Assays for profiling changes in T cell metabolism

Abstract

Abstract Immune cell therapy, including engineered T cells, engineered NK cells, and treatments to enhance native T cell response, is a rapidly advancing field of research with great promise to treat multiple diseases. However, multiple challenges, from isolating the correct cell type, determining its mode of action, manufacturing and establishing appropriate quality control criteria, must be overcome to reach its potential. In recent years, cellular energy metabolism has emerged as an important consideration for efficacy and persistence when developing cell therapies. Here we evaluate a set of bioluminescent cell-based assays for measuring rate of metabolite uptake, monitoring activity for key metabolic pathways and determining changes in intracellular metabolite levels during T cell transition from naïve to activated to memory phenotypes. Metabolite levels measured include ATP, glucose uptake, malate, branched chain amino acids, and glycogen levels. Depending on the activation state of the cells, the cells respond differently to glycolysis and oxidative phosphorylation inhibitors, as demonstrated by changes to metabolite levels. Energy storage as measured by intracellular glycogen levels also differs depending on the T cell phenotype (naïve, activated, or memory). Understanding the processes governing dynamic metabolic changes during cell modification and expansion is required for next-generation cell therapy development. The developed bioluminescent cell-based assays provide the sensitivity, throughput and robustness required for rapid evaluation of such changes.