Modulating the polyamine/hypusine axis controls generation of CD8+ tissue-resident memory T cells
Aya G. Elmarsafawi, Rebecca S. Hesterberg, Mario R. Fernandez, Chunying Yang, Lancia N.F. Darville, Min Liu, John M. Koomen, Otto Phanstiel IV, Reginald Atkins, John E. Mullinax, Shari A. Pilon-Thomas, Frederick L. Locke, Pearlie K. Epling-Burnette, John L. Cleveland
Aya G. Elmarsafawi, Rebecca S. Hesterberg, Mario R. Fernandez, Chunying Yang, Lancia N.F. Darville, Min Liu, John M. Koomen, Otto Phanstiel IV, Reginald Atkins, John E. Mullinax, Shari A. Pilon-Thomas, Frederick L. Locke, Pearlie K. Epling-Burnette, John L. Cleveland
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Research Article Immunology Metabolism

Modulating the polyamine/hypusine axis controls generation of CD8+ tissue-resident memory T cells

Abstract

Glutaminolysis is a hallmark of the activation and metabolic reprogramming of T cells. Isotopic tracer analyses of antigen-activated effector CD8+ T cells revealed that glutamine is the principal carbon source for the biosynthesis of polyamines putrescine, spermidine, and spermine. These metabolites play critical roles in activation-induced T cell proliferation, as well as for the production of hypusine, which is derived from spermidine and is covalently linked to the translation elongation factor eukaryotic translation initiation factor 5A (eIF5A). Here, we demonstrated that the glutamine/polyamine/hypusine axis controlled the expression of CD69, an important regulator of tissue-resident memory T cells (Trm). Inhibition of this circuit augmented the development of Trm cells ex vivo and in vivo in the BM, a well-established niche for Trm cells. Furthermore, blocking the polyamine/hypusine axis augmented CD69 expression as well as IFN-γ and TNF-α production in (a) human CD8+ T cells from peripheral blood and sarcoma tumor infiltrating lymphocytes and (b) human CD8+ CAR-T cells. Collectively, these findings support the notion that the polyamine-hypusine circuit can be exploited to modulate Trm cells for therapeutic benefit.

Authors

Aya G. Elmarsafawi, Rebecca S. Hesterberg, Mario R. Fernandez, Chunying Yang, Lancia N.F. Darville, Min Liu, John M. Koomen, Otto Phanstiel IV, Reginald Atkins, John E. Mullinax, Shari A. Pilon-Thomas, Frederick L. Locke, Pearlie K. Epling-Burnette, John L. Cleveland

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Figure 2

The glutamine-polyamine pathway controls CD69 expression in activated mouse CD8+ T cells.

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The glutamine-polyamine pathway controls CD69 expression in activated mo...
(A) CD69 MFI in CD8+ OT-I T cells at 24, 48, and 72 hours after activation in replete versus glutamine-deficient media (n = 3). (B and C) CD69 MFI in activated polyclonal CD4+ T cells (B) and CD8+ T cells, respectively (n = 3) (C). (D) CD69 MFI in purified CD8+ T cells at 24, 48, and 72 hours after activation (n = 3), in replete versus glutamine-deficient media. Ctrl, control complete RPMI media with 2 mM glutamine; –Gln, Glutamine-deficient media. (E) CD69 MFI in CD8+ T cells cultured in media having the indicated concentrations of glutamine (0, 0.2, 0.5, 1, and 2 mM) 72 hours after activation. US, unstimulated. (F) Schematic of the metabolic network connecting glutamine to the polyamine pathway. (G) CD69 MFI in CD8+ T cells cultured in replete media (denoted as C) or in glutamine-deficient media treated with the indicated concentrations of DM-KG (0.5, 1, and 2 mM) 72 hours after activation. (H) CD69 MFI in CD8+ T cells cultured in replete media (denoted as C) or in glutamine-deficient media ± 2 mM DM-KG, 1 mM ornithine, 500 μM putrescine (Put), or 100 μM spermidine (Spd). Data in AD were analyzed using 2-way ANOVA with Dunnett’s multiple-comparison test. Data in E, G, and H were analyzed by 1-way ANOVA and Dunnett’s multiple-comparison test. In AD and H, each dot represents a biological replicate, and data are shown as mean ± SEM. In E and G, each dot represents a technical replicate, and data are shown as mean ± SD. *P < 0.05; **P < 0.01; ***P < 0.001; ****P < 0.0001.