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Where transcription meets translation
Hegrová, Karolína ; Krásný, Libor (advisor) ; Mašek, Tomáš (referee)
Transcription and translation are key steps in gene expression. The RNA polymerase (RNAP) plays a major role in the transcription process, while the ribosome is involved in translation. In bacteria, these two processes are not separated. RNAP and the ribosome interact, and its called transcription- translation coupling. In this thesis, I discuss the mechanism of transcription and translation, with the main focus on transcription-translation interactions. I divide these interactions into indirect, which are caused by regulátory molecules, and direct, where the ribosome directly binds with RNAP. When physical binding occurs, either a tight junction between these molecules occurs or a bridge is formed by transcription factors. Then I describe regulatory function of this connection and explain the exceptions where transcription and translation don't link. In the last part of the thesis, I focus on elongation factor Tu (EF-Tu), its important role in metabolism, its interactions with MreB protein, and how this factor is used by some bacteriophages. Finally, I mention its possible role in transcription-translation interactions. Key words: transcription, translation, transcription-translation coupling, RNA polymerase, ribosome, transcription factors, EF-Tu
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The role of ribosomal proteins in the plant development
Jirásková, Veronika ; Raabe, Karel (advisor) ; Smýkal, Petr (referee)
The translation is one of the fundamental cell processes, in which the protein is synthesized according to the sequence of the mRNA molecule. The foremost recognized element of the translation machinery is the ribosome, a molecule complex composed by rRNAs and ribosomal proteins. In plants, ribosomal proteins are encoded by more than one gene, which may lead to sub- functionalization and neo-functionalization of ribosomal protein paralogs in plant development or in the reaction to the contemporary environment. Assembly of ribosomal subunits from different ribosomal protein paralogs could lead to functionally distinct pools of ribosomes with specialized role in the translation and its regulation in plants. The aim of this work is to review current data regarding the individual ribosomal proteins function within the plant growth and development. Keywords translation, translation regulation, ribosome, ribosomal proteins
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Role of small ribosomal proteins forming the decoding site in translation.
Hovorková, Zuzana ; Valášek, Leoš (advisor) ; Hálová, Martina (referee)
Translation is one of the key mechanisms occurring in the cell during every second of its existence. It is a very complex process ensured by three main actors: tRNAs, mRNAs and ribosomes. Despite of being thoroughly studied over decades, the understanding of some of its functional aspects is still rather poor. This bachelor thesis focuses on four small ribosomal proteins listed below that are reaching to the decoding centre of the small ribosomal subunit. It raises awareness of the structure and function of uS12, uS19, eS25 and eS30, their evolution, role within the ribosome, and the influence they have on various stages of translation. In particular, this thesis specifically reviews the importance of these four proteins for the stop codon readthrough. This phenomenon occurs when a near-cognate aminoacyl-tRNA or a natural suppressor tRNA wins with eRF1 over the corresponding stop codon and thus protein synthesis is continued resulting in the existence of a longer protein. It summarizes our current knowledge of its origin, molecular details of its mechanism, its existence in different species, benefits and disadvantages it brings to the life of a cell or even an organism, and finally it sums up all available knowledge for potential future use of readthrough in therapeutics. Key words: translation,...
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The function of ABCF proteins in bacteria
Mičke, Bianka ; Balíková Novotná, Gabriela (advisor) ; Lišková, Petra (referee)
Translation belongs to the most basic processes which happens in the living cells. It is the last step of proteosynthesis when genetic information encoded by the mRNA is transformed into the protein on a ribosome. Organisms have developed a wide range of mechanisms that can regulate it's needs. I focused on one of them - ABCF proteins. This protein group is a member of the ABC transporters superfamily but they haven't a transmembrane domain and their purpose is protect the ribosomes from antibiotics that bind 50S ribosomal subunit or interact with the ribosomes and influence ribosomal functions. Today, we can divide ABCF proteins into the two functional groups: antibiotic resistence proteins (ARE) and proteins with the regulatory functions. The translational regulatory function has been confirmed There is 45 ABCF protein subfamilies spread through the bacteries and eukaryotes but many essential informations like the structure and exact function of them are still missing. My bachelor thesis is analysis and summary of facts that are known about the bacterial ABCF proteins. Key words: ABCF proteins, antibiotic resistence, ARE, translational regulation, ribosome, translation, translational factors
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