Herein, we report arylazopyrazole ureas and sulfones as a novel class of photoswitchable serine hydrolase inhibitors and present a chemoproteomic platform for rapid discovery of optically controlled serine hydrolase targets in complex proteomes. Specifically, we identify highly potent and selective photoswitchable inhibitors of the drug‐metabolizing enzymes carboxylesterases 1 and 2 and demonstrate their pharmacological application by optically controlling the metabolism of the immunosuppressant drug mycophenolate mofetil. Collectively, this proof‐of‐concept study provides a first example of photopharmacological tools to optically control drug metabolism by modulating the activity of a metabolizing enzyme. Our arylazopyrazole ureas and sulfones offer synthetically accessible scaffolds that can be expanded to identify specific photoswitchable inhibitors for other serine hydrolases, including lipases, peptidases, and proteases. Our chemoproteomic platform can be applied to other photoswitches and scaffolds to achieve optical control over diverse protein classes.
Serine hydrolases (SHs) comprise a large superfamily of enzymes that play critical roles in many biological processes. Despite their importance, many SHs remain uncharacterized and the vast majority of SHs lack selective inhibitors. In response, activity-based protein profiling (ABPP) and activity-based probes (ABPs) have been leveraged to construct a more comprehensive picture of the SH proteome. Since the utility of ABPP is largely dictated by the reactivity profile of the ABPs deployed, novel scaffolds and chemotypes are needed to expand the breadth and selectivity of SH-targeting ABPs. In this review, we highlight recent innovations in SH probe development, covering both established and emerging electrophilic warheads. We then discuss how strategic implementation of SH-targeting ABPs has yielded selective, potent inhibitors and imaging agents with broad use. Finally, we present methods for ABP diversification and explore cutting-edge applications in therapeutics development and discovery biology.
Herein, we report arylazopyrazole ureas and sulfones as a novel class of photoswitchable serine hydrolase inhibitors and present a chemoproteomic platform for rapid discovery of optically controlled serine hydrolase targets in complex proteomes. Specifically, we identify highly potent and selective photoswitchable inhibitors of the drug‐metabolizing enzymes carboxylesterases 1 and 2 and demonstrate their pharmacological application by optically controlling the metabolism of the immunosuppressant drug mycophenolate mofetil. Collectively, this proof‐of‐concept study provides a first example of photopharmacological tools to optically control drug metabolism by modulating the activity of a metabolizing enzyme. Our arylazopyrazole ureas and sulfones offer synthetically accessible scaffolds that can be expanded to identify specific photoswitchable inhibitors for other serine hydrolases, including lipases, peptidases, and proteases. Our chemoproteomic platform can be applied to other photoswitches and scaffolds to achieve optical control over diverse protein classes.
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