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Structural characterization of influenza A polymerase PA subunit domains in complex with novel inhibitors
Radilová, Kateřina ; Kožíšek, Milan (advisor) ; Rumlová, Michaela (referee) ; Obšil, Tomáš (referee)
Influenza RNA-dependent RNA polymerase is a heterotrimeric complex and has an essential role in the life cycle of the virus. It is responsible for viral replication and transcription. One of its subunits, the polymerase acidic protein, interacts with the PB1 subunit via a crucial protein- protein interaction at its C-terminal domain. This 310 helix-mediated intersubunit interaction is required for the whole heterotrimer assembly. The N-terminal domain carries the endonuclease active site with two manganese ions. Both domains are considered promising drug targets. Current strategies to fight the influenza virus are limited to seasonal vaccines, and there are only a few anti-influenza drugs targeting mostly other viral proteins. Many used antivirals are susceptible to rapid resistance mutations development or cause severe side effects. This thesis provides structural insights into the two domains of the PA subunit. The first part is devoted to the characterization and optimization of a PB1-derived minimal peptide interacting with the C-terminal domain. Results from this part may be considered as a starting point for the rational design of first-in-class anti-influenza inhibitors of the PA-PB1 protein-protein interaction. In the other half, we have explored the inhibitory potency of flavonoids and...
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Mass Spectrometry-Based Identification of a Potential Binding Partner of Glutamate Carboxypetidase II
Tužil, Jan ; Konvalinka, Jan (advisor) ; Novák, Petr (referee)
English Abstract The incoming paradigm of the network (or systems) biology calls for a new high throughput tool for a wide scale study of protein-protein interactions. Mass spectrometry-based proteomics have experienced a great progress in recent years and have become an indispensable technology of elementary as well as clinical research. Glutamate carboxypeptidase II (GCPII; EC 3.5.17.21) is a transmembrane protein with two known enzymatic activities. Its expression is highly upregulated in some solid tumors and also in tumor-associated neovasculature in general. Nevertheless, none of the two enzymatic activities were shown to be physiologically relevant to these cells. Some facts point at a possible receptor function of GCPII, however, no specific binding partner has been found yet. In the search for potential binding partners and/or ligands of GCPII, a series of methods have been employed, including pull-down experiment, immunoprecipitation and mass spectrometry. Sample preparation and mass spectrometry data processing methodology was specifically developed in order to identify potential binding partners. As one of the outcome of that methodology, the interaction of β-subunit of F1 ATP synthase was selected for further detailed analysis as a putative ligand of GCPII.
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Identification of small compounds disrupting protein-protein interaction in influenza A polymerase.
Hejdánek, Jakub ; Konvalinka, Jan (advisor) ; Obšil, Tomáš (referee)
Influenza virus causes severe respiratory infections in birds and mammals and it is responsible for up to half a million deaths of human beings worldwide each year. Two molecular targets in influenza viral life cycle, neuraminidase and M2 proton channel are exploited in treatment. However, the recent emergence of new pandemic type along with increasing resistance against approved drugs has urged the need for a new drug target discovery and potential search of its inhibitor. Recently, an interesting protein-protein interaction between two subunits PA and PB1 of influenza A viral polymerase has been identified by X-ray crystallography as a new promising drug target. The fact that relatively few residues drive the binding and that the binding interface is highly conserved presents an intriguing possibility to identify antiviral lead compounds effective against all subtypes of influenza A virus. In our laboratory, we expressed and purified two fusion tag constructs of the recombinant C-terminal domain of polymerase acidic subunit (CPA) from the pandemic isolate A/California/07/2009 H1N1. First, GST-CPA fusion protein was used for kinetic evaluation of PA-PB1 interaction by surface plasmon resonance. Moreover, this construct was used in the development of high-throughput screening method for search of...
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Identification of small compounds disrupting protein-protein interaction in influenza A polymerase.
