Project description:NPM1 mutation (NPM1c)-driven acute myeloid leukemia (AML) is characterized by the sequestration of nuclear proteins and chromatin hijacking. Current treatment strategies targeting NPM1c AML are often indirect, which might lead to toxicity and resistance. In this study, we developed an allele-specific siRNA that selectively silences NPM1c while preserving the function of wild-type NPM1. This approach inhibited proliferation and promoted myeloid differentiation in NPM1-mutated AML cells in vitro. Notably, the systemic delivery of chemically optimized siNPM1c via lipid nanoparticles (LNPs) significantly reduced leukemogenesis, and enhanced the therapeutic efficacy of the menin inhibitor revumenib and overcame its resistance in vivo. Mechanistically, NPM1c recruits KAT7 and p300, driving leukemogenic transcription and establishing a pathogenic acetylome and open chromatin state. KAT7 recruitment is crucial for the retention of this complex on chromatin. Targeting NPM1c with siRNA disrupts this interaction, reverses the oncogenic epigenetic landscape, and suppresses transcription. Our findings demonstrate that silencing NPM1c effectively suppresses AML by dismantling a pathogenic KAT7/p300-dependent acetylome, highlighting the potential of LNP‑delivered siNPM1c as a promising therapeutic strategy, either as a monotherapy or in combination with menin inhibition.

Project description:NPM1 mutation (NPM1c)-driven acute myeloid leukemia (AML) is characterized by the sequestration of nuclear proteins and chromatin hijacking. Current treatment strategies targeting NPM1c AML are often indirect, which might lead to toxicity and resistance. In this study, we developed an allele-specific siRNA that selectively silences NPM1c while preserving the function of wild-type NPM1. This approach inhibited proliferation and promoted myeloid differentiation in NPM1-mutated AML cells in vitro. Notably, the systemic delivery of chemically optimized siNPM1c via lipid nanoparticles (LNPs) significantly reduced leukemogenesis, and enhanced the therapeutic efficacy of the menin inhibitor revumenib and overcame its resistance in vivo. Mechanistically, NPM1c recruits KAT7 and p300, driving leukemogenic transcription and establishing a pathogenic acetylome and open chromatin state. KAT7 recruitment is crucial for the retention of this complex on chromatin. Targeting NPM1c with siRNA disrupts this interaction, reverses the oncogenic epigenetic landscape, and suppresses transcription. Our findings demonstrate that silencing NPM1c effectively suppresses AML by dismantling a pathogenic KAT7/p300-dependent acetylome, highlighting the potential of LNP‑delivered siNPM1c as a promising therapeutic strategy, either as a monotherapy or in combination with menin inhibition.

Project description:NPM1 is the most frequently mutated gene in cytogenetically normal acute myeloid leukemia (AML). In AML cells, NPM1 mutations result in abnormal cytoplasmic localization of the mutant protein (NPM1c). NPM1 mutations are founding genetic lesions, however it is unknown whether NPM1c is required to maintain the leukemic state. Here, we show that loss of NPM1c from the cytoplasm, either through nuclear relocalization or targeted degradation, results in downregulation of homeobox (HOX) genes, and differentiation and cell growth arrest of AML cells. Additionally, we show that HOX downregulation is the earliest transcriptional event following the loss of NPM1c from the cytoplasm, preceding and promoting differentiation. Finally, we show that XPO1 inhibition efficiently relocalizes NPM1c to the nucleus, enables differentiation and prolongs survival of Npm1c+ leukemic mice. We describe an exquisite dependency of NPM1-mutant AML cells on NPM1c, providing the rationale for the use of nuclear export inhibitors in AML with mutated NPM1.

