HoxBlinc lncRNA reprograms CTCF-independent TADs to drive leukemic transcription and HSC dysregulation in NUP98-rearranged leukemia
Karina Hamamoto, Ganqian Zhu, Qian Lai, Julia Lesperance, Huacheng Luo, Ying Li, Nupur Nigam, Arati Sharma, Feng-Chun Yang, David Claxton, Yi Qiu, Peter D. Aplan, Mingjiang Xu, Suming Huang
Karina Hamamoto, Ganqian Zhu, Qian Lai, Julia Lesperance, Huacheng Luo, Ying Li, Nupur Nigam, Arati Sharma, Feng-Chun Yang, David Claxton, Yi Qiu, Peter D. Aplan, Mingjiang Xu, Suming Huang
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Research Article Genetics Hematology

HoxBlinc lncRNA reprograms CTCF-independent TADs to drive leukemic transcription and HSC dysregulation in NUP98-rearranged leukemia

Abstract

Although nucleoporin 98 (NUP98) fusion oncogenes often drive aggressive pediatric leukemia by altering chromatin structure and expression of homeobox (HOX) genes, underlying mechanisms remain elusive. Here, we report that the Hoxb-associated lncRNA HoxBlinc was aberrantly activated in NUP98-PHF23 fusion–driven leukemias. HoxBlinc chromatin occupancies led to elevated mixed-lineage leukemia 1 (MLL1) recruitment and aberrant homeotic topologically associated domains (TADs) that enhanced chromatin accessibilities and activated homeotic/hematopoietic oncogenes. HoxBlinc depletion in NUP98 fusion–driven leukemia impaired HoxBlinc binding, TAD integrity, MLL1 recruitment, and the MLL1-driven chromatin signature within HoxBlinc-defined TADs in a CCCTC-binding factor–independent (CTCF-independent) manner, leading to inhibited homeotic/leukemic oncogenes that mitigated NUP98 fusion–driven leukemogenesis in xenografted mouse models. Mechanistically, HoxBlinc overexpression in the mouse hematopoietic compartment induced leukemias resembling those in NUP98-PHF23–knockin (KI) mice via enhancement of HoxBlinc chromatin binding, TAD formation, and Hox gene aberration, leading to expansion of hematopoietic stem and progenitor cell and myeloid/lymphoid cell subpopulations. Thus, our studies reveal a CTCF-independent role of HoxBlinc in leukemic TAD organization and oncogene-regulatory networks.

Authors

Karina Hamamoto, Ganqian Zhu, Qian Lai, Julia Lesperance, Huacheng Luo, Ying Li, Nupur Nigam, Arati Sharma, Feng-Chun Yang, David Claxton, Yi Qiu, Peter D. Aplan, Mingjiang Xu, Suming Huang

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Figure 2

HoxBlinc defines chromatin boundaries of Hoxa/b TADs in NUP98-PHF23–driven leukemia.

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HoxBlinc defines chromatin boundaries of Hoxa/b TADs in NUP98-PHF23–dri...
(A) Pie chart shows overlapping of TADs by Hi-C in 961C B-ALL cells compared with BaF3 B cell precursors. The domain score for an altered TAD was normalized (quantile normalization) by subtracting the mean of all TAD Hi-C signals. ANOVA was used to identify significantly altered TADs (Bonferroni-corrected P ≤ 0.05). (B) Top 10 upregulated TADs in 961C B-ALL cells as compared with BaF3 B cell precursors. (C) HiC-Seq–interacting maps in part of the mouse chromosome 6 and chromosome 11 regions of Hoxa and Hoxb loci comparing BaF3 B cell precursors and 961C B- ALL cells. Black arrows indicate upregulated TADs/sub-TADs in 961C cells. Top panel shows HoxBlinc and CTCF binding in the corresponding Hoxa/b loci. (D) Top: Pie chart shows overlapping of TAD-upregulated (TAD UP) genes and promoters bound by HoxBlinc lncRNA. Bottom: GO analysis of these 167 overlapping genes.