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Large-Scale Analysis of the Ligand Transport and Docking inside of the Protein Tunels
Ježík, Andrej ; Martínek, Tomáš (referee) ; Musil, Miloš (advisor)
This thesis discusses large-scale analysis of the ligand transport and docking inside of the protein tunnels. Protein-ligand interactions are involved in processes such as cell signalling, transport, metabolism, regulation, gene expression, and enzyme activity. To understand the interaction between these molecules is vitally important for the research for new pharmaceuticals. The procedure of protein-ligand docking involves the following steps: (i) finding the structures of proteins (receptors) and ligands, (ii) identifying ligand binding sites, (iii) considering receptor/ligand flexibility, and (iv) computing interaction energy between the receptor and the ligand. Additional functionality will be implemented to allow CaverWeb to test a complete set of pre-processed drug ligands on a protein, in an effort to enhance the efficiency of the procedure for large sets of ligands, which will allow a much smoother workflow.
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Interaction of Cytochromes P450 with Flavodoxin: a theoretical study
Culka, Martin ; Martínek, Václav (advisor) ; Chmelík, Josef (referee)
Cytochromes P450 are diverse group of heme enzymes found in most species on Earth. In humans they are involved in metabolism of foreign compounds or steroids, bacteria employ cytochromes P450 for utilization of various hydrophobic substrates. General reaction catalyzed by cytochromes P450 is monooxygenation, when one atom of oxygen molecule is introduced into the substrate, while the other is reduced producing water. NADPH:cytochrome P450 oxidoreductase or cytochrome b5 usually serves as an electron donor providing electrons needed for activation of oxygen in eukaryotic organisms, in bacteria small FeS proteins or flavoproteins are these electron donors. It was shown earlier that bacterial electron donor flavodoxin could also interact with human cytochromes P450 in vitro. This thesis employs molecular modeling techniques to support a hypothesis that flavodoxin is responsible for reduction of human (1A2, 2A6, 2A13, 2C9, 2C19, 3A4) and bacterial (101A1 a 176A1) cytochromes P450 heterologously expressed in Escherichia coli. An initial guess of possible mutual orientations of cytochrome P450 and flavodoxin was predicted using information-driven protein-protein docking. The stability of these complexes was examined by directed dissociation method. The most stable orientation for each cytochrome P450 was further...
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Preparation and Characterization of Protein Binders Mimicking Epitopes of HIV-1 Neutralizing Antibodies
Šulc, Josef ; Malý, Petr (advisor) ; Novotný, Marian (referee)
For three decades, the ongoing HIV pandemic has taken the lives of tens of millions of people. Still, more tens of millions are fighting this incurable disease today. Current failures in combating this global problem are caused mainly by the virus's extreme ability of mutation, its very effective molecular shield which repels the immune system's attacks, and its immense variability. A breakthrough, achieved relatively recently, is the discovery of the so-called broadly neutralizing antibodies against HIV-1, which carry a very efficient and broad neutralizing response. So far, it's not known how to elucidate the production of these antibodies in the infected hosts to quell or altogether eliminate the virus. This work deals with experimental results, which led to both in vivo and in vitro proof-of-concept of the so-called protein mimetics, the ability to imitate viral surface epitopes, and therefore stimulate an efficient immune response carried by targeted broadly neutralizing antibodies. This effect is mediated by recombinant binding proteins, based on the Myomedin scaffold. This work describes the selection and characterization of these binding proteins mimicking the epitopes of one of the most effective broadly neutralizing antibodies, 10E8. It shows that the binding affinities of selected...
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Large-Scale Analysis of the Ligand Transport and Docking inside of the Protein Tunels
Ježík, Andrej ; Martínek, Tomáš (referee) ; Musil, Miloš (advisor)
This thesis discusses large-scale analysis of the ligand transport and docking inside of the protein tunnels. Protein-ligand interactions are involved in processes such as cell signalling, transport, metabolism, regulation, gene expression, and enzyme activity. To understand the interaction between these molecules is vitally important for the research for new pharmaceuticals. The procedure of protein-ligand docking involves the following steps: (i) finding the structures of proteins (receptors) and ligands, (ii) identifying ligand binding sites, (iii) considering receptor/ligand flexibility, and (iv) computing interaction energy between the receptor and the ligand. Additional functionality will be implemented to allow CaverWeb to test a complete set of pre-processed drug ligands on a protein, in an effort to enhance the efficiency of the procedure for large sets of ligands, which will allow a much smoother workflow.
