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Grid and Cloud Computing
Began, Jakub ; Dobrovský, Ladislav (referee) ; Šeda, Miloš (advisor)
The bachelor thesis deals with cloud and grid technologies. The first part discusses cloud computing technology, its components, infrastructure, models, advantages, disadvantages, and security risks. The following section describes computing and data grids, their function, use and security. The last part of the thesis shows an overview of the commercial market of cloud and grid services.
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Grid and Cloud Computing
Began, Jakub ; Dobrovský, Ladislav (referee) ; Šeda, Miloš (advisor)
The bachelor thesis deals with cloud and grid technologies. The first part discusses cloud computing technology, its components, infrastructure, models, advantages, disadvantages, and security risks. The following section describes computing and data grids, their function, use and security. The last part of the thesis shows an overview of the commercial market of cloud and grid services.
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Rhomboid family intramembrane proteases in prokaryotes: mechanism, substrate repertoires and biological functions in the Gram-positive bacterium Bacillus subtilis.
Began, Jakub
Rhomboid proteases are a class of serine intramembrane proteases, a large family of enzymes that catalyze the proteolytic cleavage of membrane proteins within their transmembrane regions, in the hydrophobic environment of cellular lipid membranes. Rhomboid proteases were discovered in 2001 in Drosophila. In their pioneering study, Lee et al. identified the essential role of Rhomboid-1 protein (Rhom-1), which proteolytically activates the epidermal growth factor (EGF) receptor signaling pathway, in the early stages of fly eye development. Members of the rhomboid superfamily - active proteases (rhomboids) as well as their catalytically-dead counterparts (rhomboid-like proteins, including iRhoms and Derlins) - are widely conserved, implying their biological significance. Rhomboids are present in all kingdoms of life from archea to humans, while proteolytically inactive rhomboid-like proteins are present in eukaryotes only. Rhomboid superfamily proteins play roles in a wide range of processes, as diverse as signaling in metazoan development, mitochondrial biogenesis in yeast, host- cell invasion by protozoan parasites, protein quality control in the endoplasmic reticulum (ER) or bacterial quorum sensing. Rhomboids are the best understood intramembrane proteases from a structural and mechanistic points...
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Rhomboid family intramembrane proteases in prokaryotes: mechanism, substrate repertoires and biological functions in the Gram-positive bacterium Bacillus subtilis.
Began, Jakub
Rhomboid proteases are a class of serine intramembrane proteases, a large family of enzymes that catalyze the proteolytic cleavage of membrane proteins within their transmembrane regions, in the hydrophobic environment of cellular lipid membranes. Rhomboid proteases were discovered in 2001 in Drosophila. In their pioneering study, Lee et al. identified the essential role of Rhomboid-1 protein (Rhom-1), which proteolytically activates the epidermal growth factor (EGF) receptor signaling pathway, in the early stages of fly eye development. Members of the rhomboid superfamily - active proteases (rhomboids) as well as their catalytically-dead counterparts (rhomboid-like proteins, including iRhoms and Derlins) - are widely conserved, implying their biological significance. Rhomboids are present in all kingdoms of life from archea to humans, while proteolytically inactive rhomboid-like proteins are present in eukaryotes only. Rhomboid superfamily proteins play roles in a wide range of processes, as diverse as signaling in metazoan development, mitochondrial biogenesis in yeast, host- cell invasion by protozoan parasites, protein quality control in the endoplasmic reticulum (ER) or bacterial quorum sensing. Rhomboids are the best understood intramembrane proteases from a structural and mechanistic points...
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Rhomboid family intramembrane proteases in prokaryotes: mechanism, substrate repertoires and biological functions in the Gram-positive bacterium Bacillus subtilis.
Began, Jakub ; Stříšovský, Kvido (advisor) ; Bařinka, Cyril (referee) ; Krásný, Libor (referee)
Rhomboid proteases are a class of serine intramembrane proteases, a large family of enzymes that catalyze the proteolytic cleavage of membrane proteins within their transmembrane regions, in the hydrophobic environment of cellular lipid membranes. Rhomboid proteases were discovered in 2001 in Drosophila. In their pioneering study, Lee et al. identified the essential role of Rhomboid-1 protein (Rhom-1), which proteolytically activates the epidermal growth factor (EGF) receptor signaling pathway, in the early stages of fly eye development. Members of the rhomboid superfamily - active proteases (rhomboids) as well as their catalytically-dead counterparts (rhomboid-like proteins, including iRhoms and Derlins) - are widely conserved, implying their biological significance. Rhomboids are present in all kingdoms of life from archea to humans, while proteolytically inactive rhomboid-like proteins are present in eukaryotes only. Rhomboid superfamily proteins play roles in a wide range of processes, as diverse as signaling in metazoan development, mitochondrial biogenesis in yeast, host- cell invasion by protozoan parasites, protein quality control in the endoplasmic reticulum (ER) or bacterial quorum sensing. Rhomboids are the best understood intramembrane proteases from a structural and mechanistic points...
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Mechanism of action of non-peptide inhibitors of HIV protease
Began, Jakub ; Konvalinka, Jan (advisor) ; Bořek Dohalská, Lucie (referee)
The inhibition of HIV-1 protease plays an important role in combating HIV. Nine HIV-1 protease inhibitors have been succesfully marketed for the treatment since 1995. However, their efficiencies decrease due to the resistance development. More potent compounds with novel structural motifs and mechanisms of action are therefore still needed. Several inhibitory compounds have been reported to bind to the protease at the loci different from the active site. Interestingly, darunavir, which is the last approved inhibitor with supposedly competitive mode of action, was also suggested to bind to the flap region of the protease. Two studies discussed this alternative binding mode based on the X-ray structural and kinetic analysis, respectively. Nevertheless, it is questionable, if such a mechanism is relevant also in physiological conditions or if it is only an artifact of crystallization. Another study provided a strong evidence for the alternative binding of darunavir to highly mutated HIV-1 protease. Based on thermodynamic analysis, it was shown that two molecules of darunavir bind to the protease dimer. Surprisingly, this observation was not confirmed by the X-ray structure analysis since the inhibitor was bound only within the active site. However, this protease variant was employed in further...
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