Project description:Treatment with Menin inhibitor (MI) disrupts interaction between Menin and MLL1 or MLL1-fusion protein (FP), inhibits HOXA9/MEIS1, induces differentiation and loss of survival of AML harboring MLL1 re-arrangement (r) and FP, or expressing mutant (mt)-NPM1. Following MI treatment, although clinical responses are common, majority of patients with AML with MLLr or mt-NPM1 succumb to their disease. Pre-clinical studies presented here demonstrate that genetic knockout or degradation of Menin, or treatment with the MI SNDX-50469 reduces MLL1/MLL1-FP targets, associated with MI-induced differentiation and loss of viability. MI treatment also attenuates BCL2 and CDK6 levels. Co-treatment with SNDX-50469 and BCL2 inhibitor (venetoclax), or CDK6 inhibitor (abemaciclib) induces synergistic lethality in cell lines and patient-derived AML cells harboring MLL1r or mtNPM1. Combined therapy with SNDX-5613 and venetoclax exerts superior in vivo efficacy in cell line or PD AML cell xenografts harboring MLL1r or mt-NPM1. Synergy with the MI-based combinations is preserved against MLLr AML cells expressing FLT3 mutation, also CRISPR edited to introduce mtTP53. These findings highlight the promise of clinically testing these MI-based combinations against AML harboring MLL1r or mtNPM1.

Project description:Menin inhibitors have demonstrated profound preclinical activity in MLL1-rearranged and NPM1 mutated AML and in this context, ziftomenib is a novel compound currently assessed in a clinical phase I/II trials. We assessed preclinical effects of ziftomenib and demonstrate profound synergy in combination with compounds targeting chromatin regulation and apoptosis including the BCL2 inhibitor venetoclax which was validated in primary AML samples and an MLL-r and NPM1 mutated AML xenograft model.

Project description:Genome wide DNA methylation profiling of parental, ABT-199 resistant population, and ABT-199 resistant clones from 3 acute myelogenous leukemia (AML) cell lines (MOLM-13, MV-4-11, OCI-AMLO2). The Illumina Infinium MethylationEPIC Human DNA methylation Beadchip was used to obtain DNA methylation profiles across approximately 850,000 CpGs from AML cell line samples. Samples include 4 ABT-199 sensitive parental MOLM-13 population samples, 4 ABT-199 resistant MOLM-13 population samples, 3 ABT-199 resistant MOLM-13 S2 clone samples, 3 ABT-199 resistant MOLM-13 S5 clone samples, 4 ABT-199 resistant MOLM-13 S6 clone samples, 3 ABT-199 sensitive parental MV-4-11 population samples, 3 ABT-199 resistant MV-4-11 population samples, 3 ABT-199 sensitive parental OCI-AML2 population samples, 3 ABT-199 resistant OCI-AML2 population samples, 3 ABT-199 resistant OCI-AML2 S1 clone samples, 3 ABT-199 resistant OCI-AML2 S2 clone samples, 3 ABT-199 resistant OCI-AML2 S8 clone samples.

Project description:Homeobox (HOX) proteins and the receptor tyrosine kinase FLT3 are frequently highly expressed and mutated in acute myeloid leukemia (AML). Aberrant HOX expression is found in nearly all AMLs that harbor a mutation in the Nucleophosmin (NPM1) gene, and FLT3 is concomitantly mutated in approximately 60% of these cases. Little is known how mutant NPM1 (NPM1mut) cells maintain aberrant gene expression. Here, we demonstrate that the histone modifiers MLL1 and DOT1L control HOX and FLT3 expression and differentiation in NPM1mut AML. Using a CRISPR-Cas9 genome editing domain screen, we show NPM1mut AML to be exceptionally dependent on the menin binding site in MLL1. Pharmacological small-molecule inhibition of the menin-MLL protein interaction had profound anti-leukemic activity in human and murine models of NPM1mut AML in vitro and in vivo. Combined pharmacological inhibition of menin-MLL and DOT1L resulted in dramatic suppression of HOX and FLT3 expression, induction of differentiation, and superior activity against NPM1mut leukemia. Together, MLL1 and DOT1L are chromatin regulators that control HOX, MEIS1 and FLT3 expression and are therapeutic targets in NPM1mut AML. Combinatorial small-molecule inhibition has synergistic on target activity and constitutes a novel therapeutic concept for this common AML subtype. RNA sequencing data of the human AML cell lines OCI-AML2 and OCI-AML3 comparing EPZ004777 [10µM] drug treatment versus DMSO vehicle control; experiments performed in biological triplicates.

