Anticipating on-target resistance to WRN inhibitors in microsatellite unstable cancers

Abstract Leveraging WRN helicase dependency in microsatellite instability (MSI) cancers offers a synthetic lethal (SL) therapeutic opportunity, with several WRN inhibitors in development. However, the hypermutator nature of MSI tumors creates strong evolutionary pressure for rapid resistance. Here, we apply a multimodal functional genomics framework integrating base editing screens and deep mutational scanning to map on-target resistance to two clinical WRN inhibitors, HRO761 and VVD-214. We identify discrete resistance hotspots within WRN and demonstrate that single-allele (heterozygous) mutations at the drug-binding site are sufficient to abrogate WRN inhibitor–induced cytotoxicity. Resistance profiles diverged between HRO761 and VVD-214, revealing mutations that impair one but preserve sensitivity to the other. Genome-wide CRISPR screens further identified non-homologous end joining (NHEJ) factors and the checkpoint phosphatase WIP1 as tractable synthetic vulnerabilities that potentiate WRN inhibition. Together, these findings establish a framework for resistance-aware deployment of WRN inhibitors through rational drug selection, therapeutic switching, and combination strategies. Statement of Significance Resistance to WRN inhibitors threatens the clinical durability of synthetic lethal therapies in microsatellite-instable cancers. Using multimodal functional genomics, we identify predictable, drug-specific on-target resistance mechanisms and reveal DNA-PK as a tractable combination partner. These findings provide a framework for resistance-aware deployment of WRN inhibitors to improve therapeutic durability.