Structure-Based Design of PROTACS for the Degradation of Soluble Epoxide Hydrolase
Julia Schönfeld, Steffen Brunst, Ludmila Ciomirtan, L. Willmer, Michel André Chromik, Adarsh Kumar, Timo Froemel, Nick Liebisch, Arne Hackspacher, Johanna H. M. Ehrler, Lukas Wintermeier, Christina Hesse, Jan Fiedler, Jan Heering, Hinrich Freitag, Patrick Zardo, Hans‐Gerd Fieguth, Astrid Brüggerhoff, Josefine Jakob, Björn Häupl, Lilia Weizel, Astrid Kaiser, Manfred Schubert‐Zsilavecz, Thomas Oellerich, Ingrid Fleming, Nils Helge Schebb, Robert Fürst, Aimo Kannt, Stefan Knapp, Ewgenij Proschak, Kerstin Hiesinger
Abstract
High Resolution Image Download MS PowerPoint Slide The bifunctional soluble epoxide hydrolase (sEH) represents a promising target for inflammation-related diseases. Although potent inhibitors targeting each domain are available, sEH-PROTACs offer the unique ability to simultaneously block both enzymatic functions, mimicking the sEH knockout phenotype, which has been associated with reducing inflammation, including neuroinflammation, and delaying the progression of Alzheimer’s disease. Herein, we report the structure-based development of a potent sEH-PROTAC as a useful pharmacological tool. In order to facilitate a rapid testing of the PROTACs, a cell-based sEH degradation assay was developed utilizing HiBiT technology. We designed and synthesized 24 PROTACs. Furthermore, cocrystallization of sEH with two selected PROTACs allowed us to explore the binding mode and rationalize the most optimal linker length. After comprehensive biological and physicochemical characterization of this series, the most optimal PROTAC 23 was identified in primary human and murine cells, highlighting the potential of using 23 in disease-relevant cell and tissue models.