Wildtype NUP98 cooperates with NPM1c to drive oncogenic transcription Free

Nucleophosmin mutations are among the most common aberrations in acute myeloid leukemia (AML). We previously uncovered a novel pivotal role for mutant NPM1 (NPM1c) in the nucleus, where it binds chromatin at key self-renewal gene loci, such as HOXA/B and MEIS1, directly regulating oncogenic transcription. How NPM1c regulates the transcriptional activity of its chromatin targets remains unclear. To identify potential nuclear cooperating partners of NPM1c, we employed TurboID proximity labeling of NPM1c and wild-type NPM1 (NPM1wt). Mass spectrometric analysis revealed an enrichment of nucleoporins in the NPM1c interactome, with Nucleoporin 98 (NUP98) emerging as a top candidate.

NUP98, a key component of the nuclear pore complex (NPC), has been established as a critical oncogenic player in AML as part of oncogenic fusion proteins. In these oncofusions the N-terminal FG (phenylalanine-glycine) repeat domain of NUP98 is preserved and fused to a diverse set of partner genes. NUP98-fusion partners are believed to mediate the chromatin binding specificity of the oncoprotein while the NUP98 FG repeats have been shown to form biomolecular condensates that enhance transcriptional output. Interestingly, wild-type NUP98 (NUP98wt) itself has been linked to gene regulatory functions during embryonic development and normal hematopoiesis. However, the role of NUP98wt in transcriptional regulation in the context of leukemia remains unresolved.

To explore a potential cooperation between NUP98wt and NPM1c we first validated their interaction by co-immunoprecipitation assays. We next wanted to determine whether NUP98 and NPM1c are recruited to the same chromatin sites. To this end, we performed ChIP-seq in an NPM1c endogenous degrader cell line. These experiments revealed co-occupancy of NUP98 at NPM1c target genes and a significant reduction of NUP98 binding upon degradation of NPM1c. These findings suggest that NPM1c is required for the recruitment of NUP98 to key oncogenic target loci.

To dissect the functional role of NUP98wt in NPM1c AML, we performed loss of function studies. CRISPR mediated knock-out of NUP98 in NPM1 mutant (OCI-AML3) cells resulted in a significant repression of NPM1c target genes, including HOXA/B and MEIS1. Given the essential nature of NUP98, we also engineered an endogenous NUP98 degrader system in OCI-AML3 and NPM1wt (MV4-11) cells to allow for the study of the effects of rapid protein depletion. Upon degradation of NUP98, OCI-AML3 cells exhibited robust myeloid differentiation (~70% increase in CD11b) and increased apoptosis (~50% increase in Annexin V⁺). MV411 cells on the other hand did not show the same differentiation phenotype. To characterize the immediate transcriptional consequences of NUP98 depletion, we performed nascent RNAseq after 1 and 3 hours of degradation. In the first hours of degradation we observed a rapid and significant repression of NPM1c target genes such as HOXA/B cluster genes, MEIS1, SMC4, TNRC18, SATB1/2 and UNCX, thus demonstrating the strong dependency of the NPM1c-driven transcriptional program on the presence of NUP98. In contrast, in MV4-11 cells, NUP98 loss had no effect on HOXA/MEIS1 expression, suggesting a leukemia subtype-specific role of NUP98wt.

To delineate the domains of NUP98 required for its chromatin function, we performed a CRISPR gene tiling screen of full-length NUP98 (635 sgRNAs) and based on this we generated several domain-deletion mutants for rescue experiments in the NUP98-degrader cell lines. Retroviral overexpression of the N-terminal FG-repeat containing domains of NUP98 was sufficient to rescue cell viability and prevent the differentiation phenotype typically observed upon NUP98 degradation. Strikingly, gene expression analysis showed that the NUP98 FG-repeats were sufficient to restore the expression of HOXA10, MEIS1, and HOXB9 expression.

Overall, our study identifies NUP98wt as a critical cofactor for NPM1c-driven oncogenic transcription. NPM1c recruits NUP98 to its chromatin targets, functionally substituting for an oncogenic fusion partner to concentrate transcriptional condensates at oncogenic loci. This establishes a previously unrecognized, subtype-specific dependency on NUP98wt in leukemogenesis.