Preclinical data and early clinical findings suggest menin inhibitors could be effective against rare NUP98-rearranged leukemias. This is based on similarities in downstream pathways to the approved KMT2A and NPM1 mutations, hinting at a broader mechanism of action for this drug class.
A major limitation of menin inhibitor monotherapy is acquired resistance. Up to 39% of patients on revumenib develop mutations in the menin (MEN1) gene. These mutations prevent the drug from binding to its target, leading to rapid relapse and highlighting the need for combination therapies or next-generation agents.
The new menin inhibitor, enzomenib, demonstrates potentially superior response rates (CR/CRH of 40-60%) compared to existing agents (~23%). Crucially, early data shows no QTc prolongation, a significant dose-limiting toxicity for current menin inhibitors, suggesting a major safety improvement for this drug class.
A high-sensitivity NGS assay for cell-free DNA (cfDNA) can detect emerging resistance mutations in the MEN1 gene. This allows for early identification of treatment failure, potentially months before a patient shows clinical signs of relapse, opening a window for proactive therapeutic adjustments like switching inhibitors.