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Substrate specificity, mechanism and activity regulation of the rhomboid family intramembrane proteases
Škerle, Jan
Intramembrane proteases from the rhomboid-like superfamily are enzymes widely distributed and conserved in all domains of life. They participate in many important processes such as membrane protein quality control or mitochondrial dynamics. Their activity is also linked with diseases like Parkinson's disease or cancer. This makes them potential therapeutic targets. In this work we tried to elucidate in more detail the mechanism of action of the main model intramembrane protease, GlpG from E. coli. We also focused on the mechanism of eukaryotic rhomboid RHBDL2, one of the four mammalian rhomboids, function of which is poorly understood. To acquire more detailed information about substrate-enzyme interaction, we synthesized a series of novel peptidyl-chloromethylketone inhibitors derived from natural rhomboid substrate TatA from P. stuartii. Crystal structure of the complex of GlpG with these inhibitors revealed four substrate binding subsites (S1 to S4) of the enzyme and explained its observed substrate specificity structurally. This study showed that substrate cleavage rate can be dramatically modified by changing the substrate sequence in positions P1 to P5. This helped us develop fluorogenic transmembrane peptide substrates for rhomboid proteases, which are usable in detergent and liposomes, and...
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Substrate specificity, mechanism and activity regulation of the rhomboid family intramembrane proteases
Škerle, Jan ; Stříšovský, Kvido (advisor) ; Hof, Martin (referee) ; Heidingsfeld, Olga (referee)
Intramembrane proteases from the rhomboid-like superfamily are enzymes widely distributed and conserved in all domains of life. They participate in many important processes such as membrane protein quality control or mitochondrial dynamics. Their activity is also linked with diseases like Parkinson's disease or cancer. This makes them potential therapeutic targets. In this work we tried to elucidate in more detail the mechanism of action of the main model intramembrane protease, GlpG from E. coli. We also focused on the mechanism of eukaryotic rhomboid RHBDL2, one of the four mammalian rhomboids, function of which is poorly understood. To acquire more detailed information about substrate-enzyme interaction, we synthesized a series of novel peptidyl-chloromethylketone inhibitors derived from natural rhomboid substrate TatA from P. stuartii. Crystal structure of the complex of GlpG with these inhibitors revealed four substrate binding subsites (S1 to S4) of the enzyme and explained its observed substrate specificity structurally. This study showed that substrate cleavage rate can be dramatically modified by changing the substrate sequence in positions P1 to P5. This helped us develop fluorogenic transmembrane peptide substrates for rhomboid proteases, which are usable in detergent and liposomes, and...
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Significance of the S1 subsite of rhomboid intramembrane proteases for catalysis and inhibitor design
Kučerová, Jolana ; Stříšovský, Kvido (advisor) ; Hodek, Petr (referee)
This thesis focuses on the development of specific inhibitors of rhomboid intramembrane proteases. These inhibitors are needed for the cell-biological investigation of rhomboid proteases and their potential pharmacological targeting, as rhomboid proteases have been associated with various diseases, such as malaria, Parkinson's disease, cancer or toxoplasmosis. The thesis advisor's laboratory has recently discovered the first such group of compounds, the peptidyl ketoamides. To exploit them fully, it is necessary to examine their properties and the possibilities of their modifications. In this work, synthetic fluorogenic substrates and enzyme kinetics were used to examine the possibilities of exploiting the S1 subsite in the rhomboid active site for rhomboid inhibitor design. Furthermore, using variants of these substrates modified by unnatural amino acids in the P1 position, the mechanism of water transfer to the rhomboid active site was investigated. Comparison of cleavage rates of ten fluorogenic substrates modified in the P1 position revealed that the E. coli rhomboid protease GlpG strongly prefers side chains -CH2-CH3 and -CH3 in the P1 position (i.e. binding into the S1 subsite). This trend was apparent also with peptidyl ketoamide inhibitors. The present substrate and inhibitor study suggests...
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Analysis of substrate specificity and mechanism of GlpG, an intramembrane protease of the rhomboid family.
Peclinovská, Lucie ; Stříšovský, Kvido (advisor) ; Konvalinka, Jan (referee)
Membrane proteins of the rhomboid-family are evolutionarily widely conserved and include rhomboid intramembrane serine proteases and rhomboid-like proteins. The latter have lost their catalytic activity in evolution but retained the ability to bind transmembrane helices. Rhomboid-family proteins play important roles in intercellular signalling, membrane protein quality control and trafficking, mitochondrial dynamics, parasite invasion and wound healing. Their medical potential is steeply increasing, but in contrast to that, their mechanistic and structural understanding lags behind. Rhomboid protease GlpG from E.coli has become the main model rhomboid-family protein and the main model intramembrane protease - it was the first one whose X-ray structure was solved. GlpG cleaves single-pass transmembrane proteins in their transmembrane helix, but how substrates bind to GlpG and how is substrate specificity achieved is still poorly understood. This thesis investigates the importance of the transmembrane helix of the substrate in its recognition by GlpG using mainly enzyme kinetics and site-directed mutagenesis. We find that the transmembrane helix of the substrate contributes significantly to the binding affinity to the enzyme, hence to cleavage efficiency, but it also plays a role in cleavage site...
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