Hejdánek, Jakub ; Konvalinka, Jan (advisor) ; Obšil, Tomáš (referee)
Influenza virus causes severe respiratory infections in birds and mammals and it is responsible for up to half a million deaths of human beings worldwide each year. Two molecular targets in influenza viral life cycle, neuraminidase and M2 proton channel are exploited in treatment. However, the recent emergence of new pandemic type along with increasing resistance against approved drugs has urged the need for a new drug target discovery and potential search of its inhibitor. Recently, an interesting protein-protein interaction between two subunits PA and PB1 of influenza A viral polymerase has been identified by X-ray crystallography as a new promising drug target. The fact that relatively few residues drive the binding and that the binding interface is highly conserved presents an intriguing possibility to identify antiviral lead compounds effective against all subtypes of influenza A virus. In our laboratory, we expressed and purified two fusion tag constructs of the recombinant C-terminal domain of polymerase acidic subunit (CPA) from the pandemic isolate A/California/07/2009 H1N1. First, GST-CPA fusion protein was used for kinetic evaluation of PA-PB1 interaction by surface plasmon resonance. Moreover, this construct was used in the development of high-throughput screening method for search of...
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Interaction PI4 kinase IIalpha with VAMP3 protein
Dubánková, Anna ; Šulc, Miroslav (advisor) ; Teisinger, Jan (referee)
Phosphoinositides are very important in regulation activity of many signaling proteins not just in cellular membranes. Phosphatidylinositol - 4 - kinases (PI4K) generate phosphatidylinositol - 4 - phosphate, an emerging regulatory molecule and precursor of important regulatory phosphoinositides. PI4Ks are associated with pathogenicity of several RNA viruses including Picornaviridae (poliovirus, coxsackie virus, aichi virus, enterovirus 71) and Flaviviridae (hepatitis C virus). PI4Ks also play important role in cancer. This study strives to clarify the mechanism of regulation of PI4K type II α by its potential interaction with Vesicle - associated membrane protein 3 (VAMP 3) of the SNARE protein family (Soluble N - ethylmaleimide Sensitive Fusion Attachment Protein Receptor).
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Study of interactions of PI4 kinase
Eisenreichová, Andrea ; Šulc, Miroslav (advisor) ; Obšilová, Veronika (referee)
The family of 14-3-3 proteins is one of great regulatory significance, which can be found in all the eucaryotic organisms and consists of seven isoforms in human cells. The function of 14-3-3 proteins rests in the interaction with their ligands, of which several hundreds has been identified. The key role of these partners comes to pass in many cellular processes such as signalization, regulation of a cell cycle and division, apoptosis and others. This thesis deals with the interaction of 14-3-3 protein with fosfatidylinositol 4-kinase IIIβ on a molecular level using the method of X-ray crystallography. Phosphatidylinositol 4-kinase IIIβ (PtdIns4KIIIβ) situated on a cytosol side of mostly Golgi aparatus membranes catalyses the connection of a phosphate group to the fourth carbon of an inositol circle. The activity of PtdIns4KIIIβ depends upon the phosphorylation of Ser294. Not only this phosphorylation increases the kinase activity PtdIns4KIIIβ, but is the condition of 14-3-3 proteins binding as well. This interaction provides the protection of PtdIns4KIIIβ against dephosphorylation and this way it guarantees continual synthesis of phosphatidylinositol 4-phosphate, a major signalization molecule and the precursor of other phosphate derivatives of phosphatidylinositol. (In Czech)
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Mass Spectrometry-Based Identification of a Potential Binding Partner of Glutamate Carboxypetidase II
Tužil, Jan ; Konvalinka, Jan (advisor) ; Novák, Petr (referee)
English Abstract The incoming paradigm of the network (or systems) biology calls for a new high throughput tool for a wide scale study of protein-protein interactions. Mass spectrometry-based proteomics have experienced a great progress in recent years and have become an indispensable technology of elementary as well as clinical research. Glutamate carboxypeptidase II (GCPII; EC 3.5.17.21) is a transmembrane protein with two known enzymatic activities. Its expression is highly upregulated in some solid tumors and also in tumor-associated neovasculature in general. Nevertheless, none of the two enzymatic activities were shown to be physiologically relevant to these cells. Some facts point at a possible receptor function of GCPII, however, no specific binding partner has been found yet. In the search for potential binding partners and/or ligands of GCPII, a series of methods have been employed, including pull-down experiment, immunoprecipitation and mass spectrometry. Sample preparation and mass spectrometry data processing methodology was specifically developed in order to identify potential binding partners. As one of the outcome of that methodology, the interaction of β-subunit of F1 ATP synthase was selected for further detailed analysis as a putative ligand of GCPII.
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