Project description:Understanding the molecular pathogenesis of MLL fusion oncoproteins (MLL-FP) has spawned epigenetic therapies that have improved clinical outcomes in this and other molecular subtypes of acute myeloid leukaemia (AML). Using genetic and pharmacological approaches, we define the individual and combined contribution of KAT6A, KAT6B and KAT7, in range of AML models. Whilst inhibition of KAT6A/B is efficacious in some pre-clinical models, simultaneous targeting of KAT7, with the novel inhibitor PF-9363, increases the therapeutic efficacy. KAT7 interacts with Menin and the MLL complex and is co-localised at chromatin to co-regulate the oncogenic transcriptional program. Focussing on MLL-FP AML, we show that inhibition of KAT6/KAT7 provides an orthogonal route to targeting Menin to disable the transcriptional activity of the MLL-FP. Consequently, combined inhibition rapidly evicts the MLL-FP from chromatin, potently represses oncogenic transcription and overcomes primary resistance to Menin inhibitors. Moreover, PF-9363 or genetic depletion reveals that KAT7 remains an important targetable dependency in acquired genetic/non-genetic resistance to Menin inhibition. These data provide the molecular rationale for rapid clinical translation of combination therapy, particularly in MLL-FP AML.  

Project description:Understanding the molecular pathogenesis of MLL fusion oncoproteins (MLL-FP) has spawned epigenetic therapies that have improved clinical outcomes in this and other molecular subtypes of acute myeloid leukaemia (AML). Using genetic and pharmacological approaches, we define the individual and combined contribution of KAT6A, KAT6B and KAT7, in range of AML models. Whilst inhibition of KAT6A/B is efficacious in some pre-clinical models, simultaneous targeting of KAT7, with the novel inhibitor PF-9363, increases the therapeutic efficacy. KAT7 interacts with Menin and the MLL complex and is co-localised at chromatin to co-regulate the oncogenic transcriptional program. Focussing on MLL-FP AML, we show that inhibition of KAT6/KAT7 provides an orthogonal route to targeting Menin to disable the transcriptional activity of the MLL-FP. Consequently, combined inhibition rapidly evicts the MLL-FP from chromatin, potently represses oncogenic transcription and overcomes primary resistance to Menin inhibitors. Moreover, PF-9363 or genetic depletion reveals that KAT7 remains an important targetable dependency in acquired genetic/non-genetic resistance to Menin inhibition. These data provide the molecular rationale for rapid clinical translation of combination therapy, particularly in MLL-FP AML.  

Project description:Targeting the MYST acetyltransferases are an exciting therapeutic opportunity in acute myeloid leukaemia (AML). Here we define the individual and combined contribution of KAT6A, KAT6B and KAT7, in range of AML models showing that although KAT6A/B inhibition is efficacious in some pre-clinical models, simultaneous targeting of KAT7, with the novel inhibitor PF-9363, markedly increases efficacy. KAT7 interacts with Menin and the MLL complex and is co-localised at chromatin to co-regulate oncogenic transcriptional programs. Focusing on MLL fusion oncoprotein (MLL-FP) AML, we show that inhibition of KAT6/KAT7 provides an orthogonal route to targeting Menin to disable the transcriptional activity of the MLL-FP. Combined inhibition rapidly evicts the MLL-FP from chromatin, potently represses oncogenic transcription and overcomes primary resistance to Menin inhibitors. Notably, KAT7 remains an important targetable dependency in acquired genetic/non-genetic resistance to Menin inhibition providing the molecular rationale for rapid clinical translation of combination therapy, particularly in MLL-FP AML.

