Abstract
Infants and children with KMT2A::AFF1+ leukemia have a dismal prognosis and are therefore in urgent need for more efficient and less aggressive therapy. In this study, we investigated three microRNAs that are downregulated in KMT2A::AFF1+ B-cell precursor acute lymphoblastic leukemia (BCP-ALL): miR-194, miR-99b, and miR-125a-5p. When overexpressed, all three microRNAs impaired the survival of KMT2A::AFF1+ leukemic blasts and the maintenance of KMT2A::AFF1+ BCP-ALL. We identified microRNA target genes responsible for this phenotype that are upregulated in KMT2A::AFF1+ BCP-ALL: CA5B, PPP3CA, and PPP2R5C. Importantly, using a drug-repurposing approach, we found that inhibition of CA5B, PPP3CA, and PP2A by acetazolamide, tacrolimus, and LB-100, respectively, showed high toxicity toward KMT2A::AFF1+ leukemic blasts and reduced leukemia burden in vivo. Furthermore, acetazolamide was able to prolong the survival of patient-derived xenotransplant models in combination with infant ALL induction therapy. This study highlights how the unique microRNA expression signature of patients with KMT2A::AFF1+ BCP-ALL can be used to uncover novel therapeutic avenues and accelerate drug repurposing. It also indicates potential new drug combinations for less toxic chemotherapy.