Maskos, J. N.; Stark, Y.; Rohner, V. L.; Haefliger, A.; Winkelvoss, D.; Kopra, K.; Mittl, P. R. E.; Plueckthun, A.

Mutant KRAS is a potent oncogene, serving as a tumor driver in many solid human cancers. Current small-molecule inhibitors target the highly conserved G-domain, but to gain further mechanistic insight into the roles of different isoforms, we investigated the strategy of sterically shielding the unstructured hypervariable regions (HVRs). KRAS HVRs undergo a series of post-translational modifications that enable intracellular trafficking and membrane attachment. Previous attempts to drug KRAS by preventing its post-translational modification, based on inhibition of the involved prenylation enzymes have been largely unsuccessful. In this study, we explored the property of Designed Armadillo Repeat Proteins (dArmRPs) to specifically bind unstructured regions. We assembled a dArmRP to recognize the unstructured KRAS4B-HVR and developed it into a high-affinity binder by directed evolution. The resulting dArmRP recognizes the 14 C-terminal residues of unprocessed KRAS4B, thereby blocking the farnesyltransferase-binding epitope. This steric shielding disrupts KRAS4B post-translational modification and thereby significantly reduces its plasma membrane localization, while demonstrating complete selectivity over KRAS4A, NRAS, and HRAS. This work establishes the shielding of intrinsically disordered regions as a precise biochemical strategy to control protein function and provides an isoform-specific tool to dissect KRAS biology.