Venetoclax-based therapy can induce responses in approximately 70% of older previously untreated patients with acute myeloid leukemia (AML). However, upfront resistance as well as relapse following initial response demonstrates the need for a deeper understanding of resistance mechanisms. In the present study, we report that responses to venetoclax + azacitidine in patients with AML correlate closely with developmental stage, where phenotypically primitive AML is sensitive, but monocytic AML is more resistant. Mechanistically, resistant monocytic AML has a distinct transcriptomic profi le, loses expression of venetoclax target BCL2, and relies on MCL1 to mediate oxidative phosphorylation and survival. This differential sensitivity drives a selective process in patients which favors the outgrowth of monocytic subpopulations at relapse. Based on these fi ndings, we conclude that resistance to venetoclax + azacitidine can arise due to biological properties intrinsic to monocytic differentiation. We propose that optimal AML therapies should be designed so as to independently target AML subclones that may arise at differing stages of pathogenesis. SIGNIFICANCE: Identifying characteristics of patients who respond poorly to venetoclax-based therapy and devising alternative therapeutic strategies for such patients are important topics in AML. We show that venetoclax resistance can arise due to intrinsic molecular/metabolic properties of monocytic AML cells and that such properties can potentially be targeted with alternative strategies.
Summary: In this study we interrogated the metabolome of human acute myeloid leukemia (AML) stem cells to elucidate properties relevant to therapeutic intervention. We demonstrate that amino acid uptake, steady-state levels, and catabolism are all elevated in the leukemia stem cell (LSC) population. Furthermore, LSCs isolated from de novo AML patients are uniquely reliant on amino acid metabolism for oxidative phosphorylation and survival. Pharmacological inhibition of amino acid metabolism reduces oxidative phosphorylation and induces cell death. In contrast, LSCs obtained from relapsed AML patients are not reliant on amino acid metabolism due to their ability to compensate through increased fatty acid metabolism. These findings indicate that clinically relevant eradication of LSCs can be achieved with drugs that target LSC metabolic vulnerabilities.
AML is characterized by the presence of leukemia stem cells (LSCs), and failure to fully eradicate this population contributes to disease persistence/relapse. Prior studies have characterized metabolic vulnerabilities of LSCs, which demonstrate preferential reliance on oxidative phosphorylation (OXPHOS) for energy metabolism and survival. In the present study, using both genetic and pharmacologic strategies in primary human AML specimens, we show that signal transducer and activator of transcription 3 (STAT3) mediates OXPHOS in LSCs. STAT3 regulates AML-specific expression of MYC, which in turn controls transcription of the neutral amino acid transporter SLC1A5. We show that genetic inhibition of MYC or SLC1A5 acts to phenocopy the impairment of OXPHOS observed with STAT3 inhibition, thereby establishing this axis as a regulatory mechanism linking STAT3 to energy metabolism. Inhibition of SLC1A5 reduces intracellular levels of glutamine, glutathione and multiple TCA metabolites, leading to reduced TCA cycle activity and inhibition of OXPHOS. Based on these findings, we used a novel small molecule STAT3 inhibitor, that binds STAT3 and disrupts STAT3-DNA, to evaluate the biological role of STAT3. We show that STAT3 inhibition selectively leads to cell death in AML stem and progenitor cells derived from newly diagnosed and relapsed patients, while sparing normal hematopoietic cells. Together, these findings establish a STAT3-mediated mechanism that controls energy metabolism and survival in primitive AML cells.
Due to the disseminated nature of leukemia, malignant cells are exposed to many different tissue microenvironments, including a variety of extramedullary sites. In the present study, we demonstrate that leukemic cells residing in the liver display unique biological properties, and also contribute to systemic changes that influence physiological responses to chemotherapy. Specifically, the liver microenvironment induces metabolic adaptations via up-regulating expression of endothelial lipase (LIPG) in leukemia cells, which not only stimulates tumor cell proliferation through polyunsaturated fatty acid (PUFA) mediated pathways, but also promotes survival by stabilizing anti-apoptotic proteins. Additionally, hepatic infiltration and tissue damage caused by malignant cells induces release of liver-derived enzymes capable of degrading chemotherapy drugs, an event which further protects leukemia cells from conventional therapies. Together, these studies demonstrate a unique role for liver in modulating the pathogenesis of leukemic disease and suggest that the hepatic microenvironment may protect leukemia cells from chemotherapeutic challenge. SIGNIFICANCE The studies presented herein demonstrate that the liver provides a microenvironment in which leukemia cells acquire unique metabolic properties. The adaptations that occur in the liver confer increased resistance to chemotherapy. Therefore, we propose that therapies designed to overcome liver-specific metabolic changes will yield improved outcomes for leukemia patients. Research.
