Targeting Cellular Metabolism in Acute Myeloid Leukemia and the Role of Patient Heterogeneity
Abstract
:1. Introduction
2. Materials and Methods
2.1. Primary Human Cells
2.1.1. Primary Human AML Cells
2.1.2. Primary Umbilical Cord Blood (UCB) Cells
2.2. Reagents
2.3. Analysis of Cell Proliferation, Viability and Constitutive Release of Mediators
2.3.1. AML Cell Proliferation
2.3.2. Cocultures of Human Mesenchymal Stem Cells (MSCs) and AML Cells
2.3.3. Viability
2.3.4. Soluble Mediator Release
2.4. Mutational Profiling, Global Gene Expression Profiling and Proteomic Analysis
2.4.1. Mutational Profiling
2.4.2. Global Gene Expression Profiling
2.4.3. Proteomic Analyses
2.5. Statistical Analyses
3. Results
3.1. Dose-Response Screening Studies of AML Cell Proliferation after Exposure to Metabolic Inhibitors
3.2. Several Metabolic Inhibitors Have Antiproliferative Effects on Primary AML Cells, with no Association with Secondary AML, AML cell Differentiation, Karyotype, FLT3 or NPM1 Mutations, or Patient Survival
3.3. Metabolic Inhibitors Have Additive Antiproliferative Effects when Combined with AraC
3.4. The Antiproliferative Effect of Metabolic Inhibitors Differs between Patients and a Subset of Patients Show Increased Susceptibility to Several Inhibitors
3.5. A Proteomic Comparison of Patient Samples Showing Either Generally Strong or Weak Antiproliferative Effects after Treatment with Metabolic Inhibitors
3.6. A Comparison of Global Gene Expression Profiles for AML Samples that Differ in Their General Susceptibility toward Metabolic Inhibitors
3.7. Metabolic Inhibitors Decrease AML Cell Viability through Proapoptotic Effects
3.8. Identification of Patient Subsets Based on Effects of Metabolic Inhibitors on AML Cell Viability
3.9. Effects of Metabolic Inhibitors on the Constitutive Release of Soluble Mediators By Primary AML Cells
3.10. 2DG Has an Antiproliferative Effect on AML Cells Even in the Presence of AML-Supporting MSCs
3.11. Dose-Response Studies of Umbilical Cord Blood Cells Treated with Metabolic Inhibitors, Effects on Proliferation and Cell Viability
3.12. Combination Treatment of Venetoclax and a Metabolic Inhibitor (2DG or 6AN) has a Stronger Antiproliferative Effect on AML Cells than Venetoclax or the Metabolic Inhibitor Alone
4. Discussion
5. Conclusions
Supplementary Materials
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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CLINICAL CHARACTERISTICS | |||||
---|---|---|---|---|---|
Gender (n) | Age (years) | ||||
Female Male | 30 51 | Median Range | 67.5 17–87 | ||
Relapse or previous hematological disease | Survival* | ||||
AML relapse MDS CMML PV Li-Fraumeni syndrome | 5 11 2 1 1 | Yes No Not relevant | 15 24 42 | ||
AML CELL DIFFERENTIATION | |||||
FAB classification | CD34 expression | ||||
M0/M1/M2 M4/M5 nd | 38 36 7 | Negative (<20%) Positive (≥20%) nd | 22 52 7 | ||
GENETIC ABNORMALITIES | |||||
Cytogenetics** | FLT3 | NPM-1 | |||
Favorable Intermediate Adverse nd | 10 48 14 9 | wt ITD TKD ITD/TKD nd | 45 22 2 3 9 | wt INS nd | 45 28 8 |
Metabolic Inhibitor | Molecular Target—Main Metabolic Pathway Affected |
---|---|
AZD3965 | Inhibits glycolysis; a selective inhibitor of monocarboxylate transporter 1 (MCT1) that regulates lactate transport across the plasma membrane. |
Metformin | Inhibits oxidative phosphorylation (OXPHOS) and fatty acid metabolism; inhibits hexokinase activity, activates AMP-activated protein kinase (AMPK) and indirectly inhibits mammalian target of rapamycin (mTOR). |
2DG | Inhibits glycolysis; inhibits the rate-limiting enzyme hexokinase. |
Lonidamine | Inhibits glycolysis and OXPHOS through multisite effects, including inhibition of hexokinase II, MCT1, the mitochondrial pyruvate carrier, the electron transport chain and alters mitochondrial permeability. |
6AN | Inhibits the pentose phosphate pathway (PPP) which is a main source of NADPH and ribose-5 phosphate. |
BPTES | Inhibits glutaminase activity, that is the conversion of glutamine to glutamate. |
ST1326 | Inhibits carnetyl palmitoyl transferase-1 (CPT-1), the rate-limiting step of fatty acid oxidation (FAO). |
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Grønningsæter, I.S.; Reikvam, H.; Aasebø, E.; Bartaula-Brevik, S.; Tvedt, T.H.; Bruserud, Ø.; Hatfield, K.J. Targeting Cellular Metabolism in Acute Myeloid Leukemia and the Role of Patient Heterogeneity. Cells 2020, 9, 1155. https://doi.org/10.3390/cells9051155
Grønningsæter IS, Reikvam H, Aasebø E, Bartaula-Brevik S, Tvedt TH, Bruserud Ø, Hatfield KJ. Targeting Cellular Metabolism in Acute Myeloid Leukemia and the Role of Patient Heterogeneity. Cells. 2020; 9(5):1155. https://doi.org/10.3390/cells9051155
Chicago/Turabian StyleGrønningsæter, Ida Sofie, Håkon Reikvam, Elise Aasebø, Sushma Bartaula-Brevik, Tor Henrik Tvedt, Øystein Bruserud, and Kimberley Joanne Hatfield. 2020. "Targeting Cellular Metabolism in Acute Myeloid Leukemia and the Role of Patient Heterogeneity" Cells 9, no. 5: 1155. https://doi.org/10.3390/cells9051155
APA StyleGrønningsæter, I. S., Reikvam, H., Aasebø, E., Bartaula-Brevik, S., Tvedt, T. H., Bruserud, Ø., & Hatfield, K. J. (2020). Targeting Cellular Metabolism in Acute Myeloid Leukemia and the Role of Patient Heterogeneity. Cells, 9(5), 1155. https://doi.org/10.3390/cells9051155