The development of immunotherapies over the past decade has resulted in a paradigm shift in the treatment of cancer. However, the majority of patients do not benefit from immunotherapy, presumably owing to insufficient reprogramming of the immunosuppressive tumour microenvironment (TME) and thus limited reinvigoration of antitumour immunity. Various metabolic machineries and nutrient-sensing mechanisms orchestrate the behaviour of immune cells in response to nutrient availability in the TME. Notably, tumour-infiltrating immune cells typically experience metabolic stress as a result of the dysregulated metabolic activity of tumour cells, leading to impaired antitumour immune responses. Moreover, the immune checkpoints that are often exploited by tumour cells to evade immunosurveillance have emerging roles in modulating the metabolic and functional activity of T cells. Thus, repurposing of drugs targeting cancer metabolism might synergistically enhance immunotherapy via metabolic reprogramming of the TME. In addition, interventions targeting the metabolic circuits that impede antitumour immunity have been developed, with several clinical trials underway. Herein, we discuss how these metabolic circuits regulate antitumour immunity and the possible approaches to targeting these pathways in the context of anticancer immunotherapy. We also describe hypothetical combination treatments that could be used to better unleash the potential of adoptive cell therapies by enhancing T cell metabolism.Metabolism involves a network of biochemical reac-tions that convert nutrients into small molecules called metabolites. Through these conversions and the result-ing metabolites, cells generate the energy, redox equiv-alents and macromolecules (including proteins, lipids, DNA and RNA) that they require to survive and sustain cellular functions1. Moreover, metabolic profiles reflect the cellular state, and metabolic pathways are, there-fore, intimately entwined with cell signalling and epi-genetic networks2,3. Thus, metabolism has a central role in cellular homeostasis and adaptation in response to intracellular and extracellular stimuli. The key nutrients available to cells include glucose, amino acids and fatty acids. These nutrients are mostly converted and used in central metabolism, which consists of catabolic glycoly-sis and the tricarboxylic acid (TCA) cycle, as well as the connected anabolic pathways that provide precursors for macromolecule synthesis. Through glycolysis, glucose is broken down to pyruvate, leading to generation of the cellular energy equivalent ATP. Glucose can also enter the pentose phosphate or glycogenesis pathways for carbon storage and the production of NADPH, nucle-otide sugars and ribose-5-phosphate; in turn, these metabolites support a variety of macromolecule biosyn-thesis, antioxidant production and protein glycosylation pathways. Other glycolytic metabolites, such as glycerol-3-phosphate and 3-phosphoglycerate, can be diverted into the fatty acid and serine-glycine biosynthesis path-ways, respectiv...
