U2af1 is a haplo-essential gene required for hematopoietic cancer cell survival in mice
Brian A. Wadugu, Sridhar Nonavinkere Srivatsan, Amanda Heard, Michael O. Alberti, Matthew Ndonwi, Jie Liu, Sarah Grieb, Joseph Bradley, Jin Shao, Tanzir Ahmed, Cara L. Shirai, Ajay Khanna, Dennis L. Fei, Christopher A. Miller, Timothy A. Graubert, Matthew J. Walter
Brian A. Wadugu, Sridhar Nonavinkere Srivatsan, Amanda Heard, Michael O. Alberti, Matthew Ndonwi, Jie Liu, Sarah Grieb, Joseph Bradley, Jin Shao, Tanzir Ahmed, Cara L. Shirai, Ajay Khanna, Dennis L. Fei, Christopher A. Miller, Timothy A. Graubert, Matthew J. Walter
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Research Article Hematology Oncology

U2af1 is a haplo-essential gene required for hematopoietic cancer cell survival in mice

Abstract

Somatic mutations in the spliceosome gene U2AF1 are common in patients with myelodysplastic syndromes. U2AF1 mutations that code for the most common amino acid substitutions are always heterozygous, and the retained WT allele is expressed, suggesting that mutant hematopoietic cells may require the residual WT allele to be viable. We show that hematopoiesis and RNA splicing in U2af1 heterozygous knockout mice were similar to those in control mice, but that deletion of the WT allele in U2AF1(S34F) heterozygous mutant–expressing hematopoietic cells (i.e., hemizygous mutant) was lethal. These results confirm that U2AF1 mutant hematopoietic cells are dependent on the expression of WT U2AF1 for survival in vivo and that U2AF1 is a haplo-essential cancer gene. Mutant U2AF1(S34F)-expressing cells were also more sensitive to reduced expression of WT U2AF1 than nonmutant cells. Furthermore, mice transplanted with leukemia cells expressing mutant U2AF1 had significantly reduced tumor burden and improved survival after the WT U2af1 allele was deleted compared with when it was not deleted. These results suggest that selectively targeting the WT U2AF1 allele in heterozygous mutant cells could induce cancer cell death and be a therapeutic strategy for patients harboring U2AF1 mutations.

Authors

Brian A. Wadugu, Sridhar Nonavinkere Srivatsan, Amanda Heard, Michael O. Alberti, Matthew Ndonwi, Jie Liu, Sarah Grieb, Joseph Bradley, Jin Shao, Tanzir Ahmed, Cara L. Shirai, Ajay Khanna, Dennis L. Fei, Christopher A. Miller, Timothy A. Graubert, Matthew J. Walter

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Figure 5

U2af1 deletion induces alternative splicing, but there is no change or alteration in the sequence specificity at the 3′ splice site.

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U2af1 deletion induces alternative splicing, but there is no change or ...
Differential splicing analysis of RNA-Seq of E14.5 hematopoietic progenitor cells (KL). (A) Distribution of alternative splicing events in Vav1-Cre U2af1fl/fl compared with Vav1-Cre control cells (left), Vav1-Cre U2af1WT/fl compared with Vav1-Cre control cells (center), and Vav1-Cre U2af1WT/S34F compared with Vav1-Cre control cells (right). (B) Venn diagram comparing the skipped exon events (positive and negative) in Vav1-Cre U2af1fl/fl, Vav1-Cre U2af1WT/fl, and Vav1-Cre U2af1WT/S34F. (CE) The consensus sequence around the 3′ AG dinucleotide splice-acceptor site of cassette exons that are unchanged (control), included more (positive), or skipped more (negative) in Vav1-Cre U2af1fl/fl, Vav1-Cre U2af1WT/fl, and Vav1-Cre U2af1WT/S34F compared with Vav1-Cre control (FDR < 0.1, |ΔΨ| > 0.1). n = 1–4 per genotype. A5SS, alternative 5′ splice site; A3SS, alternative 3′ splice site; MXE, mutually exclusive exons; RI, retained intron; negative, decrease in event relative to Vav1-Cre control; positive, increase in event relative to Vav1-Cre control.