Project description:Targeting the MYST acetyltransferases are an exciting therapeutic opportunity in acute myeloid leukaemia (AML). Here we define the individual and combined contribution of KAT6A, KAT6B and KAT7, in range of AML models showing that although KAT6A/B inhibition is efficacious in some pre-clinical models, simultaneous targeting of KAT7, with the novel inhibitor PF-9363, markedly increases efficacy. KAT7 interacts with Menin and the MLL complex and is co-localised at chromatin to co-regulate oncogenic transcriptional programs. Focusing on MLL fusion oncoprotein (MLL-FP) AML, we show that inhibition of KAT6/KAT7 provides an orthogonal route to targeting Menin to disable the transcriptional activity of the MLL-FP. Combined inhibition rapidly evicts the MLL-FP from chromatin, potently represses oncogenic transcription and overcomes primary resistance to Menin inhibitors. Notably, KAT7 remains an important targetable dependency in acquired genetic/non-genetic resistance to Menin inhibition providing the molecular rationale for rapid clinical translation of combination therapy, particularly in MLL-FP AML.

Project description:Targeting the MYST acetyltransferases are an exciting therapeutic opportunity in acute myeloid leukaemia (AML). Here we define the individual and combined contribution of KAT6A, KAT6B and KAT7, in range of AML models showing that although KAT6A/B inhibition is efficacious in some pre-clinical models, simultaneous targeting of KAT7, with the novel inhibitor PF-9363, markedly increases efficacy. KAT7 interacts with Menin and the MLL complex and is co-localised at chromatin to co-regulate oncogenic transcriptional programs. Focusing on MLL fusion oncoprotein (MLL-FP) AML, we show that inhibition of KAT6/KAT7 provides an orthogonal route to targeting Menin to disable the transcriptional activity of the MLL-FP. Combined inhibition rapidly evicts the MLL-FP from chromatin, potently represses oncogenic transcription and overcomes primary resistance to Menin inhibitors. Notably, KAT7 remains an important targetable dependency in acquired genetic/non-genetic resistance to Menin inhibition providing the molecular rationale for rapid clinical translation of combination therapy, particularly in MLL-FP AML.

Project description:Targeting the MYST acetyltransferases are an exciting therapeutic opportunity in acute myeloid leukaemia (AML). Here we define the individual and combined contribution of KAT6A, KAT6B and KAT7, in range of AML models showing that although KAT6A/B inhibition is efficacious in some pre-clinical models, simultaneous targeting of KAT7, with the novel inhibitor PF-9363, markedly increases efficacy. KAT7 interacts with Menin and the MLL complex and is co-localised at chromatin to co-regulate oncogenic transcriptional programs. Focusing on MLL fusion oncoprotein (MLL-FP) AML, we show that inhibition of KAT6/KAT7 provides an orthogonal route to targeting Menin to disable the transcriptional activity of the MLL-FP. Combined inhibition rapidly evicts the MLL-FP from chromatin, potently represses oncogenic transcription and overcomes primary resistance to Menin inhibitors. Notably, KAT7 remains an important targetable dependency in acquired genetic/non-genetic resistance to Menin inhibition providing the molecular rationale for rapid clinical translation of combination therapy, particularly in MLL-FP AML.

Project description:Understanding the molecular pathogenesis of MLL leukaemia has led to the development of epigenetic therapies that have altered the natural history of this often-incurable disease. Here, using complementary genetic and pharmacological approaches, we define the individual and combined contribution of the MYST acetyltransferases, KAT6A, KAT6B and KAT7, to MLL fusion oncoprotein (MLL-FP) driven acute leukaemia. We show that inhibition of KAT6A/B is efficacious in some but not all MLL-FP pre-clinical models; however, simultaneous targeting of KAT7 increases the therapeutic effect. At a molecular level, KAT7 interacts with Menin and other members the MLL complex and we demonstrate that these epigenetic regulators are co-localised at chromatin where they co-regulate the oncogenic transcriptional program initiated and maintained by the MLL-FP. Catalytic inhibition of KAT6/KAT7 with the novel small molecule inhibitor PF-9363 provides an orthogonal route to Menin inhibition to disable the transcriptional activity of MLL-FP. This is of clinical importance as PF-9363 or genetic depletion of KAT7 is able to overcome both genetic and non-genetic acquired resistance to Menin inhibition. Moreover, combined inhibition of KAT6/KAT7 and Menin results in a rapid eviction of chromatin bound MLL-FP and a profound repression of the oncogenic transcriptional program resulting in marked synergistic benefit in pre-clinical models of primary resistance to single agent therapy. Together these data provide the molecular rationale for rapid clinical translation of combination therapy to further improve clinical outcomes in MLL-FP leukaemia.

