Abstract SF3B1 mutations, the most frequent spliceosomal alterations across cancers, occur in 25% of myelodysplastic syndromes (MDS) patients yet lack effective therapies. Two phase 2 clinical trials with the XPO1 inhibitors in high-risk MDS revealed increased activity in patients with SF3B1 mutations. XPO1 (Exportin-1) plays a role in the transport of multiple RNA species, including small nuclear RNAs (snRNAs) out of the nucleus. Given the role of XPO1 in exporting snRNAs, which form the catalytic portion of the spliceosome, we hypothesized that XPO1 inhibition may preferentially affect SF3B1-mutant cells and that SF3B1-mutant high-risk MDS patients would have a better response to rational targeted drug combinations with XPO1 inhibitors. To evaluate the mechanism underlying the preferential sensitivity of SF3B1-mutant cells to XPO1 inhibition, we conducted subcellular RNA sequencing before and after XPO1 inhibition in SF3B1 wildtype and mutant cells. Transcriptomic analysis revealed increased global retention of RNA transcripts and elevated snRNAs in the nucleus after XPO1 inhibition in the SF3B1 mutant cell line. Global RNA expression and splicing analysis revealed increased alternative splicing in SF3B1 mutant cells after XPO1 inhibition. These results suggest that the preferential sensitivity of SF3B1 mutant cells to nuclear export inhibition arises through increased nuclear retention of spliceosomal snRNAs and select mRNAs that results in perturbation of apoptotic pathways. Despite the promising efficacy of XPO1 inhibition in SF3B1-mutated MDS, dose escalation is limited by toxicity. In order to identify novel drug combination targets with lower XPO1 inhibitor doses, we employed whole genome CRISPR screens in two acute myeloid leukemia (AML) cell lines treated with XPO1 inhibitor. We identified two drug targets that greatly synergized with eltanexor specifically in the SF3B1 mutant cell lines: venetoclax (a BCL2 inhibitor), and A1331852 (a BCL-XL inhibitor). In addition, BH3 profiling demonstrated increased priming of the BCL2 and BCL-XL in SF3B1 mutant cells. We further validated these combinations in vivo using competitive transplant assays in Sf3b1 K700E conditional knock-in mice. The combination of eltanexor with venetoclax and eltanexor with A1331852 showed a significant decrease in the Sf3b1-mutant burden in the peripheral blood and bone marrow progenitor compartments, suggesting a preferential sensitivity of the combinations for SF3B1 mutant cells. Although A1331852 exhibited similar results to venetoclax, there was increased weight loss and decrease in hemoglobin associated with BCLXL inhibition. In conclusion, our study provides insight on the mechanisms underlying the heightened sensitivity of XPO1 inhibition in SF3B1-mutant MDS/AML. The identification of BCL2 and BCL-XL as synergistic targets with XPO1 inhibitors, validated by in vivo testing, BH3 profiling, and RNA sequencing, highlights the potential for therapeutic combinations. Specifically, the combination of eltanexor and venetoclax could be a promising SF3B1-specific therapy. Citation Format: Sana Chaudhry, Felipe Beckedorff, Shaista Shabbir Jasdanwala, Tulasigeri M Totiger, Maurizio Affer, Nidhi Hariramani, Olivia Tonini, Stephan Noudali, Alexandra Chirino, Alyssa Cornista, Skye Montoya, Daniel Bilbao, Jumana Afaghani, Jose Antonio Rodríguez, Shruti Bhatt, Eric Wang, Justin Taylor. Altered RNA Export Sensitizes to Nuclear Export Inhibition in SF3B1 Mutant MDS [abstract]. In: Proceedings of the Blood Cancer Discovery Symposium; 2024 Mar 4-6; Boston, MA. Philadelphia (PA): AACR; Blood Cancer Discov 2024;5(2_Suppl):Abstract nr P26.
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