidate sites for phosphomimicking aspartate led to the activation of ARHGAP18 GAP domain which resulted in decreased levels of active RhoA, suggesting the existence...
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Regulatory mechanisms of centrosomal microtubule nucleation
Klebanovych, Anastasiya ; Dráber, Pavel (advisor) ; Hašek, Jiří (referee) ; Vomastek, Tomáš (referee)
The spatio-temporal organization and dynamic behavior of microtubules accurately react to cellular needs during intracellular transport, signal transduction, growth, division, and differentiation. The cell generates centrosomal microtubules de novo with the help of γ-tubulin complexes (γTuRCs). The post-translational modifications fine-tune microtubule nucleation by targeting the proteins, interacting with γTuRCs. However, the exact signaling pathways, regulating centrosomal microtubule nucleation, remain mostly unknown. In the presented thesis, we functionally characterized protein tyrosine phosphatase SHP-1 and E3 UFM-protein ligase 1 (UFL1) with its interacting protein CDK5RAP3 (C53) in the regulation of centrosomal microtubule nucleation. We also elucidated the role of actin regulatory protein profilin 1 in this process. We found that SHP-1 formed complexes with γTuRC proteins and negatively regulated microtubule nucleation by modulating the amount of γ-tubulin/γTuRC at the centrosomes in bone marrow-derived mast cells (BMMCs). We suggested a novel mechanism with centrosomal tyrosine-phosphorylated Syk kinase, targeted by SHP-1 during Ag-induced BMMCs activation, regulating microtubules. We showed for the first time that UFL1/C53 protein complex is involved in the regulation of microtubule...
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The role of ERK1 and ERK2 protein kinases in the MAPK/ERK signaling
Galvánková, Kristína ; Vomastek, Tomáš (advisor) ; Dráber, Peter (referee)
The MAPK/ERK cascade is highly conserved signalling pathway regulating cellular processes which are necessary for cell life, such as proliferation, differentiation, apoptosis or cell migration. All these cellular responses are the result of the processing of extracellular signals through three-tier ERK cascade consisting of protein kinases Raf, MEK and ERK. The signal is transmitted by sequential phosphorylation where RAF phosphorylates MEK and MEK phosphorylates and activates ERK. Protein kinase ERK then phosphorylates and regulates a wide range of substrates at different locations in the cell. This affects the cellular response to the extracellular signal. Regulation of this pathway on every level is very important and is modulated by interaction partners and adaptor proteins. Deregulation of the pathway as well as mutations of individual protein kinases can lead to severe pathological consequences. At the level of ERK, there are two isoforms, ERK1 and ERK2, which are more than 80 % identical at the amino acid level. Their high sequence similarity has triggered the interest of many authors for more detailed examination of both isoforms in respect of their evolutionary conservation and whether they are functionally redundant or whether they have specific functions. The aim of this work is to...
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Mechanisms of phenotypic plasticity induced by genotoxic stress
Přibyl, Miroslav ; Hodný, Zdeněk (advisor) ; Remešová, Hana (referee) ; Vomastek, Tomáš (referee)
Therapy resistance of malignant cells represents the main reason responsible for the failure of cancer therapy. The growth of malignant cells at primary tumour sites but most importantly the dissemination of tumour cells and their growth at secondary sites, are the main reasons why patients eventually succumb to the disease. Even novel immune-based therapies find their limitation in most tumour types. The therapy resistance is mediated by the tumour cells but also by other cellular components of the tumour microenvironment. Understanding the tumour cells mechanisms and the tumour microenvironment features responsible for therapy resistance enables the development of novel therapeutic strategies. Here, we show that ionizing irradiation, 5-azacytidine, and IFNγ treatments induced expression of suprabasin (SBSN) and therapy-resistant low-adherent phenotype in cancer cells. Knockdown of SBSN resulted in suppression of the phenotype. Next, we identified aberrantly elevated SBSN in the bone marrow of a subgroup of myelodysplastic syndromes (MDS) patients. SBSN was expressed by myeloid-derived suppressor cells (MDSCs) and showed significant anti-correlation with T cell abundance and CCL2 levels, hence promises a prognostic value in clinical use. We compiled the most of the relevant knowledge of SBSN...
