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Exquisitely Specific anti-KRAS Biodegraders Inform on the Cellular Prevalence of Nucleotide-Loaded States

Shuhui Lim, Regina Khoo, Yu‐Chi Juang, Pooja Gopal, Huibin Zhang, Constance Yeo, Khong Ming Peh, Jinkai Teo, Simon Ng, Brian Henry, Anthony W. Partridge

2020ACS Central Science86 citationsDOIOpen Access PDF

Abstract

mutants. Targeted degradation has emerged as an attractive alternative approach, but for KRAS, identification of the required high-affinity ligands continues to be a challenge. Another significant hurdle is the discovery of a hybrid molecule that appends an E3 ligase-recruiting moiety in a manner that satisfies the precise geometries required for productive polyubiquitin transfer while maintaining favorable druglike properties. To gain insights into the advantages and feasibility of KRAS targeted degradation, we applied a protein-based degrader (biodegrader) approach. This workflow centers on the intracellular expression of a chimeric protein consisting of a high-affinity target-binding domain fused to an engineered E3 ligase adapter. A series of anti-RAS biodegraders spanning different RAS isoform/nucleotide-state specificities and leveraging different E3 ligases provided definitive evidence for RAS degradability. Further, these established that the functional consequences of KRAS degradation are context dependent. Of broader significance, using the exquisite degradation specificity that biodegraders can possess, we demonstrated how this technology can be applied to answer questions that other approaches cannot. Specifically, application of the GDP-state specific degrader uncovered the relative prevalence of the "off-state" of WT and various KRAS mutants in the cellular context. Finally, if delivery challenges can be addressed, anti-RAS biodegraders will be exciting candidates for clinical development.

Topics & Concepts

KRASUbiquitin ligaseContext (archaeology)Computational biologyMutantBiologySmall moleculeGene isoformCancer researchUbiquitinChemistryMutationCell biologyGeneticsGenePaleontologyProtein Degradation and InhibitorsUbiquitin and proteasome pathwaysPeptidase Inhibition and Analysis