Project description:We found NUP98 fusions activate Hoxb-associated lncRNA, HoxBlinc that occupies homeotic/oncogenic topologically associated domain (TAD) boundaries in malignant hematopoiesis. Aberration of HoxBlinc led to recruitment of MLL1 complex and reorganization of homeotic/oncogenicTADs that enhanced chromatin accessibilities and aberrantly activated homeotic/hematopoietic oncogenes defined by Hoxblinc chromatin occupancies in NUP98-PHF23 related murine leukemia cells. Eliminated HoxBlinc in NUP98 fusion-driven leukemic cells resulted in loss of Hoxblinc binding, TAD integrity, recruitment of MLL complex, and MLL driven H3K4me3 and chromatin accessibility within the HoxBlinc defined domain in a CTCF independent manner, leading to inhibiting homeotic/leukemic oncogenes and mitigating NUP98 fusion-driven leukemia in xenografted mouse models. Moreover, overexpression of HoxBlinc in mouse bone marrow hematopoietic compartment developed multiple leukemia resembling NUP98-PHF23 knock-in mice via enhancing HoxBlinc binding and TAD formation to transcriptionally expanding HS/PC and myeloid/lymphoid subpopulations leading to leukemogenesis. Our studies reveal a CTCF independent role of HoxBlinc in leukemic TAD organization and oncogenic gene regulatory networks in NUP98-fusion related leukemia.

Project description:We found NUP98 fusions activate Hoxb-associated lncRNA, HoxBlinc that occupies homeotic/oncogenic topologically associated domain (TAD) boundaries in malignant hematopoiesis. Aberration of HoxBlinc led to recruitment of MLL1 complex and reorganization of homeotic/oncogenicTADs that enhanced chromatin accessibilities and aberrantly activated homeotic/hematopoietic oncogenes defined by Hoxblinc chromatin occupancies in NUP98-PHF23 related murine leukemia cells. Eliminated HoxBlinc in NUP98 fusion-driven leukemic cells resulted in loss of Hoxblinc binding, TAD integrity, recruitment of MLL complex, and MLL driven H3K4me3 and chromatin accessibility within the HoxBlinc defined domain in a CTCF independent manner, leading to inhibiting homeotic/leukemic oncogenes and mitigating NUP98 fusion-driven leukemia in xenografted mouse models. Moreover, overexpression of HoxBlinc in mouse bone marrow hematopoietic compartment developed multiple leukemia resembling NUP98-PHF23 knock-in mice via enhancing HoxBlinc binding and TAD formation to transcriptionally expanding HS/PC and myeloid/lymphoid subpopulations leading to leukemogenesis. Our studies reveal a CTCF independent role of HoxBlinc in leukemic TAD organization and oncogenic gene regulatory networks in NUP98-fusion related leukemia.

Project description:We found NUP98 fusions activate Hoxb-associated lncRNA, HoxBlinc that occupies homeotic/oncogenic topologically associated domain (TAD) boundaries in malignant hematopoiesis. Aberration of HoxBlinc led to recruitment of MLL1 complex and reorganization of homeotic/oncogenicTADs that enhanced chromatin accessibilities and aberrantly activated homeotic/hematopoietic oncogenes defined by Hoxblinc chromatin occupancies in NUP98-PHF23 related murine leukemia cells. Eliminated HoxBlinc in NUP98 fusion-driven leukemic cells resulted in loss of Hoxblinc binding, TAD integrity, recruitment of MLL complex, and MLL driven H3K4me3 and chromatin accessibility within the HoxBlinc defined domain in a CTCF independent manner, leading to inhibiting homeotic/leukemic oncogenes and mitigating NUP98 fusion-driven leukemia in xenografted mouse models. Moreover, overexpression of HoxBlinc in mouse bone marrow hematopoietic compartment developed multiple leukemia resembling NUP98-PHF23 knock-in mice via enhancing HoxBlinc binding and TAD formation to transcriptionally expanding HS/PC and myeloid/lymphoid subpopulations leading to leukemogenesis. Our studies reveal a CTCF independent role of HoxBlinc in leukemic TAD organization and oncogenic gene regulatory networks in NUP98-fusion related leukemia.