Project description:NPM1 is the most frequently mutated gene in cytogenetically normal acute myeloid leukemia (AML). In AML cells, NPM1 mutations result in abnormal cytoplasmic localization of the mutant protein (NPM1c). NPM1 mutations are founding genetic lesions, however it is unknown whether NPM1c is required to maintain the leukemic state. Here, we show that loss of NPM1c from the cytoplasm, either through nuclear relocalization or targeted degradation, results in downregulation of homeobox (HOX) genes, and differentiation and cell growth arrest of AML cells. Additionally, we show that HOX downregulation is the earliest transcriptional event following the loss of NPM1c from the cytoplasm, preceding and promoting differentiation. Finally, we show that XPO1 inhibition efficiently relocalizes NPM1c to the nucleus, enables differentiation and prolongs survival of Npm1c+ leukemic mice. We describe an exquisite dependency of NPM1-mutant AML cells on NPM1c, providing the rationale for the use of nuclear export inhibitors in AML with mutated NPM1.

Project description:NPM1-mutated acute myeloid leukemia (AML) accounts for one third of AML in adults. NPM1-mutated AML maintenance depends on the interaction between mutated NPM1 (NPM1c) and the nuclear exporter Exportin 1 (XPO1). In this work, we show that continous XPO1 inhibition is necessary to achieve stable disruption of the NPM1c-XPO1 interaction and to induce HOX downregulation and differentiation of AML cells with mutated NPM1. In contrast, intermittent XPO1 inhibition only results in minimal transcriptional perturbation and limited antileukemic activity.

Project description:The nucleolar scaffold protein NPM1 acts as a multifunctional regulator of cellular homeostasis, genome integrity, and stress response. NPM1 mutations, known as NPM1c variants that promote its aberrant cytoplasmic localization, are the most frequent genetic alterations in acute myeloid leukemia (AML). A hallmark of AML cells is their dependency on elevated autophagic flux. In order to identify the proteome changes upon NPM1 and NPM1c overexpression, we performed TMT-labeled mass spectrometry analysis of whole cell lysates.

Project description:The nucleolar scaffold protein NPM1 acts as a multifunctional regulator of cellular homeostasis, genome integrity, and stress response. NPM1 mutations, known as NPM1c variants that promote its aberrant cytoplasmic localization, are the most frequent genetic alterations in acute myeloid leukemia (AML). A hallmark of AML cells is their dependency on elevated autophagic flux. In order to identify the proteome changes upon NPM1 and NPM1c overexpression, we performed TMT-labeled mass spectrometry analysis of whole cell lysates.

Project description:Nucleophosmin (NPM1) is a ubiquitously expressed nucleolar protein with a wide range of functions including ribosome biogenesis, mRNA processing, and maintenance of genomic stability1-4. In acute myeloid leukemia (AML), the terminal exon of NPM1 is often mutated (~30% of adult AMLs), resulting in the change of the nucleolar localization signal into a nuclear export signal and a shift of the protein to the cytoplasm (NPM1c)2,3,5. AMLs carrying this mutation have aberrant expression of the HOXA genes, whose overexpression leads to leukemogenic transformation6-8. Recently, it was shown that depletion or re-localization of the NPM1c protein into the nucleus causes downregulation of the HOXA genes, leading to the speculation that NPM1c directly regulates their transcription9-11. Here, we show that NPM1c binds to a subset of active gene promoters marked with high levels of H3K27ac in NPM1c leukemia cell lines and primary leukemia blasts, including well-known leukemia-driving genes such as posterior HOXA, HOXB, and MEIS1/PBX3 genes as well as novel targets IRX5 and NKX2-3. The binding of NPM1c on chromatin sustains active transcription of key target genes by maintaining high local-concentration of transcriptional complexes, including the Super Elongation Complex (SEC) and Menin/MLL1. NPM1c also maintains the active chromatin landscape by inhibiting the activity of histone deacetylases (HDACs). Depletion of NPM1c causes histone deacetylation and the silencing of key leukemic genes, leading to cell differentiation and growth arrest. The export protein XPO1 plays a key role by tethering NPM1c onto chromatin. The combination of XPO1 inhibitors (e.g., Selinexor and Eltanexor) with the Menin inhibitor MI-3454 has a synergistic effect on inducing differentiation in both NPM1-mutated leukemia cell lines and PDX model. Together, these findings reveal the neomorphic function of NPM1c as transactivator for leukemic gene expression and open up potential avenues for therapeutic intervention.