Project description:GSK3alpha has been identified as a new target in the treatment of acute myeloid leukemia (AML). However, most GSK3 inhibitors lack specificity for GSK3alpha over GSK3beta and other kinases. We have previously shown in lung cancer cells that GSK3alpha and to a lesser extent GSK3beta are inhibited by the advanced clinical candidate tivantinib (ARQ197), which was designed as a MET inhibitor. Thus, we hypothesized that tivantinib would be an effective therapy for the treatment of AML. Here, we show that tivantinib has potent anticancer activity across several AML cell lines and primary patient cells. Tivantinib strongly induced apoptosis, differentiation and G2/M cell cycle arrest and caused less undesirable stabilization of beta-catenin compared to the pan-GSK3 inhibitor LiCl. Subsequent drug combination studies identified the BCL-2 inhibitor ABT-199 to synergize with tivantinib. Interestingly, the addition of ABT-199 to tivantinib completely abrogated tivantinib induced beta-catenin stabilization. Tivantinib alone, or in combination with ABT-199, downregulated anti-apoptotic MCL-1 and BCL-XL levels, which likely contribute to the observed synergy. Importantly, tivantinib as single agent or in combination with ABT-199 significantly inhibited the colony forming capacity of primary patient AML bone marrow mononuclear cells. In summary, tivantinib is a novel GSK3alpha/beta inhibitor that potently kills AML cells and tivantinib single agent or combination therapy with ABT-199 may represent attractive new therapeutic opportunities for AML.

Project description:The interaction of Menin (MEN1) and MLL (MLL1, KMT2A) is a dependency and potential therapeutic opportunity against NPM1 mutant (NPM1mut) and MLL-rearranged (MLL-r) leukemias. Concomitant activating driver mutations in the gene encoding the tyrosine kinase FLT3 occur in both leukemias and are particularly common in the NPM1mut subtype. Transcriptional profiling upon pharmacological inhibition of the Menin-MLL complex revealed specific changes in gene expression with downregulation of the MEIS1 transcription factor and its transcriptional target gene FLT3 being most pronounced. Combining Menin-MLL inhibition with specific small molecule kinase inhibitors of FLT3 phosphorylation resulted in a significantly superior reduction of phosphorylated FLT3 and transcriptional suppression of genes downstream to FLT3 signaling. The drug combination induced synergistic inhibition of proliferation as well as enhanced apoptosis and differentiation compared to single-drug treatment in models of human and murine NPM1mut and MLL-r leukemias harboring an FLT3 mutation. Primary AML cells harvested from patients with NPM1mut FLT3mut AML showed significantly better responses to combined Menin and FLT3 inhibition than to single-drug or vehicle control treatment, while AML cells with wildtype NPM1, MLL, and FLT3 were not affected by any of the two drugs. In vivo treatment of leukemic animals with MLL-r FLT3mut leukemia reduced leukemia burden significantly and prolonged survival compared to the single-drug and vehicle control groups. Our data suggest that combined Menin-MLL and FLT3 inhibition represents a novel and promising therapeutic strategy for patients with NPM1mut or MLL-r leukemia and concurrent FLT3 mutation.

