Selective CD28 blockade attenuates CTLA-4–dependent CD8+ memory T cell effector function and prolongs graft survival
Danya Liu, I. Raul Badell, Mandy L. Ford
Danya Liu, I. Raul Badell, Mandy L. Ford
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Research Article Immunology Transplantation

Selective CD28 blockade attenuates CTLA-4–dependent CD8+ memory T cell effector function and prolongs graft survival

Abstract

Memory T cells pose a significant problem to successful therapeutic control of unwanted immune responses during autoimmunity and transplantation, as they are differentially controlled by cosignaling receptors such as CD28 and CTLA-4. Treatment with abatacept and belatacept impede CD28 signaling by binding to CD80 and CD86, but they also have the unintended consequence of blocking the ligands for CTLA-4, a process that may inadvertently boost effector responses. Here, we show that a potentially novel anti-CD28 domain antibody (dAb) that selectively blocks CD28 but preserves CTLA-4 coinhibition confers improved allograft survival in sensitized recipients as compared with CTLA-4 Ig. However, both CTLA-4 Ig and anti-CD28 dAb similarly and significantly reduced the accumulation of donor-reactive CD8+ memory T cells, demonstrating that regulation of the expansion of CD8+ memory T cell populations is controlled in part by CD28 signals and is not significantly impacted by CTLA-4. In contrast, selective CD28 blockade was superior to CTLA-4 Ig in inhibiting IFN-γ, TNF, and IL-2 production by CD8+ memory T cells, which in turn resulted in reduced recruitment of innate CD11b+ monocytes into allografts. Importantly, this superiority was CTLA-4 dependent, demonstrating that effector function of CD8+ memory T cells is regulated by the balance of CD28 and CTLA-4 signaling.

Authors

Danya Liu, I. Raul Badell, Mandy L. Ford

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Figure 4

CTLA-4 coinhibitory signals control CD8+ memory T cell/secondary effector cytokine secreting function.

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CTLA-4 coinhibitory signals control CD8+ memory T cell/secondary effecto...
Thy1.1+ OT-I T cells (1 × 104) were adoptively transferred into naive B6 Thy1.2 hosts and infected with Listeria-OVA to generate recipients containing memory OT-I T cells. On day 30 after infection, mice received an OVA-expressing skin graft and were treated with 200 μg CTLA-4 Ig, 100 μg anti-CD28 dAb, or 100 μg anti-CD28 dAb + 250 μg anti–CTLA-4 on days 0, 2, and 4 after transplant. Animals were sacrificed on day 5 after transplant, and splenocytes were harvested and restimulated in vitro with 10 nM SIINFEKL as described in Methods. (A) Representative flow cytometry plots of IFN-γ and IL-2 secretion from unstimulated (top row) and stimulated (bottom row) CD8+Thy1.1+ T cells. (B) Representative flow cytometry plots of IFN-γ and TNF secretion from unstimulated (top row) and stimulated (bottom row) CD8+Thy1.1+ T cells. (C–E) Frequencies (left) and absolute numbers (right) of (C) IFN-γ–, (D) IFN-γ +IL-2+–, and (E) IFN-γ+TNF+–producing CD8+ Thy1.1+ T cells. Data are representative of 3 independent experiments with a total of 10–15 mice per group. *P < 0.05 by 1-way ANOVA. dAb, domain antibody.