Small-molecule Inhibition of MAP2K4 is Synergistic with RAS Inhibitors in -mutant Cancers

Overview

Journal Proc Natl Acad Sci U S A

Specialty Science

Date 2024 Feb 20

PMID 38377196

Authors

Robin A Jansen

Sara Mainardi

Matheus Henrique Dias

Astrid Bosma

Emma van Dijk

Roland Selig

Wolfgang Albrecht

Stefan A Laufer

Lars Zender

Rene Bernards

Affiliations

Soon will be listed here.

Abstract

The Kirsten rat sarcoma viral oncogene homologue is among the most commonly mutated oncogenes in human cancers, thus representing an attractive target for precision oncology. The approval for clinical use of the first selective inhibitors of G12C mutant KRAS therefore holds great promise for cancer treatment. However, despite initial encouraging clinical results, the overall survival benefit that patients experience following treatment with these inhibitors has been disappointing to date, pointing toward the need to develop more powerful combination therapies. Here, we show that responsiveness to KRAS and pan-RAS inhibitors in -mutant lung and colon cancer cells is limited by feedback activation of the parallel MAP2K4-JNK-JUN pathway. Activation of this pathway leads to elevated expression of receptor tyrosine kinases that reactivate KRAS and its downstream effectors in the presence of drug. We find that the combination of sotorasib, a drug targeting KRAS, and the MAP2K4 inhibitor HRX-0233 prevents this feedback activation and is highly synergistic in a panel of -mutant lung and colon cancer cells. Moreover, combining HRX-0233 and sotorasib is well-tolerated and resulted in durable tumor shrinkage in mouse xenografts of human lung cancer cells, suggesting a therapeutic strategy for KRAS-driven cancers.

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