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Role of RACK1 in translation regulation during stress conditions
Chvalová, Věra ; Groušl, Tomáš (advisor) ; Převorovský, Martin (referee)
RACK1 (Receptor for activated C kinase 1) is an evolutionary conserved protein which has essential role in most studied eukaryotic organisms, except for yeast. Although RACK1 was originally described as a binding partner of protein kinase C, later studies re- vealed its significant role in other cellular signalizations such as MAPK, Src or FAK. Thanks to this, RACK1 participates in the regulation of key cellular processes including migration, apoptosis or translation. As a binding partner of a small ribosomal subunit, RACK1 contributes to transla- tion regulation by integrating signals from different cellular pathways and several transla- tional components such as PKC and eIF6. Moreover, RACK1 has a role in translation regu- lation during stress. Under stress conditions there is a global reduction of translation, in- creased expression of specific mRNAs important for cellular stress response and formation of cytosolic foci called stress granules (SGs). SGs play an important role in protection of mRNAs and translation components against degradation. SGs also function in prevention of apoptosis. RACK1 has been identified as one of many components of SGs and its localization into SGs leads to inhibition of RACK1-mediated pro-apoptotic pathways. Aim of this diploma thesis was to elucidate the role of...
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Identification of a new mechanism of Lck regulation via its C-terminal sequence
Valečka, Jan ; Filipp, Dominik (advisor) ; Vomastek, Tomáš (referee)
T-cell activation is a complex process crucial for a proper function of immune system. It has been extensively studied and its main features are well understood. However, some of the events involved in T-cell signalling are still unclear. After T-cell receptor stimulation, Src-family kinase Lck drives the initiation of signalling by tyrosine phosphorylation. Phosphorylation of several downstream targets is dependent on the redistribution of Lck to the different compartment of the plasma membrane, called lipid rafts. In lipid rafts, active Lck is juxtaposed and activates raft-resident substrates which then trigger downstream signalling. The critical in this process is the mechanism of Lck translocation to lipid rafts which has not been studied so far and represents the topic of great academic and clinical interests. Previously, we identified the adaptor protein RACK1 as a candidate protein mediating the redistribution of Lck to lipid rafts by linking it to the microtubular network. In this thesis, we analysed the structural features and functional role of RACK1 in its interaction with Lck. We show here, using the SYF cell lines expressing the wild type and various mutated forms of Lck, that intact SH3 or SH2 domains of Lck are required for an effective RACK1-Lck complex formation. We also documented...
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The regulation of the ERK signalling pathway by scaffold protein RACK1
Bráborec, Vojtěch ; Vomastek, Tomáš (advisor) ; Filipp, Dominik (referee)
The ERK signalling cascade comprised of protein kinases Raf, MEK and ERK is an evolutionarily conserved member of MAPK family that is activated in response to wide range of extracellular stimuli. The ERK pathway controls fundamental cellular functions including cell proliferation, differentiation, apoptosis or cell motility. To control such a diverse cellular responses by a single pathway cells have evolved regulatory mechanisms that channel the extracellular signals towards the specific biological response. Crucial to this control are non- enzymatic proteins termed scaffolds that associate with and enhance functional interaction of the components of MAPK pathways and can regulate amplitude, timing, specificity and location of signals. Scaffold protein RACK1 associates with several components of cell migration machinery including integrins, FAK, Src and the ERK pathway core protein kinases. RACK1 regulates distinct steps of cell migration such as establishment of cell polarity and focal adhesion turnover, however, the molecular mechanism by which RACK1 regulates these processes remains largely unknown. The main aim of this study was to investigate the functional role of RACK1 in cell motility, in particular to identify new effector proteins utilized by the ERK pathway and RACK1 in the regulation of...
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