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Mechanism of regulation of EGFR receptor ligand activation via the intramembrane pseudoprotease iRhom and cell surface metalloprotease ADAM17
Trávníčková, Květa ; Stříšovský, Kvido (advisor) ; Vomastek, Tomáš (referee)
Signalling through the EGF receptor is subject to a complex and multilayered regulation. One such mode of regulation is through control of ligand production which plays an important role in fine- tuning EGF receptor activation. In mammals, the production of soluble, biologically active forms of EGF receptor ligands relies on ADAM metalloproteases, predominantly ADAM10 and ADAM17. Recently, a pseudoprotease from the rhomboid-like family of intramembrane proteases, iRhom, emerged as a key positive regulator of ADAM17. However, Drosophila iRhom has also been implicated in the negative regulation of EGF receptor signalling by promoting the degradation of precursors of its ligands. Cell culture based assays suggest that mammalian iRhoms might also be involved in a similar process. In this thesis, the effect of mammalian iRhom overexpression on the levels of EGF receptor ligands has been investigated. Contrary to previous findings, the data presented in this thesis suggest that the observed effect might not be entirely iRhom specific, for the inactive mutants of rhomboid proteases also diminish the levels of EGF receptor ligands. Nor do we find the effect to be specific to EGF receptor ligands, as unrelated transmembrane proteins were also depleted by iRhom overexpression. The coexpression of ADAM17 was...
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Development of Biophysical Interpretation of Quantitative Phase Image Data
Křížová, Aneta ; Jákl, Petr (referee) ; Vomastek, Tomáš (referee) ; Chmelík, Radim (advisor)
This doctoral thesis deals with biophysical interpretation of quantitative phase imaging (QPI) gained with coherence-controlled holographic microscope (CCHM). In the first part methods evaluating information from QPI such as analysis of shape and dynamical characteristics of segmented objects as well as evaluation of the phase information itself are described. In addition, a method of dynamic phase differences (DPD) is designed to allow more detailed monitoring of cell mass translocations. All of these methods are used in biological applications. In an extensive study of various types of cell death, QPI information is compared with flow cytometry data, and preferably a combination of QPI and fluorescence microscopy is used. The DPD method is used to study mass translocations inside the cell during osmotic events. The simplified DPD method is applied to investigate the mechanism of tumor cell movement in collagen gels.
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Analyzing the role of the p130Cas SH3 domain in p130Cas-mediated signaling
Gemperle, Jakub ; Rösel, Daniel (advisor) ; Vomastek, Tomáš (referee) ; Truksa, Jaroslav (referee)
The adaptor protein p130Cas (CAS, BCAR1) represents a nodal signaling platform for integrin and growth factor receptor signaling, and influences normal development and tissue homeostasis. Its altered expression drives many pathological conditions including tumor growth, metastasis and drug resistance in many cancer types. How p130Cas contributes to many of these pathologies is still poorly understood. Therefore, the overall aim of my PhD work was to provide new insights to p130Cas signaling and its regulation. The SH3 domain is indispensable for p130Cas signaling, but the ligand binding characteristics of the p130Cas SH3 domain, and the structural determinants of its regulation were not well understood. To be able to study various aspects of p130Cas signaling we identified an atypical binding motif in p130Cas SH3 domain by establishing collaborations with Dr Veverka (Structural biology) and Dr Lepšík (Computational biochemistry; Academy of Sciences, CZ) which gave new insight into this binding interface. Through these collaborations I generated chimeras of p130Cas SH3 domain with its ligands for structural NMR analysis and learned how to visualize and analyze structures. Furthermore, my work expanded our knowledge of p130Cas SH3 ligand binding regulation and led to a novel model of Src-p130Cas- FAK...
