T cell–derived tumor necrosis factor induces cytotoxicity by activating RIPK1-dependent target cell death
Nicholas Chun, Rosalind L. Ang, Mark Chan, Robert L. Fairchild, William M. Baldwin III, Julian K. Horwitz, Jesse D. Gelles, Jerry Edward Chipuk, Michelle A. Kelliher, Vasile I. Pavlov, Yansui Li, Dirk Homann, Peter S. Heeger, Adrian T. Ting
Nicholas Chun, Rosalind L. Ang, Mark Chan, Robert L. Fairchild, William M. Baldwin III, Julian K. Horwitz, Jesse D. Gelles, Jerry Edward Chipuk, Michelle A. Kelliher, Vasile I. Pavlov, Yansui Li, Dirk Homann, Peter S. Heeger, Adrian T. Ting
View: Text | PDF
Research Article Cell biology Immunology

T cell–derived tumor necrosis factor induces cytotoxicity by activating RIPK1-dependent target cell death

Abstract

TNF ligation of TNF receptor 1 (TNFR1) promotes either inflammation and cell survival by (a) inhibiting RIPK1’s death-signaling function and activating NF-κB or (b) causing RIPK1 to associate with the death-inducing signaling complex to initiate apoptosis or necroptosis. The cellular source of TNF that results in RIPK1-dependent cell death remains unclear. To address this, we employed in vitro systems and murine models of T cell–dependent transplant or tumor rejection in which target cell susceptibility to RIPK1-dependent cell death could be genetically altered. We show that TNF released by T cells is necessary and sufficient to activate RIPK1-dependent cell death in target cells and thereby mediate target cell cytolysis independently of T cell frequency. Activation of the RIPK1-dependent cell death program in target cells by T cell–derived TNF accelerates murine cardiac allograft rejection and synergizes with anti-PD1 administration to destroy checkpoint blockade–resistant murine melanoma. Together, the findings uncover a distinct immunological role for TNF released by cytotoxic effector T cells following cognate interactions with their antigenic targets. Manipulating T cell TNF and/or target cell susceptibility to RIPK1-dependent cell death can be exploited to either mitigate or augment T cell–dependent destruction of allografts and malignancies to improve outcomes.

Authors

Nicholas Chun, Rosalind L. Ang, Mark Chan, Robert L. Fairchild, William M. Baldwin III, Julian K. Horwitz, Jesse D. Gelles, Jerry Edward Chipuk, Michelle A. Kelliher, Vasile I. Pavlov, Yansui Li, Dirk Homann, Peter S. Heeger, Adrian T. Ting

×

Figure 2

SHARPIN-deficient allografts survive indefinitely in syngeneic and immunodeficient recipients.

Options: View larger image (or click on image) Download as PowerPoint
SHARPIN-deficient allografts survive indefinitely in syngeneic and immun...
(A) Survival of Sharpincpdm allografts subjected to 8h CIS and transplanted into syngeneic WT B6 or allogeneic BALB/c scid recipients without immunosuppression (n = 4/group) and a representative photomicrograph (inset) of H&E-stained B6 Sharpincpdm heart harvested from a BALB/c scid recipient on day 60, showing minimal mononuclear infiltration, preservation of myocyte architecture, and a normal artery (lower right). Scale bar: 25 μm. (B) Representative IHC showing statistically significant increased macrophage (Mac2, top) and neutrophil (RB6, bottom) staining of untransplanted Sharpincpdm (left) and day 6 posttransplant Sharpincpdm hearts (right) (n = 4/group and P < 0.05 for both by t test. Scale bar: 100 μm). (C) Bulk cardiac mRNA transcript qPCR ΔCt scores (TNF-18s) of naive and day 6 posttransplant Sharpincpdm allografts. No detectable TNF gene transcript was found in hearts obtained from naive mice (n = 4/group, *P < 0.05 by t test). (D) Gating strategy and representative flow plots of naive (top) and day 6 posttransplant Sharpincpdm allografts (bottom) graft infiltrating TNF-producing cells gated on the CD45+CD11b+CD11c and CD45+CD11bCD11c+ populations with quantification (right) (n = 4/group, *P < 0.05 by t test).