Abstract While there has been tremendous progress developing small molecule covalent K-Ras G12C inhibitors that bind Ras-off (GDP) and inhibit nucleotide exchange, there remains a need for additional K-Ras inhibitors with different Ras isoform/mutant selectivity profiles and Ras-on (GTP) mechanisms of inhibition. Of particular interest are compounds with a pan-K-Ras profile that inhibit multiple oncogenic mutants and wild type K-Ras, but achieve a therapeutic window by sparing H and N-Ras. In addition, addressing cancers driven by K-Ras oncogenic mutants beyond G12C, K-Ras amplification, or upstream dysregulation where K-Ras is maintained in the GTP-bound state will require “Ras-on” compounds that prevent effector binding. We were interested in the potential of peptide macrocycles that bind the Switch II pocket of K-Ras, in a different conformation than the small molecules, to inhibit Ras-on by allosterically blocking Raf and other effector binding. KRpep-2d is a 19-residue disulfide bridged peptide macrocycle discovered by phage display against K-Ras G12D bound to GDP. Due to its high molecular weight (2561 Da), polarity and metabolic instability, KRpep2d is inactive in in vitro cell assays. And while biochemical experiments have shown that it binds the Ras-off GDP-bound conformation of K-Ras with high affinity to inhibit nucleotide exchange, it has low affinity for K-Ras GTP and does not allosterically inhibit Raf binding. Using parallel macrocyclic peptide chemistry, we made 180 analogs of KRpep-2d to explore truncation of the exocyclic residues and replacement of the labile disulfide bond. UNP-6752, the best compound from this exploratory library, had K-Ras affinities similar to KRpep2d with a 50-fold K-Ras GDP/GTP preference, but was only 11 residues and cyclized with a non-reducible linker. Critically this compound lacked the eight arginine residues of KrPep-2d, which both preclude passive-cell permeability and induce mast cell degranulation. A second iteration of 350 compounds designed to explore single or multiple amino acid substitutions in the core of UNP-6752 led to compound UNP-7572 with sub-micromolar affinity for K-Ras GTP and an IC50 in a K-Ras-Raf TR-FRET assay of ~800 nM. Working from the UNP-7572 we are tuning selectivity for K-Ras and our progress further improving allosteric Ras-Raf inhibition, cell permeability and activity will be presented. Citation Format: Kristopher Josephson, Anthony Silvestri, Jennifer L. Fribourgh, Walter M. Bray, Brian David, Cameron C. Hanna, Sai Kumar Chakka, Alex Hyatt, Monique Porcella, Dio Dieppa-Matos, Cameron R. Pye, Joshua Schwochert. The development of macrocyclic peptide Ras inhibitors [abstract]. In: Proceedings of the AACR Special Conference: Targeting RAS; 2023 Mar 5-8; Philadelphia, PA. Philadelphia (PA): AACR; Mol Cancer Res 2023;21(5_Suppl):Abstract nr B018.
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