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Structure-assisted design of inhibitors targeting medicinally relevant enzymes
Djukic, Stefan ; Maloy Řezáčová, Pavlína (advisor) ; Kutá-Smatanová, Ivana (referee) ; Kolenko, Petr (referee)
Structure-assisted drug discovery is a powerful approach that utilizes detailed knowledge on 3D structure to design and optimize new inhibitors targeting medically relevant enzymes. X-ray crystallography is a widely used structural biology technique since it provides detailed snapshot of protein-inhibitor complex, which is used to analyze protein- inhibitor interactions. PNP plays an important role in salvage pathway of purine metabolism, it is a target in treatment of T-cell malignancies and/or parasitic infections. Our effort focused on human and M. tuberculosis PNP, and our aim was to develop new inhibitors with high selectivity and specificity. Our inhibitors are acyclic nucleoside phosphates with 9- deazahypoxanthine nucleobase that contain three moieties binding to all three regions of the active site: purine, phenyl and phosphonate moieties. The best inhibitors have IC50 values as low as 19 nM (human) and 4 nM (M. tuberculosis). The presence of short substituents at central phenyl moiety, such as methoxy and bromide group, decreases inhibitor's affinity towards human PNP, but does not affect affinity towards mycobacterial PNP. At the same time, bulky substituents, such as fluorinated phenyl ring, decrease inhibitor's affinity towards human PNP but increase affinity towards mycobacterial...
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Inhibitors of rhomboid proteases as tools for cell biology
Kuzmík, Ján ; Stříšovský, Kvido (advisor) ; Hlouchová, Klára (referee)
Rhomboid intramembrane serine proteases cleave polypeptide chains within lipid bilayer. Rhomboid proteases were originally discovered in Drosophila melanogaster where they regulate ontogenesis of the fly, but they are present in all domains of life. Nowadays, various diseases, such as malaria, amoebiasis, Parkinson's disease, various tumour malignancies, and diabetes, have been linked with rhomboid proteases. However, natural substrates and function of most rhomboids remain elusive. Cell biology tools are needed for unravelling functions of rhomboids, as well as for potential pharmacological applications, and this together fuels the effort to develop specific rhomboid inhibitors. The inhibitors known to date always bear an electrophilic warhead attacking the nucleophilic serine of the atypical serine-histidine catalytic dyad of rhomboid. From the various developed inhibitors, peptidyl -ketoamides substituted at the ketoamide nitrogen by hydrophobic groups, discovered in our laboratory, hold the biggest potential. They are potent, reversible, selective, tunable, and are built around a pharmacophore already approved for medical use. Here, I set out to improve peptidyl -ketoamides by exploring the chemical space in the active site of rhomboid and testing substituents of the ketoamide nitrogen of increasing...
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Inhibitors of rhomboid proteases as tools for cell biology
Kuzmík, Ján ; Stříšovský, Kvido (advisor) ; Hlouchová, Klára (referee)
Rhomboid intramembrane serine proteases cleave polypeptide chains within lipid bilayer. Rhomboid proteases were originally discovered in Drosophila melanogaster where they regulate ontogenesis of the fly, but they are present in all domains of life. Nowadays, various diseases, such as malaria, amoebiasis, Parkinson's disease, various tumour malignancies, and diabetes, have been linked with rhomboid proteases. However, natural substrates and function of most rhomboids remain elusive. Cell biology tools are needed for unravelling functions of rhomboids, as well as for potential pharmacological applications, and this together fuels the effort to develop specific rhomboid inhibitors. The inhibitors known to date always bear an electrophilic warhead attacking the nucleophilic serine of the atypical serine-histidine catalytic dyad of rhomboid. From the various developed inhibitors, peptidyl -ketoamides substituted at the ketoamide nitrogen by hydrophobic groups, discovered in our laboratory, hold the biggest potential. They are potent, reversible, selective, tunable, and are built around a pharmacophore already approved for medical use. Here, I set out to improve peptidyl -ketoamides by exploring the chemical space in the active site of rhomboid and testing substituents of the ketoamide nitrogen of increasing...
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