Metabolic Reprogramming of Anti-cancer T Cells: Targeting AMPK and PPAR to Optimize Cancer Immunotherapy

Cancer treatment era has been revolutionized by the novel therapeutic methods such as immunotherapy in recent years. Immunotherapy-based approaches are considered effective and reliable methods that has brought hope to eradicate certain cancers. Nonetheless, there are some issues, considered as critical obstacles in successful cancer immunotherapy. Such issues are attributed to the ability of the tumor cells in providing a tolerant microenvironment that impairs the immune responses, and help the cancer cells evade the immunogenic cell death. It has been suggested that the re-activation and maintenance of effector immune cells may become possible by metabolic reprogramming. Several signaling pathways have been noticed with the possibility of metabolic reprogramming of tumor-specific T cells, to overcome the metabolic restrictions in the tumor microenvironment; and among them, AMP-activated protein kinase (AMPK) and peroxisome proliferator-activated receptors (PPAR) have been investigated the most as the main energy sensors and regulators of mitochondrial biogenesis. The synergic effects of AMPK activators and/or PPAR agonists in cancer immunotherapy have been reported. In this review, we compare the roles of AMPK activators and PPAR agonists, and the efficacy of their combination in metabolic reprogramming of cytotoxic T cells in favoring cancer immunotherapy.