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Quality control in snRNP biogenesis
Roithová, Adriana ; Staněk, David (advisor) ; Malínský, Jan (referee) ; Vomastek, Tomáš (referee)
(English) snRNPs are key components of the spliceosome. During their life, they are found in the cytoplasm and also in the nucleus, where carry out their function. There are five major snRNPs named according to RNA they contain U1, U2, U4, U5 and U6. Each snRNP consists from RNA, ring of seven Sm or LSm proteins and additional proteins specific for each snRNP. Their biogenesis starts in the nucleus, where they are transcribed. Then they are transported into the cytoplasm. During their cytoplasmic phase, the SMN complex forms the Sm ring around the specific sequence on snRNA and cap is trimethylated. These two modifications are the signals for reimport of snRNA into the nucleus, where they accumulate in the nuclear structures called Cajal bodies (CBs), where the final maturation steps occur. There are several quality control points during snRNP biogenesis that ensure that only fully assembled particles reach the spliceosome. The first checkpoint is in the nucleus immediately after the transcription, when the export complex is formed. The second checkpoint is in the cytoplasm and proofreads Sm ring assembly. If the Sm ring formation fails, the defective snRNPs are degraded in the cytoplasm by Xrn1 exonuclease. However, it is still unclear, how the cell distinguishes between normal and defective...
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The assembly of perinuclear actin stress fibers and their role in cell movement
Votavová, Barbora ; Vomastek, Tomáš (advisor) ; Cvačková, Zuzana (referee)
Nucleus is the largest cellular organelle in animal cells. Due to its bulky nature and the stiffness of nuclear lamina the nucleus constitutes the substantial problem for migrating cells where nucleus has to move. The actomyosin generated forces and LINC (Linker of Nucleoskeleton and Cytoskeleton) complex, that is composed of SUN and nesprin proteins, play key role in nuclear movement. LINC complex mechanically couples nuclear lamina to the cytoskeleton and allows the forces exerted by the cytoskeleton to move the nucleus. Perinuclear actin fibers, also termed actin cap, mechanically link focal adhesions with nucleus and they may generate forces that position the nucleus in a way that is optimal for cellular movement. However, molecular mechanism of how perinuclear actin fibers and LINC complex orchestrate the nuclear movement and functional significance of this process remain poorly understood. The specific aim was to determine the mechanisms by which perinuclear actin fibers are formed and how are these mechanisms employed to facilitate cell migration. The role of LPA-RhoA signaling axis and LINC complex in the formation of perinuclear actin fibers was also examined. It was confirmed that LPA is essencial stimulus during actin cap formation. On the other hand, FAK kinase was found necessary for...
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Regulation of Epithelial-Mesenchymal transition by the ERK pathway.
Čáslavský, Josef ; Vomastek, Tomáš (advisor) ; Brábek, Jan (referee) ; Gregor, Martin (referee)
Typical epithelium is uniformly polarized solid structure defined by the presence of cell-cell contacts that are connected to well-organized network of actin cytoskeleton. While epithelium is considered to be rather static, during embryogenesis or cancer development epithelial tissues undergo considerable dynamic changes in their integrity that are characterized by loss of epithelial polarity, disruption of cell-cell adhesions and gaining mesenchymal or mesenchymal-like migratory phenotype. These changes, collectively termed as epithelial-mesenchymal transition (EMT), allow cells to effectively invade surrounding tissues and are considered to be a main factor underlying the formation of metastatic cancer. The MAPK/ERK cascade, comprised of protein kinases Raf, MEK and ERK, induces the breakdown of epithelial integrity and cell autonomous migration in various cell lines. In the ERK pathway, ERK is an effector protein kinase which, depending on the cellular context, phosphorylates a number of different substrates. Spatiotemporal phosphorylation of specific constellation of ERK substrates drives specific biologic outcome. The question arises whether, during conversion of multicellular epithelium to autonomously migrating cells, ERK regulates a "master" controller or whether the ERK regulatory function...
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