The Glucose Transporter 5 Enhances CAR-T Cell Metabolic Function and Anti-tumour Durability

Roddy S. O’Connor, Bakir Valentić, Andre Kelly, Alexander Shestov, Zhiyang Gan, Feng Shen, Adam Chatoff, Alison Jaccard, Claudia V Crispim, John Scholler, Simon Heeke, Nathaniel Snyder, S. Ghassemi, Nicholas Jones, Saar Gill
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Abstract

Abstract Activated T cells undergo a metabolic shift to aerobic glycolysis to support the energetic demands of proliferation, differentiation, and cytolytic function. Transmembrane glucose flux is facilitated by glucose transporters (GLUT) that play a vital role in T cell metabolic reprogramming and anti-tumour function. GLUT isoforms are regulated at the level of expression and subcellular distribution. GLUTs also display preferential selectivity for carbohydrate macronutrients including glucose, galactose, and fructose. GLUT5, which selectively transports fructose over glucose, has never been explored as a genetic engineering strategy to enhance CAR-T cells in fructose-rich tumour environments. Fructose levels are significantly elevated in the bone marrow and the plasma of acute myeloid leukaemia (AML) patients. Here, we demonstrate that the expression of wild-type GLUT5 restores T cell metabolic fitness in glucose-free, high fructose conditions. We find that fructose supports maximal glycolytic capacity and ATP replenishment rates in GLUT5-expressing T cells. Using steady state tracer technology, we show that 13C6 fructose supports glycolytic reprogramming and TCA anaplerosis in CAR-T cells undergoing log phase expansion. In cytotoxicity assays, GLUT5 rescues T cell cytolytic function in glucose-free medium. The fructose/GLUT5 metabolic axis also supports maximal migratory velocity, which provides mechanistic insight into why GLUT5-expressing CAR-Ts have superior effector function as they undergo “hit-and-run” serial killing. These findings translate to superior anti-tumour function in a xenograft model of AML. In fact, we found that GLUT5 enhances CAR-T cell anti-tumour function in vivo without any need for fructose intervention. Accordingly, we hypothesize that GLUT5 is sufficient to enhance CAR-T resilience by increasing the cells’ competitiveness for glucose at physiologic metabolite levels. Our findings have immediate translational relevance by providing the first evidence that GLUT5 confers a competitive edge in a fructose-enriched milieu, and is a novel approach to overcome glucose depletion in hostile tumour microenvironments (TMEs).
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葡萄糖转运体 5 能增强 CAR-T 细胞的代谢功能和抗肿瘤持久性
摘要 活化的 T 细胞在代谢过程中转向有氧糖酵解,以支持增殖、分化和细胞溶解功能的能量需求。跨膜葡萄糖通量由葡萄糖转运体(GLUT)促进,葡萄糖转运体在 T 细胞代谢重编程和抗肿瘤功能中发挥着重要作用。GLUT 同工型在表达和亚细胞分布水平上受到调控。GLUT 还对包括葡萄糖、半乳糖和果糖在内的碳水化合物主要营养素具有优先选择性。GLUT5 可选择性地转运果糖而不是葡萄糖,但它从未被作为一种基因工程策略用于在富含果糖的肿瘤环境中增强 CAR-T 细胞。急性髓性白血病(AML)患者的骨髓和血浆中果糖水平明显升高。在这里,我们证明了野生型 GLUT5 的表达可恢复 T 细胞在无葡萄糖、高果糖条件下的代谢能力。我们发现,果糖支持表达 GLUT5 的 T 细胞的最大糖酵解能力和 ATP 补充率。利用稳态示踪技术,我们发现 13C6 果糖支持对数期扩增的 CAR-T 细胞的糖酵解重编程和 TCA 失活。在细胞毒性试验中,GLUT5 能在无葡萄糖培养基中挽救 T 细胞的细胞溶解功能。果糖/GLUT5代谢轴还支持最大迁移速度,这从机理上揭示了为什么表达GLUT5的CAR-T细胞在进行 "打了就跑 "的连续杀伤时具有卓越的效应功能。这些发现转化为急性髓细胞性白血病异种移植模型中的卓越抗肿瘤功能。事实上,我们发现 GLUT5 无需果糖干预即可增强 CAR-T 细胞的体内抗肿瘤功能。因此,我们推测 GLUT5 足以通过提高细胞在生理代谢物水平上对葡萄糖的竞争性来增强 CAR-T 的恢复能力。我们的研究结果首次证明 GLUT5 在富含果糖的环境中具有竞争优势,是克服恶劣肿瘤微环境(TMEs)中葡萄糖耗竭的一种新方法,因此具有直接的转化意义。
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