Abstract
Resistance to first-line chemotherapies and crizotinib in anaplastic large cell lymphoma (ALCL) represents a significant challenge, often leading to a dismal outcome. Despite recent advancements, the dissection of the intrinsic and extrinsic molecular alterations underlying crizotinib resistance in ALCL is still poorly understood. Here, we transcriptionally unraveled the bidirectional interplay between anaplastic lymphoma kinase (ALK)-driven ALCL (ALK+ ALCL) and stromal cells in the presence of crizotinib at bulk and single-cell levels and identified that the microenvironment provides prosurvival signals leading to crizotinib persistence in ALK+ ALCL. We detected increased B-cell lymphoma 2 (BCL2) expression and downregulation of pathways related to apoptosis in crizotinib-persister ALK+ ALCL cells. Furthermore, we predicted in silico the ligand-receptor interactions between tumoral and stromal cells, supporting their contribution to ALCL pathogenesis mainly participating in the adhesion/membrane transport, triggering receptors, and promoting activation and microenvironment stimulation in lymphoma cells. Finally, we explored the effect of crizotinib in combination with BH3 mimetics. Pharmacologic and genetic ablation of anti-apoptotic targets displayed a significant synergistic effect with crizotinib, overcoming the stroma-mediated protection of lymphoma cells on drug treatment. Thus, BCL2/B-cell lymphoma-extra large (BCL-XL) targeting is synthetic lethal with crizotinib exposure in ALK+ ALCL and represents an intrinsic- and extrinsic-mediated targetable vulnerability in lymphoma cells challenged with crizotinib. Our data support the evaluation of BCL2 targeting in crizotinib-based regimens in the management of patients with ALK+ ALCL.