TP53 mutations drive therapy resistance via post-mitochondrial caspase blockade.

Acute myeloid leukemia (AML) is a heterogeneous disease characterized by a broad spectrum of molecular alterations that influence clinical outcomes. TP53 mutations define one of the most lethal subtypes of acute myeloid leukemia (AML), driving resistance to nearly all available treatment modalities, including venetoclax plus azacitidine (VenAza). Yet, the molecular basis of this resistance, beyond affecting transactivation of BCL-2 family genes, has remained elusive. Here, we demonstrate that VenAza treatment leads to reduced transcriptional upregulation of the p53 signaling pathway in TP53 mutant/deficient AML compared to wild-type AML. Functionally, TP53 mutant/deficient AML exhibits selective failure in apoptosis induction rather than impaired G1 arrest or senescence. Despite inhibition of pro-apoptotic BAX and selective enrichment for MCL-1 in TP53 mutant isogenic AML cells, compensatory upregulation of BIM preserved functional mitochondrial outer membrane permeabilization (MOMP). TP53 mutant primary AML tumors at baseline also had retained capacity for MOMP. Instead, TP53 mutant AML exhibited disruption in caspase-3/7 activation to evade apoptosis after VenAza therapy - decoupling the mitochondrial and executioner phases of apoptosis. Importantly, this "post-MOMP brake" is not a bystander effect but itself a driver of VenAza and chemotherapy resistance in TP53 mutant/deficient AML. This previously unrecognized mechanistic insight shifts the focus from mitochondrial priming to terminal caspase blockade in TP53 mutant AML and opens the door for urgently needed therapeutic strategies that reignite apoptosis at its execution point.