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Construction and characterization of recombinant adenylate cyclase toxoid of bacterium Bordetella pertussis carrying mycobacterial antigen TB7.7
Mikulecký, Pavel ; Staněk, Ondřej (advisor) ; Vopálenský, Václav (referee)
Bacterium Mycobacterium tuberculosis is an etiological agent of a deadly disease called tuberculosis that presents a global problem. According to The World Health Organization there are more than 2 billions people infected with latent tuberculosis all over the world. There is still need of specific, sensitive, quick and economic available method for identification of infected individuals. Currently in vitro blood tests are considered to be the best way of diagnosis. They are based on restimulation of specific T lymphocytes by mycobacterial antigens derived from virulent strains. There are several different approaches for enhancing of direct antigen delivery into antigen presenting cells and promising one is a genetically detoxified adenylate cyclase toxin (CyaA) of bacteria Bordetella pertussis. The main aim of the thesis includes construction and subsequent characterization of biological properties of CyaA protein carrying specific mycobacterial antigen TB7.7 in translocating domain. Here is shown that fusion protein CyaA-TB7.7 can form cation selective pores in target cell membranes and is able to deliver antigens into the cytosol of APC to be presented on surface with molecules MHC class II. Genetically detoxified CyaA- TB7.7 protein will be used to supplement current approaches such as also in vitro...
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Increasing affinity of Interferon gamma receptor 1 to Interferon gamma by combining molecular modeling and experimental methods
Mikulecký, Pavel
Protein-protein interactions play an important role in nearly all processes of the living cells and the function of many proteins is dependent on their specific interactions with other biomolecules. A reliable tool to modulate these interactions would be invaluable for the development of molecules suitable for diagnostics, medicine, and biotechnology. In this work, we aimed to study the specificity of interactions in the model system of Interferon gamma receptor 1 (IFNgR1) and its natural ligand Interferon gamma (IFNg), important in innate immunity. We searched for mutations within the interferon receptor molecule IFNgR1 to modulate (increase as well as decrease) its affinity to IFNg by in silico analysis of the existing crystal structures of the complex between IFNgR1 and IFNg. We modeled amino acid substitutions and gauged how they influenced the interaction using empirical force field implemented in software FoldX. All selected promising IFNgR1 variants were expressed in Escherichia coli, purified to homogeneity, characterized, and kinetics of their interactions with IFNg was measured by Surface Plasmon Resonance (SPR). The first set of IFNgR1 variants included mutations on the interface of the IFNg/IFNgR1 complex. According to our SPR measurements, the affinity of most of these receptor...
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Protein engineering as a tool for the production of antibody derivatives
Šulc, Josef ; Bařinka, Cyril (advisor) ; Mikulecký, Pavel (referee)
This thesis deals with production and properties of disulfide-stabilized single-chain variable fragments of the 5D3 antibody (dsscFv), which specifically recognizes and binds to glutamate carboxypeptidase II (GCPII), an antigen closely related to the prostate carcinoma processes and other tumor diseases. Small antibody fragments are in current focus of development of diagnostic and therapeutic reagents. However, compromised stability of antibody derivatives often results in low production yield or loss of function. Introduction of structural changes by protein engineering is often used to solve the issue. The aim of the study was based on enhancement of protein stability by the introduction of interdomain disulfide bond into the structure of single-chain variable fragment. The effect of modification was evaluated by estimation of production yield and affinity of studied protein. The aforementioned antibody derivative was produced using an Escherichia coli expression system, using specific signal sequences leading the production to the bacterial periplasm. The attempted stabilization was carried out by introducing mutations at LV-G44 and HV-G100 positions, replacing glycines with cysteines. The binding affinity of the derivative for human GCPII was determined using ELISA. This thesis also shows a solved 3D...
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Increasing affinity of Interferon gamma receptor 1 to Interferon gamma by combining molecular modeling and experimental methods
Mikulecký, Pavel ; Schneider, Bohdan (advisor) ; Šulc, Miroslav (referee) ; Vaněk, Ondřej (referee)
Protein-protein interactions play an important role in nearly all processes of the living cells and the function of many proteins is dependent on their specific interactions with other biomolecules. A reliable tool to modulate these interactions would be invaluable for the development of molecules suitable for diagnostics, medicine, and biotechnology. In this work, we aimed to study the specificity of interactions in the model system of Interferon gamma receptor 1 (IFNgR1) and its natural ligand Interferon gamma (IFNg), important in innate immunity. We searched for mutations within the interferon receptor molecule IFNgR1 to modulate (increase as well as decrease) its affinity to IFNg by in silico analysis of the existing crystal structures of the complex between IFNgR1 and IFNg. We modeled amino acid substitutions and gauged how they influenced the interaction using empirical force field implemented in software FoldX. All selected promising IFNgR1 variants were expressed in Escherichia coli, purified to homogeneity, characterized, and kinetics of their interactions with IFNg was measured by Surface Plasmon Resonance (SPR). The first set of IFNgR1 variants included mutations on the interface of the IFNg/IFNgR1 complex. According to our SPR measurements, the affinity of most of these receptor...
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Increasing affinity of Interferon gamma receptor 1 to Interferon gamma by combining molecular modeling and experimental methods
Mikulecký, Pavel
Protein-protein interactions play an important role in nearly all processes of the living cells and the function of many proteins is dependent on their specific interactions with other biomolecules. A reliable tool to modulate these interactions would be invaluable for the development of molecules suitable for diagnostics, medicine, and biotechnology. In this work, we aimed to study the specificity of interactions in the model system of Interferon gamma receptor 1 (IFNgR1) and its natural ligand Interferon gamma (IFNg), important in innate immunity. We searched for mutations within the interferon receptor molecule IFNgR1 to modulate (increase as well as decrease) its affinity to IFNg by in silico analysis of the existing crystal structures of the complex between IFNgR1 and IFNg. We modeled amino acid substitutions and gauged how they influenced the interaction using empirical force field implemented in software FoldX. All selected promising IFNgR1 variants were expressed in Escherichia coli, purified to homogeneity, characterized, and kinetics of their interactions with IFNg was measured by Surface Plasmon Resonance (SPR). The first set of IFNgR1 variants included mutations on the interface of the IFNg/IFNgR1 complex. According to our SPR measurements, the affinity of most of these receptor...
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Construction and characterization of recombinant adenylate cyclase toxoid of bacterium Bordetella pertussis carrying mycobacterial antigen TB7.7
Mikulecký, Pavel ; Vopálenský, Václav (referee) ; Staněk, Ondřej (advisor)
Bacterium Mycobacterium tuberculosis is an etiological agent of a deadly disease called tuberculosis that presents a global problem. According to The World Health Organization there are more than 2 billions people infected with latent tuberculosis all over the world. There is still need of specific, sensitive, quick and economic available method for identification of infected individuals. Currently in vitro blood tests are considered to be the best way of diagnosis. They are based on restimulation of specific T lymphocytes by mycobacterial antigens derived from virulent strains. There are several different approaches for enhancing of direct antigen delivery into antigen presenting cells and promising one is a genetically detoxified adenylate cyclase toxin (CyaA) of bacteria Bordetella pertussis. The main aim of the thesis includes construction and subsequent characterization of biological properties of CyaA protein carrying specific mycobacterial antigen TB7.7 in translocating domain. Here is shown that fusion protein CyaA-TB7.7 can form cation selective pores in target cell membranes and is able to deliver antigens into the cytosol of APC to be presented on surface with molecules MHC class II. Genetically detoxified CyaA- TB7.7 protein will be used to supplement current approaches such as also in vitro...
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