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Comparative structural analysis of Borreliella spp. virulent factors focusing on their surface topology conservation
Zdrha, Alois ; Drbal, Karel (advisor) ; Nunvář, Jaroslav (referee)
Gram-negative bacteria of genus Borreliella cause the nowadays spreading illness Lyme borreliosis. However, their classification as gram-negative bacteria is rather mislea- ding because they differ in their complex genome, pathogenic adaptation to their hosts and composition of their outer membrane. One species of borreliella can harbour up to 23 variable plasmids and one conserved chromosome and they still lack many crucial proteins needed for synthesis of key compounds. Hence, they have to obtain these compounds from the host. However, in order for borreliella to utilise the metabolic processes of the host, it has to first survive its immune response. Therefore borreliella contains many virulent factors including highly variable surface lipoproteins. The variability is a major obstacle to overcome when using their surface epitopes for detection and vaccine development because most of the dominant antigenic epitopes of borreliella are usually parts of the most variable regions of the lipoproteins. Nowadays, we can use many different algorithms which determine evolutionary conserved epitopes based on analysis of sequences of given lipoprotein, in order to find suitable targets for antibodies. In general, conserved epitopes are more suitable for vaccines, whereas more variable epitopes are better...
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Theoretical study of enzymes related to carcinogenesis: DNA polymerase β and cytochromes P450
Jeřábek, Petr ; Martínek, Václav (advisor) ; Entlicher, Gustav (referee) ; Ettrich, Rüdiger (referee)
Present doctoral thesis contributed to understanding of mechanistic principles of two enzymes participating in the process of carcinogenesis; DNA polymerase (pol ) and cytochromes P450 (CYP). Pol is part of the DNA base-excision repair mechanism (BER). The primary role of pol in, the BER mechanism, is inserting a new nucleotide into a DNA strand according to Watson-Crick base pairing rules. Pol plays an important role in the process of carcinogenesis, approximately 30 % of human tumors express pol mutants. The ability of pol to discriminate between "right" and "wrong" nucleotide during the insertion process is called fidelity. We employed computational methods to elucidate molecular basis of the fidelity of pol . First, the relative free energy calculation method LRA was employed to compare differences in free energies between the "right" and "wrong" nucleotide during its insertion into DNA. The results indicated a better stabilization of transition-state of the nucleophilic substitution catalyzed by pol in the case of the "right" versus "wrong" nucleotide. This difference resulted in an 80-fold contribution to its fidelity. Further, computational methods FEP and LIE were used to examine how mutations effect fidelity of pol . Results were than correlated with experimental data...
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Interaction of Cytochromes P450 with Flavodoxin: a theoretical study
Culka, Martin ; Martínek, Václav (advisor) ; Chmelík, Josef (referee)
Cytochromes P450 are diverse group of heme enzymes found in most species on Earth. In humans they are involved in metabolism of foreign compounds or steroids, bacteria employ cytochromes P450 for utilization of various hydrophobic substrates. General reaction catalyzed by cytochromes P450 is monooxygenation, when one atom of oxygen molecule is introduced into the substrate, while the other is reduced producing water. NADPH:cytochrome P450 oxidoreductase or cytochrome b5 usually serves as an electron donor providing electrons needed for activation of oxygen in eukaryotic organisms, in bacteria small FeS proteins or flavoproteins are these electron donors. It was shown earlier that bacterial electron donor flavodoxin could also interact with human cytochromes P450 in vitro. This thesis employs molecular modeling techniques to support a hypothesis that flavodoxin is responsible for reduction of human (1A2, 2A6, 2A13, 2C9, 2C19, 3A4) and bacterial (101A1 a 176A1) cytochromes P450 heterologously expressed in Escherichia coli. An initial guess of possible mutual orientations of cytochrome P450 and flavodoxin was predicted using information-driven protein-protein docking. The stability of these complexes was examined by directed dissociation method. The most stable orientation for each cytochrome P450 was further...
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