Project description:Homeobox (HOX) proteins and the receptor tyrosine kinase FLT3 are frequently highly expressed and mutated in acute myeloid leukemia (AML). Aberrant HOX expression is found in nearly all AMLs that harbor a mutation in the Nucleophosmin (NPM1) gene, and FLT3 is concomitantly mutated in approximately 60% of these cases. Little is known how mutant NPM1 (NPM1mut) cells maintain aberrant gene expression. Here, we demonstrate that the histone modifiers MLL1 and DOT1L control HOX and FLT3 expression and differentiation in NPM1mut AML. Using a CRISPR-Cas9 genome editing domain screen, we show NPM1mut AML to be exceptionally dependent on the menin binding site in MLL1. Pharmacological small-molecule inhibition of the menin-MLL protein interaction had profound anti-leukemic activity in human and murine models of NPM1mut AML in vitro and in vivo. Combined pharmacological inhibition of menin-MLL and DOT1L resulted in dramatic suppression of HOX and FLT3 expression, induction of differentiation, and superior activity against NPM1mut leukemia. Together, MLL1 and DOT1L are chromatin regulators that control HOX, MEIS1 and FLT3 expression and are therapeutic targets in NPM1mut AML. Combinatorial small-molecule inhibition has synergistic on target activity and constitutes a novel therapeutic concept for this common AML subtype.

Project description:MLL1 translocations encode fusion proteins retaining the N-terminus of MLL1, which interacts with the tumor suppressor, menin. This interaction is essential for leukemogenesis, thus is a promising drug target. However, wild-type MLL1 plays a critical role in sustaining hematopoietic stem cells (HSCs), therefore disruption of an essential MLL1 cofactor would be expected to obliterate normal hematopoiesis. Here we show that rather than working together as a complex, menin and MLL1 regulate distinct pathways during normal hematopoiesis, particularly in HSCs and B-cells. We demonstrate the lack of genetic interaction between menin and MLL1 in steady-state or regenerative hematopoiesis and in B-cell differentiation despite the fact that MLL1 is critical for these processes. In B-cells, menin- or MLL1-regulated genes can be classified into three categories: 1) a relatively small group of co-regulated genes including previously described targets Hoxa9 and Meis1 but also Mecom and Eya1, and much larger groups of 2) exclusively menin-regulated and 3) exclusively MLL1-regulated genes. Our results highlight the large degree of independence of these two proteins and demonstrate that menin is not a requisite cofactor for MLL1 during normal hematopoiesis. Furthermore, our data support the development of menin-MLL1 disrupting drugs as safe and selective leukemia targeting agents. We performed gene expression analysis to determine the genes deregulated in B-cell progenitors upon loss of menin. Fraction B pro-B cells (defined as B220+CD43+HSA+BP-1- BM cells) were sorted from four MenF/F and four Rag1-cre;MenF/F mice of three weeks old. Total RNA was amplified once, labeled, fragmented and hybridized to Affymerix GeneChip Mouse Genome 430 2.0 array.

Project description:Two mice in which luciferase-positive LOUCY ETP-ALL cells were xenografted were treated with either vehicle or ABT-199 (50 mg/kg) for 11 days. Afterwards, single cells suspensions were made from bone marrow and spleen of both mice for 10x Genomics scRNA-seq. Following quality control, a total of 13,681 spleen cells and 11,442 bone marrow cells of the control mouse and 15,955 spleen cells and 9,443 bone marrow cells of the ABT 199 treated mouse were processed for further analysis. Our data show that ABT-199 triggers transcriptional changes in T-cell differentiation genes in leukemic cells obtained from the spleen microenvironment. These results are in line with our previous findings that mature typical T-ALL are resistant to ABT-199.

Project description:The interaction between MLL1 And Menin controls cancer cell proliferation, migration, and tumor progression. MLL1 depletion reduced 3D cell migration in vitro and led to lesser metastatic burden and prolonged survival in vivo. Mechanistically, MLL1-Menin interaction controls actin filament assembly and protrusion generation through IL-6-pSTAT3-Arp3 axis. MLL1-Menin interaction also controls TGF-β1-mediated acto-myosin contractility via Gli2-ROCK1/2-pMLC2 axis. Additionally, MLL1-menin inhibition decreased cell proliferation via a multitude of cell-cycle related pathways. Mice bearing MLL1-depleted tumors exhibited decreased significant lung metastatic burden when sacrificed at a set tumor size, indicating that MLL1 played a role in the invasion of tumor cells in vivo. Finally, MLL1-Menin inhibition was additive with standard chemotherapeutics, both in vitro and in vivo.