Mitochondrial arginase-2 is a cell‑autonomous regulator of CD8+ T cell function and antitumor efficacy
Adrià-Arnau Martí i Líndez, Isabelle Dunand-Sauthier, Mark Conti, Florian Gobet, Nicolás Núñez, J. Thomas Hannich, Howard Riezman, Roger Geiger, Alessandra Piersigilli, Kerstin Hahn, Sylvain Lemeille, Burkhard Becher, Thibaut De Smedt, Stéphanie Hugues, Walter Reith
Adrià-Arnau Martí i Líndez, Isabelle Dunand-Sauthier, Mark Conti, Florian Gobet, Nicolás Núñez, J. Thomas Hannich, Howard Riezman, Roger Geiger, Alessandra Piersigilli, Kerstin Hahn, Sylvain Lemeille, Burkhard Becher, Thibaut De Smedt, Stéphanie Hugues, Walter Reith
View: Text | PDF
Research Article Immunology Oncology

Mitochondrial arginase-2 is a cell‑autonomous regulator of CD8+ T cell function and antitumor efficacy

Abstract

As sufficient extracellular arginine is crucial for T cell function, depletion of extracellular arginine by elevated arginase 1 (Arg1) activity has emerged as a hallmark immunosuppressive mechanism. However, the potential cell-autonomous roles of arginases in T cells have remained unexplored. Here, we show that the arginase isoform expressed by T cells, the mitochondrial Arg2, is a cell-intrinsic regulator of CD8+ T cell activity. Both germline Arg2 deletion and adoptive transfer of Arg2–/– CD8+ T cells significantly reduced tumor growth in preclinical cancer models by enhancing CD8+ T cell activation, effector function, and persistence. Transcriptomic, proteomic, and high-dimensional flow cytometry characterization revealed a CD8+ T cell–intrinsic role of Arg2 in modulating T cell activation, antitumor cytoxicity, and memory formation, independently of extracellular arginine availability. Furthermore, specific deletion of Arg2 in CD8+ T cells strongly synergized with PD-1 blockade for the control of tumor growth and animal survival. These observations, coupled with the finding that pharmacologic arginase inhibition accelerates activation of ex vivo human T cells, unveil Arg2 as a potentially new therapeutic target for T cell–based cancer immunotherapies.

Authors

Adrià-Arnau Martí i Líndez, Isabelle Dunand-Sauthier, Mark Conti, Florian Gobet, Nicolás Núñez, J. Thomas Hannich, Howard Riezman, Roger Geiger, Alessandra Piersigilli, Kerstin Hahn, Sylvain Lemeille, Burkhard Becher, Thibaut De Smedt, Stéphanie Hugues, Walter Reith

×

Figure 8

Tumor growth is inhibited synergistically by PD-1 blockade and either germline or CD8+ T cell–intrinsic deletion of Arg2.

Options: View larger image (or click on image) Download as PowerPoint
Tumor growth is inhibited synergistically by PD-1 blockade and either ge...
(A–C) MC38-OVA cells were implanted s.c. into WT or Arg2–/– hosts, which were then treated with 200 μg i.p. injections of isotype control (IgG2a) or anti–PD-1 antibodies after 8, 11, and 14 days (green arrows). The results show (A) tumor growth, (B) mouse survival, and (C) tumor clearance rates at day 40 after tumor injection (n = 14–16). (D) The scheme illustrates the experimental setting used in panels E and F. WT mice were implanted with MC38-OVA cells; when tumors were palpable (after 5 days), WT or Arg2–/– OT-I cells were adoptively transferred, and mice were immunized the following day with OVA257–264 and CpG-B. Finally, the mice were treated with 200 μg i.p. injections of isotype control (IgG2a) or anti–PD-1 antibodies at days 8, 11, and 14 after T cell transfer (green arrows). Mice receiving no OT-I cells were used as controls. The results show (E) tumor growth, (F) mouse survival, and (G) tumor clearance rates at day 60 after tumor injection (n = 14–16). Isotype control data not shown in F, and in E, data were split into 2 graphs for clarity. (AF) Results were pooled from 2 independent experiments. (A and E) Statistical analysis was performed using 2-way ANOVA. (A and E) Data is represented as mean ± SEM. *P < 0.05, ***P < 0.001, and ****P < 0.0001 (A and E: 2-way ANOVA) (B and F: log-rank Mantel-Cox test) (C and G: Fisher’s exact test).