The research described in this thesis aims at the development of ubiquitin-based research tools to study the enzymes of the ubiquitination pathway, the ligase enzymes and the deubiquitinating... Show moreThe research described in this thesis aims at the development of ubiquitin-based research tools to study the enzymes of the ubiquitination pathway, the ligase enzymes and the deubiquitinating enzymes. These enzymes are responsible for the conjugation and the removal of the post-translational modifier ubiquitin. This small protein is involved in almost all cellular processes, and when conjugated onto a substrate protein it can signal for degradation and influence the localization, interaction, stability and activity of the protein. Therefore, the dysregulation of these processes can have detrimental effects of cell organization and survival which in turn has implications in numerous processes related to diseases. Hence, it is important to fully understand the ubiquitination pathway and how to interact with it. The ubiquitin-based research tools described in this thesis aim to shine light on parts of this pathway. Ranging from the selectivity and specificity of DUBs for specific Ub linkages in competition and the catalytic efficiency of these proteolytic cleavage processes to the selectivity and activity of ligases and the activity of DUBs in cells. All ubiquitin research tools are based on synthetic ubiquitin modified with unnatural amino acids, neutron-encoded amino acids, point mutations and/or fluorescent labels, in order to study the characteristics of the enzymes in vitro. Show less
Deubiquitinating enzymes are key regulators in the ubiquitin system and an emerging class of drug targets. These proteases disassemble polyubiquitin chains and many deubiquitinases show... Show moreDeubiquitinating enzymes are key regulators in the ubiquitin system and an emerging class of drug targets. These proteases disassemble polyubiquitin chains and many deubiquitinases show selectivity for specific polyubiquitin linkages. However, most biochemical insights originate from studies of single diubiquitin linkages in isolation, whereas in cells all linkages coexist. To better mimick this diubiquitin substrate competition, we develop a multiplexed mass spectrometry-based deubiquitinase assay that can probe all ubiquitin linkage types simultaneously to quantify deubiquitinase activity in the presence of all potential diubiquitin substrates. For this, all eight native diubiquitins are generated and each linkage type is designed with a distinct molecular weight by incorporating neutron-encoded amino acids. Overall, 22 deubiquitinases are profiled, providing a three-dimensional overview of deubiquitinase linkage selectivity over time and enzyme concentration. Show less