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Recombinant preparation of DNA binding domain of transcription factor TEAD1
Kúdelová, Veronika ; Novák, Petr (advisor) ; Dračínská, Helena (referee)
TEAD proteins belong to a significant family of transcription factors that contribute to the regulation of organism growth and cell differentiation during its development by activating the expression of a wide variety of genes. This family shares two highly conserved sites, the TEA DNA binding domain, after which the proteins have been named, and the domain by which transcription factors bind other coactivators. Because TEAD proteins are not able to activate transcription themselves, they interact with a number of coactivators. These coactivators allow the transcription of the gene of interest to be regulated. Failure of TEAD protein activity regulation can lead to cancer. Therefore, TEAD family proteins nowadays play an important role in the development of new anticancer drugs. One way of inhibiting these proteins is to block the active site in their DNA binding domain, thus, to block their binding to DNA. This bachelor thesis deals with recombinant expression of said DNA binding domain of transcription factor TEAD1, which is extended by amino acids in unstructured regions. After finding suitable conditions of protein production, we proceeded to large volume production which was followed by purification and protein identity verification. Finally, the ability of the produced protein to interact...
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Recombinant preparation of DNA binding domain of transcription factor TEAD4
Zákopčaník, Marek ; Novák, Petr (advisor) ; Šulc, Miroslav (referee)
6 Abstract Transcription factors play a key role in the management of cell growth and differ- entiation and their deregulation is associated with many cancers. TEAD proteins utilise highly conserved DNA binding domain to recognise specific DNA sequences. This domain could facilitate new drug design and development. The goal of this master thesis includes recombinant preparation of DNA binding domain of transcriptional factor TEAD4 extended by a part of an unstruc- tured variable sequence, which connects this domain with transactivation domain. Purification steps include affinity chromatography followed by size exclusion chro- matography. The characterization of produced protein was performed by mass spectrometry and finally, native gel electrophoresis was used to prove the ability of the produced protein to bind DNA. During purification steps, a fragmentation from C-terminus was observed. Based on analysis of the mass spectra, three most represented forms of produced protein were described all of which were fragmented. The most abundant form (55%) consisted of amino acids 30-131 from TEAD4 protein. Second most abun- dant form (18%) consisted of amino acids 30-144 and the third form consisted of amino acids 30-81. Native gel electrophoresis verified the ability to bind DNA, the efficiency was however lower...
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Recombinant preparation of DNA binding domain of transcription factor TEAD1
Kúdelová, Veronika ; Novák, Petr (advisor) ; Dračínská, Helena (referee)
TEAD proteins belong to a significant family of transcription factors that contribute to the regulation of organism growth and cell differentiation during its development by activating the expression of a wide variety of genes. This family shares two highly conserved sites, the TEA DNA binding domain, after which the proteins have been named, and the domain by which transcription factors bind other coactivators. Because TEAD proteins are not able to activate transcription themselves, they interact with a number of coactivators. These coactivators allow the transcription of the gene of interest to be regulated. Failure of TEAD protein activity regulation can lead to cancer. Therefore, TEAD family proteins nowadays play an important role in the development of new anticancer drugs. One way of inhibiting these proteins is to block the active site in their DNA binding domain, thus, to block their binding to DNA. This bachelor thesis deals with recombinant expression of said DNA binding domain of transcription factor TEAD1, which is extended by amino acids in unstructured regions. After finding suitable conditions of protein production, we proceeded to large volume production which was followed by purification and protein identity verification. Finally, the ability of the produced protein to interact...
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Model for study of transcription regulation of granulocytic genes MPO and MMP9 by different levels of PU.1 transcription factor
Chramostová, Kamila ; Pospíšil, Vít (advisor) ; Kleibl, Zdeněk (referee)
9 Abstract Enhancers are distal cis - regulatory DNA sequences that regulate (enhance) transcription of the respective gene driven by its promoter. Enhancers are found in non-coding DNA upstream or downstream of the gene coding sequence, or in introns or coding regions that are located up to hundreds kb away from the gene. Superenhancers are newly discovered clusters of multiple enhancers that play a vital role in activating tissue-specific genes, determining cell identity and regulating differentiation. PU.1 is the transcription factor (TF) that is necessary for normal haematopoiesis, specifically for the development of myeloid and lymphoid blood lineages. Distinct levels of PU.1 induce differentiation of hematopoietic cells into different cell lineages whereby disruption of PU.1 levels leads to leukemogenesis. High PU.1 levels stimulate macrophage development, while intermediate levels stimulate the development of granulocytes. This diploma thesis seeks to contribute to addressing the interesting biological question of what are the regulatory mechanisms to ensure that granulocytic genes are activated only at the intermediate concentration of PU.1, whereas macrophage genes are activated only at its high levels. The aim of this diploma thesis was to create a series of reporter vectors carrying regulatory...
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Regulation of expression of Ms1, a sRNA from Mycobacterium smegmatis
Páleníková, Petra ; Krásný, Libor (advisor) ; Lichá, Irena (referee)
Bacteria are exposed to various environmental conditions during their growth. They have to cope with rapid changes in temperature, lack of nutrition, etc. To survive, bacteria alter their gene expression. One type of regulation of gene expression is regulation by small RNAs (sRNAs). In bacteria, a well-studied sRNA is 6S RNA that binds to the RNA polymerase holoenzyme. However, 6S RNA has not been identified in several bacterial species. Mycobacteria are a genus that probably does not have 6S RNA. Instead, Mycobacterium smegmatis possess another sRNA - Ms1. Ms1 structurally resembles 6S RNA and indeed it was first identified as a 6S RNA structural homologue. However, Ms1 binds to RNAP devoid of any sigma factor, and, therefore, is significantly distinct from 6S RNA. This work describes regulation of expression of Ms1. DNA fragments of different length from the region upstream of the Ms1 gene were prepared. These fragments were fused to the lacZ reporter gene and their activity was tested in different growth phases and under stress. This allowed identification and characterization of the core promoter sequence and regulatory sequences that might interact with transcription factor(s). Promoter activity increased with increased length of the promoter fragment and after transition into stationary...
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