Project description:Nucleophosmin (NPM1) is a ubiquitously expressed nucleolar protein with a wide range of functions including ribosome biogenesis, mRNA processing, and maintenance of genomic stability1-4. In acute myeloid leukemia (AML), the terminal exon of NPM1 is often mutated (~30% of adult AMLs), resulting in the change of the nucleolar localization signal into a nuclear export signal and a shift of the protein to the cytoplasm (NPM1c)2,3,5. AMLs carrying this mutation have aberrant expression of the HOXA genes, whose overexpression leads to leukemogenic transformation6-8. Recently, it was shown that depletion or re-localization of the NPM1c protein into the nucleus causes downregulation of the HOXA genes, leading to the speculation that NPM1c directly regulates their transcription9-11. Here, we show that NPM1c binds to a subset of active gene promoters marked with high levels of H3K27ac in NPM1c leukemia cell lines and primary leukemia blasts, including well-known leukemia-driving genes such as posterior HOXA, HOXB, and MEIS1/PBX3 genes as well as novel targets IRX5 and NKX2-3. The binding of NPM1c on chromatin sustains active transcription of key target genes by maintaining high local-concentration of transcriptional complexes, including the Super Elongation Complex (SEC) and Menin/MLL1. NPM1c also maintains the active chromatin landscape by inhibiting the activity of histone deacetylases (HDACs). Depletion of NPM1c causes histone deacetylation and the silencing of key leukemic genes, leading to cell differentiation and growth arrest. The export protein XPO1 plays a key role by tethering NPM1c onto chromatin. The combination of XPO1 inhibitors (e.g., Selinexor and Eltanexor) with the Menin inhibitor MI-3454 has a synergistic effect on inducing differentiation in both NPM1-mutated leukemia cell lines and PDX model. Together, these findings reveal the neomorphic function of NPM1c as transactivator for leukemic gene expression and open up potential avenues for therapeutic intervention.

Project description:Nucleophosmin (NPM1) is a ubiquitously expressed nucleolar protein with a wide range of functions including ribosome biogenesis, mRNA processing, and maintenance of genomic stability1-4. In acute myeloid leukemia (AML), the terminal exon of NPM1 is often mutated (~30% of adult AMLs), resulting in the change of the nucleolar localization signal into a nuclear export signal and a shift of the protein to the cytoplasm (NPM1c)2,3,5. AMLs carrying this mutation have aberrant expression of the HOXA genes, whose overexpression leads to leukemogenic transformation6-8. Recently, it was shown that depletion or re-localization of the NPM1c protein into the nucleus causes downregulation of the HOXA genes, leading to the speculation that NPM1c directly regulates their transcription9-11. Here, we show that NPM1c binds to a subset of active gene promoters marked with high levels of H3K27ac in NPM1c leukemia cell lines and primary leukemia blasts, including well-known leukemia-driving genes such as posterior HOXA, HOXB, and MEIS1/PBX3 genes as well as novel targets IRX5 and NKX2-3. The binding of NPM1c on chromatin sustains active transcription of key target genes by maintaining high local-concentration of transcriptional complexes, including the Super Elongation Complex (SEC) and Menin/MLL1. NPM1c also maintains the active chromatin landscape by inhibiting the activity of histone deacetylases (HDACs). Depletion of NPM1c causes histone deacetylation and the silencing of key leukemic genes, leading to cell differentiation and growth arrest. The export protein XPO1 plays a key role by tethering NPM1c onto chromatin. The combination of XPO1 inhibitors (e.g., Selinexor and Eltanexor) with the Menin inhibitor MI-3454 has a synergistic effect on inducing differentiation in both NPM1-mutated leukemia cell lines and PDX model. Together, these findings reveal the neomorphic function of NPM1c as transactivator for leukemic gene expression and open up potential avenues for therapeutic intervention.