PO.CL05.02 · 临床研究

Metabolically supercharged NK cells engineered with adenoviral E4ORF-1

海报缩略图:Metabolically supercharged NK cells engineered with adenoviral E4ORF-1
编号 5197 展板 15 时间 4/21 09:00–12:00 区域 Section 40 主讲 May Daher, MD
分会场 Adoptive Cell Therapy 2
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作者与单位

Maliha Munir1, Madison Moore1, Silvia Tiberti1, Rafet Basar1, Byron Jia1, Leen Kheirbek1, Nadima Uprety1, Francia Reyes Silva1, Rejeena Shrestha1, Ana K. Nunez Cortes1, Mayra Shanley1, Sunil Acharya2, Jeong-Min Park1, Bin Liu1, Pinaki Banerjee1, Paul Lin1, Donghai Xiong1, Enli Liu1, Alia Ghrayeb1, Eyal Gottlieb1, Elizabeth Joan Shpall3, Katayoun Rezvani1, May Daher1

1UT MD Anderson Cancer Center, Houston, TX,2Molecular and Cellular Oncology, UT MD Anderson Cancer Center, Houston, TX,3Professor of Medicine, Dept. of Stem Cell Transplant & Cell Therapy, UT MD Anderson Cancer Center, Houston, TX

摘要 Abstract

Background: Chimeric antigen receptor (CAR) T and natural killer (NK) cells have achieved success in hematologic malignancies but show limited efficacy in solid tumors. A major barrier is the metabolically hostile solid tumor microenvironment (TME), where hypoxia, acidosis, and nutrient deprivation impair immune cell fitness, cytotoxicity, and persistence. Current metabolic engineering strategies that enhance single nutrient uptake or target one metabolic pathway provide only partial benefit and remain vulnerable to tumor metabolic plasticity. A critical unmet need is the development of immune cells with metabolic flexibility rather than single-pathway dependence. To address this, we explored a strategy inspired by viral metabolic rewiring. During adenoviral infection, the viral protein E4ORF-1 activates PI3K-AKT signaling, stabilizes MYC, augments nutrient uptake, and enhances glycolysis, oxidative phosphorylation (OXPHOS), and fatty acid oxidation (FAO). We hypothesized that engineering E4ORF-1 into NK cells would generate a viral-like metabolic state capable of withstanding nutrient restriction in solid tumors. Methods: Metabolic characterization included mitochondrial mass and membrane potential, Seahorse assays, and SCENITH. CAR-NK cells were cocultured with solid tumor cell lines, and cytotoxicity was quantified using xCelligence and IncuCyte platforms. In vivo efficacy was tested in xenograft models of hematologic (MOLM14) and solid tumors (SKOV3). Mechanistic studies incorporated bulk RNAseq, CyTOF profiling, and CRISPR-Cas9 knockout of AMPK. Results: E4ORF-1 expression significantly enhanced NK cell antitumor function across tumor models and sustained cytotoxicity and metabolic fitness under glucose-, glutamine-, or lipid-limited conditions. Western blotting confirmed coordinated upregulation of nutrient transporters and metabolic enzymes across glycolysis, OXPHOS, and FAO. E4ORF-1 NK cells also maintained a cytotoxic advantage under targeted metabolic inhibition; despite blockade of glycolysis, OXPHOS, FAO, or glutamine metabolism, they consistently demonstrated superior tumor killing, underscoring enhanced metabolic adaptability. Transcriptomic profiling showed preserved cytokine signaling and metabolic signatures even under nutrient restriction or after tumor challenge. Mechanistic studies identified AMPK as a central metabolic integrator required for the E4ORF-1 phenotype, as CRISPR deletion of AMPK abrogated metabolic and functional advantages. Incorporation of E4ORF-1 into CAR-NK cells improved tumor control and survival in vivo. Conclusion: E4ORF-1 enhances NK cell metabolic flexibility, enabling sustained antitumor activity and improving therapeutic potential for solid tumors. These findings establish viral gene-mediated metabolic rewiring as a promising platform to strengthen CAR-NK cell fitness and overcome nutrient competition in the TME.
利益披露 Disclosure
L. Kheirbek, None.. S. Acharya, None.. A. Ghrayeb, None.. E. Gottlieb, None. M. Daher, Takeda Patent. Aurigene SAB member. Bruker Cellular Analysis Other, SAB member. CellsBin Other, SAB member.

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