Project description:We found NUP98 fusions activate Hoxb-associated lncRNA, HoxBlinc that occupies homeotic/oncogenic topologically associated domain (TAD) boundaries in malignant hematopoiesis. Aberration of HoxBlinc led to recruitment of MLL1 complex and reorganization of homeotic/oncogenicTADs that enhanced chromatin accessibilities and aberrantly activated homeotic/hematopoietic oncogenes defined by Hoxblinc chromatin occupancies in NUP98-PHF23 related murine leukemia cells. Eliminated HoxBlinc in NUP98 fusion-driven leukemic cells resulted in loss of Hoxblinc binding, TAD integrity, recruitment of MLL complex, and MLL driven H3K4me3 and chromatin accessibility within the HoxBlinc defined domain in a CTCF independent manner, leading to inhibiting homeotic/leukemic oncogenes and mitigating NUP98 fusion-driven leukemia in xenografted mouse models. Moreover, overexpression of HoxBlinc in mouse bone marrow hematopoietic compartment developed multiple leukemia resembling NUP98-PHF23 knock-in mice via enhancing HoxBlinc binding and TAD formation to transcriptionally expanding HS/PC and myeloid/lymphoid subpopulations leading to leukemogenesis. Our studies reveal a CTCF independent role of HoxBlinc in leukemic TAD organization and oncogenic gene regulatory networks in NUP98-fusion related leukemia.

Project description:We found NUP98 fusions activate Hoxb-associated lncRNA, HoxBlinc that occupies homeotic/oncogenic topologically associated domain (TAD) boundaries in malignant hematopoiesis. Aberration of HoxBlinc led to recruitment of MLL1 complex and reorganization of homeotic/oncogenicTADs that enhanced chromatin accessibilities and aberrantly activated homeotic/hematopoietic oncogenes defined by Hoxblinc chromatin occupancies in NUP98-PHF23 related murine leukemia cells. Eliminated HoxBlinc in NUP98 fusion-driven leukemic cells resulted in loss of Hoxblinc binding, TAD integrity, recruitment of MLL complex, and MLL driven H3K4me3 and chromatin accessibility within the HoxBlinc defined domain in a CTCF independent manner, leading to inhibiting homeotic/leukemic oncogenes and mitigating NUP98 fusion-driven leukemia in xenografted mouse models. Moreover, overexpression of HoxBlinc in mouse bone marrow hematopoietic compartment developed multiple leukemia resembling NUP98-PHF23 knock-in mice via enhancing HoxBlinc binding and TAD formation to transcriptionally expanding HS/PC and myeloid/lymphoid subpopulations leading to leukemogenesis. Our studies reveal a CTCF independent role of HoxBlinc in leukemic TAD organization and oncogenic gene regulatory networks in NUP98-fusion related leukemia.

Project description:We found NUP98 fusions activate Hoxb-associated lncRNA, HoxBlinc that occupies homeotic/oncogenic topologically associated domain (TAD) boundaries in malignant hematopoiesis. Aberration of HoxBlinc led to recruitment of MLL1 complex and reorganization of homeotic/oncogenicTADs that enhanced chromatin accessibilities and aberrantly activated homeotic/hematopoietic oncogenes defined by Hoxblinc chromatin occupancies in NUP98-PHF23 related murine leukemia cells. Eliminated HoxBlinc in NUP98 fusion-driven leukemic cells resulted in loss of Hoxblinc binding, TAD integrity, recruitment of MLL complex, and MLL driven H3K4me3 and chromatin accessibility within the HoxBlinc defined domain in a CTCF independent manner, leading to inhibiting homeotic/leukemic oncogenes and mitigating NUP98 fusion-driven leukemia in xenografted mouse models. Moreover, overexpression of HoxBlinc in mouse bone marrow hematopoietic compartment developed multiple leukemia resembling NUP98-PHF23 knock-in mice via enhancing HoxBlinc binding and TAD formation to transcriptionally expanding HS/PC and myeloid/lymphoid subpopulations leading to leukemogenesis. Our studies reveal a CTCF independent role of HoxBlinc in leukemic TAD organization and oncogenic gene regulatory networks in NUP98-fusion related leukemia.

Project description:We found NUP98 fusions activate Hoxb-associated lncRNA, HoxBlinc that occupies and regulates homeotic/oncogenic topologically associated domain (TAD) in malignant hematopoiesis. Aberration of HoxBlinc led to recruitment of MLL1 complex , altered chromatin landscape (both H3K4me3 and chromatin accessibility), and HOX/homeotic gene activatiion in NUP98-PHF23 fusion driven leukemia and HoxBlinc -Tg models. Conversely, eliminated HoxBlinc in NUP98 fusion-driven leukemic cells resulted in loss of Hoxblinc binding, TAD integrity, recruitment of MLL complex, and MLL driven H3K4me3 and chromatin accessibility within the HoxBlinc defined domain in a CTCF independent manner, leading to inhibiting homeotic/leukemic oncogenes and mitigating NUP98 fusion-driven leukemia in xenografted mouse models. Thus, our studies revealed a CTCF independent role of HoxBlinc in leukemic TAD organization and oncogenic gene regulatory networks in NUP98-fusion related leukemia.