Project description:NUP98 fusion oncoproteins (FOs) are a hallmark of childhood acute myeloid leukemia (AML) and drive leukemogenesis through liquid-liquid phase separation-mediated nuclear condensate formation. However, the composition and consequences of NUP98 FO-associated condensates are incompletely understood. Here we show that MYST family histone acetyltransferase (HAT) complex proteins including MOZ/KAT6A, HBO1/KAT7, and the common MOZ/HBO1 complex subunit BRPF1 associate with NUP98 FOs on chromatin and within condensates. MYST HATs are molecular dependencies in NUP98-rearranged (NUP98-r) leukemia, and genetic inactivation or pharmacologic inhibition of Moz and Hbo1 impairs NUP98-r cell fitness. MOZ/HBO1 inhibition decreased global H3K23ac levels, displaced NUP98::HOXA9 from chromatin at the Meis1 locus, and led to myeloid cell differentiation. Additionally, MOZ/HBO1 inhibition decreased leukemic burden in multiple NUP98-r leukemia xenograft mouse models, synergized with Menin inhibitor treatment, and was efficacious in Menin inhibitor-resistant cells. In summary, we show that MYST family HATs are therapeutically actionable dependencies in NUP98-r AML.

Project description:NUP98 fusion oncoproteins (FOs) are a hallmark of childhood acute myeloid leukemia (AML) and drive leukemogenesis through liquid-liquid phase separation-mediated nuclear condensate formation. However, the composition and consequences of NUP98 FO-associated condensates are incompletely understood. Here we show that MYST family histone acetyltransferase (HAT) complex proteins including MOZ/KAT6A, HBO1/KAT7, and the common MOZ/HBO1 complex subunit BRPF1 associate with NUP98 FOs on chromatin and within condensates. MYST HATs are molecular dependencies in NUP98-rearranged (NUP98-r) leukemia, and genetic inactivation or pharmacologic inhibition of Moz and Hbo1 impairs NUP98-r cell fitness. MOZ/HBO1 inhibition decreased global H3K23ac levels, displaced NUP98::HOXA9 from chromatin at the Meis1 locus, and led to myeloid cell differentiation. Additionally, MOZ/HBO1 inhibition decreased leukemic burden in multiple NUP98-r leukemia xenograft mouse models, synergized with Menin inhibitor treatment, and was efficacious in Menin inhibitor-resistant cells. In summary, we show that MYST family HATs are therapeutically actionable dependencies in NUP98-r AML.

Project description:KAT6A-CBP (K/C) and KAT6A-P300 (K/P) fusions are recurrent genetic alterations in acute myeloid leukemia(AML) that are associated with poor prognosis. The large size of these fusion proteins has posed challenges in developing preclinical models, limiting mechanistic studies. To address this, we employed a domain-focused truncation strategy to generate de novo murine models of K/C and K/P fusions, which faithfully recapitulate the morphological, immunophenotypic, and transcriptomic features of KAT6A-rearranged AML. Genomic profiling revealed that KAT6A fusions preferentially localize to H3K4me2/3-marked regions and interact with the Nucleosome Remodeling Factor (NURF), a critical H3K4me2/3 reader. Disrupting NURF-chromatin interactions impaired K/C recruitment to target loci and disrupted MLL/COMPASS-mediated H3K4me2 deposition, thereby establishing an epigenetic regulatory module involving KAT6A chimeras, NURF, and MLL/COMPASS. Concurrently, CBP/P300 inhibition reduced histone acetylation, chromatin accessibility, and genomic targeting of the module. Therapeutically, NURF inhibition induced cell cycle arrest and suppressed leukemia proliferation, while CBP/P300 inhibition promoted leukemia differentiation. Both strategies demonstrated promising efficacy in K/C murine models, with superior effects observed with combined NURF and CBP/P300 inhibition. These findings uncover a self-reinforcing epigenetic module centered on histone reader proteins and modifying enzymes, providing mechanistic insights into KAT6A-rearranged AML and identifying promising combinatorial therapeutic vulnerabilities.