The combination of venetoclax with hypomethylating agents has resulted in highly promising clinical outcomes for acute myeloid leukemia (AML) patients. However, a subset of patients are refractory or develop resistance to venetoclax based regimens, resulting in disease recurrence. The goal of this project was to determine a mechanism to re-sensitize resistant leukemia stem cells (LSCs) to venetoclax with azacitidine (ven/aza) treatment. LSCs are the population of leukemia cells that initiate disease and are not fully eradicated by conventional treatments resulting in disease recurrence. We have previously reported that ven/aza targets LSCs in de novo AML patients by perturbing amino acid uptake resulting in decreased oxidative phosphorylation (OXPHOS). To investigate how some AML patients, develop resistance to ven/aza, we first determined if ven/aza reduced amino acid uptake in primary human AML ven/aza resistant LSCs by stable isotope labeled metabolic flux and mass spectroscopy analysis. Amino acid uptake was significantly reduced in both ven/aza sensitive and resistant LSCs upon ven/aza treatment, indicating that ven/aza is still biologically active in resistant LSCs. Next, we performed gene expression analysis from LSCs isolated from AML patients who were treated with ven/aza, responded, and then either remained in remission or progressed on ven/aza therapy. Gene set enrichment analysis revealed that fatty acid transport was enriched in LSCs isolated from patients who eventually progressed on ven/aza therapy (FDR = 0.0088) (Figure A). We then determined differences in overall fatty acid levels by lipidomics mass spectroscopy analysis in ven/aza sensitive and resistant LSCs. We observed a significant increase in abundance of 20% (6/29) of fatty acids detected in resistant LSCs. To determine if targeting fatty acid transport could re-sensitize resistant LSCs to ven/aza we knocked down genes involved in fatty acid transport including CD36, CPT1A and CPT1C in 4 ven/aza resistant AML specimens and then measured viability and colony-forming potential upon ven/aza treatment (Figure B and C). Knockdown of CD36, CPT1A, or CPT1C in combination with ven/aza treatment significantly decreased both viability and colony forming ability in each of the AML specimens. In addition, knockdown of CPT1A or CPT1C in combination with ven/aza reduced OXPHOS, a known metabolic requirement of LSCs. To perturb fatty acid transport in a therapeutically relevant manner, we treated LSCs isolated from ven/aza resistant patient specimens with a CPT1 inhibitor, etomoxir, as a single agent or in combination with ven/aza, and then measured viability and OXPHOS. The combination but not single agents reduced viability and OXPHOS, consistent with our genetic studies. To determine if ven/aza with etomoxir targeted functional LSCs we treated a primary AML specimen with etomoxir, ven/aza or the combination and measured engraftment into immune deficient mice. Combination therapy significantly reduced engraftment potential compared to ven/aza or etomoxir alone indicating that the combination of ven/aza with etomoxir decreased LSC function (Figure D). To determine if ven/aza with etomoxir could target AML cells in vivo, we treated a primary patient derived xenograft model with ven/aza, etomoxir, or the combination for 2 weeks and measured leukemic burden in the bone marrow (Figure E). The combination reduced leukemic burden more significantly than ven/aza or etomoxir alone. Finally, we measured the consequences of ven/aza, etomoxir, or the combination on normal hematopoietic stem and progenitor cells. Neither single agents nor combination therapy decreased CD34+ cell viability or colony forming ability, indicating that there may be a therapeutic window to targeting these metabolic pathways in AML without harming normal stem cells. Gene expression analysis revealed that CD36, CPT1A, and CPT1C are expressed at significantly higher levels in AML compared to HSCs, which may contribute to this therapeutic window. In conclusion, these data indicate that ven/aza resistance can be overcome by targeting fatty acid transport in LSCs. Furthermore, combining ven/aza with a CPT1 inhibitor such as etomoxir may be a clinically relevant strategy to overcoming ven/aza resistance. Figure Disclosures Pollyea: Gilead: Consultancy, Membership on an entity's Board of Directors or advisory committees; Abbvie: Consultancy, Membership on an entity's Board of Directors or advisory committees, Research Funding; Celyad: Consultancy, Membership on an entity's Board of Directors or advisory committees; Janssen: Consultancy, Membership on an entity's Board of Directors or advisory committees; Astellas: Consultancy, Membership on an entity's Board of Directors or advisory committees; Celgene: Consultancy, Membership on an entity's Board of Directors or advisory committees; Pfizer: Consultancy, Membership on an entity's Board of Directors or advisory committees, Research Funding; Forty-Seven: Consultancy, Membership on an entity's Board of Directors or advisory committees; Diachii Sankyo: Consultancy, Membership on an entity's Board of Directors or advisory committees; Takeda: Consultancy, Membership on an entity's Board of Directors or advisory committees; Agios: Consultancy, Membership on an entity's Board of Directors or advisory committees.
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