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Merck

Coenzyme A fuels T cell anti-tumor immunity.

Cell metabolism (2021-12-09)
Michael St Paul, Samuel D Saibil, SeongJun Han, Kavita Israni-Winger, Scott C Lien, Rob C Laister, Azin Sayad, Susanne Penny, Rodabe N Amaria, Lauren E Haydu, Carlos R Garcia-Batres, Meghan Kates, David T Mulder, Céline Robert-Tissot, Matthew J Gold, Charles W Tran, Alisha R Elford, Linh T Nguyen, Trevor J Pugh, Devanand M Pinto, Jennifer A Wargo, Pamela S Ohashi
RESUMEN

Metabolic programming is intricately linked to the anti-tumor properties of T cells. To study the metabolic pathways associated with increased anti-tumor T cell function, we utilized a metabolomics approach to characterize three different CD8+ T cell subsets with varying degrees of anti-tumor activity in murine models, of which IL-22-producing Tc22 cells displayed the most robust anti-tumor activity. Tc22s demonstrated upregulation of the pantothenate/coenzyme A (CoA) pathway and a requirement for oxidative phosphorylation (OXPHOS) for differentiation. Exogenous administration of CoA reprogrammed T cells to increase OXPHOS and adopt the CD8+ Tc22 phenotype independent of polarizing conditions via the transcription factors HIF-1α and the aryl hydrocarbon receptor (AhR). In murine tumor models, treatment of mice with the CoA precursor pantothenate enhanced the efficacy of anti-PDL1 antibody therapy. In patients with melanoma, pre-treatment plasma pantothenic acid levels were positively correlated with the response to anti-PD1 therapy. Collectively, our data demonstrate that pantothenate and its metabolite CoA drive T cell polarization, bioenergetics, and anti-tumor immunity.

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Sigma-Aldrich
Coenzyme A, Trilithium Salt, Coenzyme A, Trilithium Salt, CAS 18439-24-2, serves as a cofactor in enzymatic acetyl transfer reactions.