The implementation of targeted therapies for acute myeloid leukemia has been challenged by complex mutational patterns within and across patients as well as a dearth of pharmacologic agents for most mutational events. Here, we report initial findings from the Beat AML program on a cohort of 672 tumor specimens collected from 562 patients. We assessed these specimens using whole exome sequencing, RNA-sequencing, and ex vivo drug sensitivity analyses. Our data reveal Users may view, print, copy, and download text and data-mine the content in such documents, for the purposes of academic research, subject always to the full Conditions of use:
Translating the genetic and epigenetic heterogeneity underlying human cancers into therapeutic strategies is an ongoing challenge. Large-scale sequencing efforts have uncovered a spectrum of mutations in many hematologic malignancies, including acute myeloid leukemia (AML), suggesting that combinations of agents will be required to treat these diseases effectively. Combinatorial approaches will also be critical for combating the emergence of genetically heterogeneous subclones, rescue signals in the microenvironment, and tumor-intrinsic feedback pathways that all contribute to disease relapse. To identify novel and effective drug combinations, we performed ex vivo sensitivity profiling of 122 primary patient samples from a variety of hematologic malignancies against a panel of 48 drug combinations. The combinations were designed as drug pairs that target nonoverlapping biological pathways and comprise drugs from different classes, preferably with Food and Drug Administration approval. A combination ratio (CR) was derived for each drug pair, and CRs were evaluated with respect to diagnostic categories as well as against genetic, cytogenetic, and cellular phenotypes of specimens from the two largest disease categories: AML and chronic lymphocytic leukemia (CLL). Nearly all tested combinations involving a BCL2 inhibitor showed additional benefit in patients with myeloid malignancies, whereas select combinations involving PI3K, CSF1R, or bromodomain inhibitors showed preferential benefit in lymphoid malignancies. Expanded analyses of patients with AML and CLL revealed specific patterns of ex vivo drug combination efficacy that were associated with select genetic, cytogenetic, and phenotypic disease subsets, warranting further evaluation. These findings highlight the heuristic value of an integrated functional genomic approach to the identification of novel treatment strategies for hematologic malignancies.
In many malignancies, the tumor microenvironment includes CSF1R-expressing supportive monocyte/macrophages that promote tumor cell survival. For chronic lymphocytic leukemia (CLL), these supportive monocyte/macrophages are known as nurse-like cells (NLCs), although the potential effectiveness of selective small-molecule inhibitors of CSF1R against CLL is understudied. Here, we demonstrate the preclinical activity of two inhibitors of CSF1R, GW-2580 and ARRY-382, in primary CLL patient samples. We observed at least 25% of CLL samples showed sub-micromolar sensitivity to CSF1R inhibitors. This sensitivity was observed in samples with varying genetic and clinical backgrounds, although higher white cell count and monocyte cell percentage was associated with increased sensitivity. Depleting CD14-expressing monocytes preferentially decreased viability in samples sensitive to CSF1R inhibitors, and treating samples with CSF1R inhibitors eliminated the presence of NLCs in long-term culture conditions. These results indicate that CSF1R small-molecule inhibitors target CD14-expressing monocytes in the CLL microenvironment, thereby depriving leukemia cells of extrinsic support signals. In addition, significant synergy was observed combining CSF1R inhibitors with idelalisib or ibrutinib, two current CLL therapies that disrupt tumor cell intrinsic B-cell receptor signaling. These findings support the concept of simultaneously targeting supportive NLCs and CLL cells and demonstrate the potential clinical utility of this combination.
