Abstract
Targeted protein degradation, particularly through molecular glue degraders (MGDs), offers a promising strategy for targeting "undruggable" proteins. However, existing fluorescence-based screening approaches, such as time-resolved fluorescence resonance energy transfer, may be constrained by conformational changes or inefficient labeling of targets, necessitating more efficient screening approaches. Here, we present a MGDs screening approach based on surface plasmon resonance (SPR) coupled with degradomics and interactomics (SPR-DI). This approach leverages the high-throughput and label-free SPR for screening E3 ligands, followed by an unbiased "dual filter" of degradomics and interactomics to identify candidate proteins of interests (POIs). The feasibility of SPR-DI was validated using previously established MGD VH032, which can drive VHL to induce CDO1 degradation. Employing VHL and Keap1 as drivers E3, we then screened a natural product library and successfully identified triptolide and pycropodophyllin as potential MGDs. Subsequent investigations demonstrated that triptolide facilitates VHL-mediated degradation of IMP3, whereas picropodophyllin promotes Keap1-mediated degradation of DDX52 and LDHB. These degradation events were confirmed to depend on the respective E3 and ubiquitin-proteasome system, underscoring the capacity of these compounds to induce ternary complex formation. In conclusion, the establishment of SPR-DI provides a promising tool for the discovery of MGDs and their corresponding POIs, offering instructive insights to advance future MGD screening methodologies.