Project description:Cancer-associated genetic aberrations, such as the nucleoporin 98 (NUP98) gene rearrangement detected in human leukemias, often produce condensates, a type of membrane-less biomolecular assemblies. How exactly the cancer-related condensation contributes to oncogenesis remains far from clear. Here, we investigate NUP98-PHF23, a leukemia-causing chimeric protein that fuses NUP98’s sequence enriched in phenylalanine-and-glycine repeats (FG repeats, also known as intrinsically disordered region [IDR]) in-frame with PHF23’s PHD finger, a domain that specifically ‘reads’ and binds H3K4 trimethylation (H3K4me3). Our integrated analyses using protein module mutagenesis, cell imaging, genomic profiling and condensation reconstitution collectively demonstrate a multifaced role for NUP98’s FG repeats in driving fusion condensation while recruiting and co-mixing with a set of histone modifiers and chromatin remodelers, notably the MLL family of H3K4 methylation-‘writing’ enzymes. The H3K4me3-‘reading’ PHD finger and NUP98’s IDR are cooperative in mediating efficient targeting of NUP98-PHF23 and its coactivators onto leukemic genes, leading to active transcription. Together, we show that NUP98-PHF23 coordinates a set of homotypic and heterotypic interactions (IDR:IDR, IDR:coactivator and PHD:histone) to organize formation of the chromatin-bound multi-component condensates, wherein a feedforward loop involving the ‘reading’ and ‘writing’ of H3K4 methylation acts to enforce an open chromatin landscape at leukemogenic loci, thereby driving oncogenic transformation.

Project description:Cancer-associated genetic aberrations, such as the nucleoporin 98 (NUP98) gene rearrangement detected in human leukemias, often produce condensates, a type of membrane-less biomolecular assemblies. How exactly the cancer-related condensation contributes to oncogenesis remains far from clear. Here, we investigate NUP98-PHF23, a leukemia-causing chimeric protein that fuses NUP98’s sequence enriched in phenylalanine-and-glycine repeats (FG repeats, also known as intrinsically disordered region [IDR]) in-frame with PHF23’s PHD finger, a domain that specifically ‘reads’ and binds H3K4 trimethylation (H3K4me3). Our integrated analyses using protein module mutagenesis, cell imaging, genomic profiling and condensation reconstitution collectively demonstrate a multifaced role for NUP98’s FG repeats in driving fusion condensation while recruiting and co-mixing with a set of histone modifiers and chromatin remodelers, notably the MLL family of H3K4 methylation-‘writing’ enzymes. The H3K4me3-‘reading’ PHD finger and NUP98’s IDR are cooperative in mediating efficient targeting of NUP98-PHF23 and its coactivators onto leukemic genes, leading to active transcription. Together, we show that NUP98-PHF23 coordinates a set of homotypic and heterotypic interactions (IDR:IDR, IDR:coactivator and PHD:histone) to organize formation of the chromatin-bound multi-component condensates, wherein a feedforward loop involving the ‘reading’ and ‘writing’ of H3K4 methylation acts to enforce an open chromatin landscape at leukemogenic loci, thereby driving oncogenic transformation.

Project description:Recurrent cancer-causing fusions of NUP98 produce higher-order assemblies known as condensates. How NUP98 oncofusion-driven condensates activate oncogenes remains poorly understood. Here, we investigate NUP98-PHF23, a leukemogenic chimera of the disordered FG-repeats-rich region of NUP98 and the H3K4me3/2-binding PHD finger domain of PHF23. Our integrated analyses using mutagenesis, proteomics, genomics, and condensate reconstitution demonstrate that the PHD domain targets condensates to H3K4me3/2-demarcated developmental genes while the FG repeats determine condensate composition and gene activation. The FG repeats are necessary to form condensates that partition a specific set of transcriptional regulators, notably the KMT2/MLL family of H3K4 methyltransferases, histone acetyltransferases and BRD4. The FG repeats are sufficient to partition these transcriptional regulators and activate a reporter when tethered to a locus. NUP98-PHF23 assembles the chromatin-bound condensates that partition multiple positive regulators, initiating a feed-forward loop of reading-and-writing active histone modifications. This network of interactions enforces an open chromatin landscape at proto-oncogenes, thereby driving cancerous transcriptional programs.