Introduction: Monocyte/macrophage lineage cells have been reported to provide a supportive signal in a variety of neoplastic settings. Tumor-associated macrophages (TAMs) have been shown to provide microenvironmental support that maintains tumor cell viability and growth for a variety of solid tumor types, and these TAMs have been shown to depend on the receptor tyrosine kinase, CSF1R (M-CSFR). Monocyte/macrophage lineage cells have also been implicated in the microenvironment of CLL and are termed nurse-like cells in this setting. However, the role of CSF1R in CLL including potential maintenance of these nurse-like cells has not been explored. Using an ex vivo, functional screening platform applied directly to primary specimens from CLL patients, we have identified recurrent sensitivity to CSF1R inhibitors as well as decreased viability after depletion of CSF1R-expressing monocytes, thereby depriving the CLL cells of an important, microenvironmental growth/survival signal. We also have seen synergistic anti-tumor activity when combining CSF1R inhibitors with idelaisib and ibrutinib which inhibit b-cell receptor (BCR) activated pathways. Methods: We evaluated the impact on cell viability of hundreds of CLL patient specimens against panels of targeted small molecule inhibitors. These panels include two small-molecules with exquisite specificity for CSF1R (GW-2580; ARRY-382). In addition, we evaluated the impact of antibody depletion of monocytes (CD14-depletion) on ex vivo CLL cell viability as well as the effect of monocyte cell depletion on response to CSF1R inhibitors. We also evaluated the combination of GW-2580 or ARRY-382 with idelalisib (PI3kδ inhibitor) and ibrutinib (BTK inhibitor). Results: We found that 20-30% of CLL specimens showed sensitivity to inhibition of CSF1R with good concordance between GW-2580 and ARRY-382. Analysis of clinical and demographic features of these patients failed to reveal correlation of CSF1R with any prominent disease subsets. Flow cytometry analysis revealed that CSF1R was not expressed on CLL cells but only on a subpopulation of CD14-expressing monocytes. Depletion of these monocytes with CD14 antibody had little to no impact on samples not exhibiting ex vivo sensitivity to CSF1R inhibitors, however, samples showing strong sensitivity to CSF1R inhibitors were also quite sensitive to depletion of this CD14-positive monocyte population. After CD14 depletion, the remaining CLL cells showed no further sensitivity to CSF1R inhibitors. Finally, when combined with ibrutinib or idelalisib synergy was seen. Conclusions: These results show that CSF1R is a potential therapeutic target in CLL and suggest that CLL supporting monocytes (nurse-like cells) express CSF1R and depend on CSF1R for viability in a similar manner as TAMs depend on CSF1R in a variety of solid tumor settings. As such, CSF1R inhibitors may deprive CLL cells of this supportive microenvironmental signal resulting in CLL cell death. Therefore, we propose that CSF1R inhibitors, such as ARRY-382, possibly in combination with ibrutinib, idelalisib, or other approved agents, may be a promising new line of therapy to target CLL cells by impacting the tumor microenvironment. Disclosures Spurgeon: Genentech: Honoraria; Acerta Pharma: Research Funding; Bristol Meyers Squibb: Research Funding; Gilead sciences: Honoraria, Research Funding; Janssen: Research Funding; Pharmacyclics: Honoraria. Tyner:Janssen Pharmaceuticals: Research Funding; Incyte: Research Funding; Aptose Biosciences: Research Funding; Constellation Pharmaceuticals: Research Funding; Array Biopharma: Research Funding. Agarwal:CTI BioPharma: Research Funding. Lee:Array Biopharma: Employment. Chantry:Array Biopharma: Employment. Druker:Fred Hutchinson Cancer Research Center: Research Funding; Bristol-Myers Squibb: Research Funding; Henry Stewart Talks: Patents & Royalties; Millipore: Patents & Royalties; Sage Bionetworks: Research Funding; MolecularMD: Consultancy, Equity Ownership, Membership on an entity's Board of Directors or advisory committees; Gilead Sciences: Consultancy, Membership on an entity's Board of Directors or advisory committees; Cylene Pharmaceuticals: Consultancy, Equity Ownership, Membership on an entity's Board of Directors or advisory committees; AstraZeneca: Consultancy; Novartis Pharmaceuticals: Research Funding; Blueprint Medicines: Consultancy, Equity Ownership, Membership on an entity's Board of Directors or advisory committees; Oregon Health & Science University: Patents & Royalties; CTI Biosciences: Consultancy, Equity Ownership, Membership on an entity's Board of Directors or advisory committees; Leukemia & Lymphoma Society: Membership on an entity's Board of Directors or advisory committees, Research Funding; Oncotide Pharmaceuticals: Research Funding; Roche TCRC, Inc.: Consultancy, Membership on an entity's Board of Directors or advisory committees; McGraw Hill: Patents & Royalties; ARIAD: Research Funding; Aptose Therapeutics, Inc (formerly Lorus): Consultancy, Equity Ownership, Membership on an entity's Board of Directors or advisory committees.
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