New Insights into the Role of Membrane Interactions and Conformational Dynamics in Intramembrane Proteolysis by GlpG Rhomboid
The rhomboid family of intramembrane serine proteases can catalyze proteolysis of substrates that are normally embedded in the cell membrane, making them key players in a diverse range of biological processes. While X-ray crystal structures provide detailed insights into the mechanism of intramembra...
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Format: | Others |
Language: | en |
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Université d'Ottawa / University of Ottawa
2017
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Online Access: | http://hdl.handle.net/10393/36941 http://dx.doi.org/10.20381/ruor-21213 |
Summary: | The rhomboid family of intramembrane serine proteases can catalyze proteolysis of substrates that are normally embedded in the cell membrane, making them key players in a diverse range of biological processes. While X-ray crystal structures provide detailed insights into the mechanism of intramembrane hydrolysis, questions remain concerning how transmembrane (TM) substrates are able to gain access to the rhomboid active site, and whether interactions with the membrane environment can influence its structure and function. In this thesis, these questions were investigated using the E. coli rhomboid ecGlpG. In Chapter 3, the effect of hydrophobic mismatch between lipid and protein was investigated using families of amphiphiles with saturated alkyl chains. While ecGlpG displayed maximal activity against a water-soluble model substrate when solubilized in detergents containing 10-12 carbon atoms, shorter and longer chain detergents led to loss of activity. An even larger effect was observed when ecGlpG was reconstituted into phospholipid bicelles, with no proteolytic activity being detected in 14-carbon lipids. These results suggest that mismatch between the hydrophobic regions of the catalytic TM domain (TMD) and the local membrane environment is detrimental to proteolysis. To obtain further insight into the structure and dynamics of ecGlpG, sample conditions were identified in Chapter 4 that enabled, for the first time, the acquisition of NMR spectra showing signals from the ecGlpG TMD. While significant peak broadening prevented chemical shift assignment, the sensitivity and resolution of peaks corresponding to the tryptophan indole NH group allowed their use as structural probes. These were employed in Chapter 5 to characterize the open conformation of ecGlpG that is postulated to facilitate substrate entry. These spectra showed evidence of an open conformation in which the intact α5 is laterally displaced. Interactions with a substrate-derived peptide also appeared to stimulate gate opening; however, activity assays suggested that formation of the open state could compromise catalytic activity against water-soluble substrates, and that interactions with TM substrates could counter this effect. Taken together, these results provide new insight into the role of both the local membrane environment and α5-conformational dynamics on intramembrane proteolysis, and suggest a mechanism to prevent cleavage of off-target rhomboid substrates in vivo. |
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