Exp Hematol Oncol. 2026 Jul 02.
Metabolic crosstalk between cancer cells and immune cells is now recognized as a major determinant of immune escape and resistance to anticancer treatments. Cancer cells profoundly reshape the metabolic landscape of the tumor microenvironment, driving nutrient competition, hypoxia, and the accumulation of immunosuppressive oncometabolites that collectively blunt antitumor immunity. Effector T cells, NK cells, and dendritic cells are exposed to nutrient deprivation and suppressive metabolites, including lactate, adenosine, and kynurenine, resulting in impaired T cell proliferation and cytotoxic function and expansion of metabolically adapted regulatory T cells and myeloid-derived suppressor cells. Cancer-associated fibroblasts further reinforce this metabolic reprogramming through extracellular matrix remodeling, secretion of immunosuppressive metabolites, and nutrient recycling that supports tumor growth. Abnormal tumor vasculature sustains metabolic stress by causing uneven perfusion, hypoxia, and acidosis, thereby limiting immune cell infiltration, and promoting immune exhaustion. In addition, diet- and microbiome-driven metabolic cues dynamically shape cancer-immunity interactions and therapeutic responses. Targeting key metabolic checkpoints, including glycolysis, adenosine signaling, tryptophan metabolism, fatty acid oxidation, and lactate production, has emerged as a promising strategy to restore antitumor immunity. Nevertheless, metabolic heterogeneity, context-dependent immune responses, and safety concerns pose persistent challenges to its successful implementation. Recent advances in biomarker development, patient stratification, and rational combination strategies underpin the clinical translation of metabolic-immune vulnerabilities in cancer therapy. Integrating metabolic interventions with immune checkpoint blockade or adoptive cell therapies has demonstrated synergistic effects in preclinical and early clinical studies, enhancing T cell persistence and cytotoxic function within metabolically hostile tumor microenvironments. This review addresses these issues and delineates the mechanistic basis of the dynamic interplay between cancer metabolism and immune regulation. It discusses how anti-cancer therapies affect metabolic and immune pathways and highlights next-generation, metabolically targeted therapies that leverage newly uncovered, tumor-specific rewiring of glycolysis, mitochondrial function, and nutrient uptake. Special emphasis is given to the development of first-in-class inhibitors targeting glutaminase, lipid biosynthesis, one-carbon pathways, and redox homeostasis, which, when paired with immunotherapy or conventional treatments, offer unprecedented opportunities to overcome metabolic barriers, abrogate resistance, and achieve durable immune control of cancer.
Keywords: Cancer-associated fibroblasts; Diet and cancer; Immune cell metabolism; Immunotherapy; Microbiome and cancer; Oncometabolites; Therapy resistance; Tumor metabolism; Tumor microenvironment