Reprogramming of antiviral T cells prevents inactivation and restores T cell activity during persistent viral infection
David G. Brooks, … , Dorian B. McGavern, Michael B.A. Oldstone
David G. Brooks, … , Dorian B. McGavern, Michael B.A. Oldstone
Published June 1, 2006
Citation Information: J Clin Invest. 2006;116(6):1675-1685. https://doi.org/10.1172/JCI26856.
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Research Article Virology

Reprogramming of antiviral T cells prevents inactivation and restores T cell activity during persistent viral infection

Abstract

Failure to clear persistent viral infections results from the early loss of T cell activity. A pertinent question is whether the immune response is programmed to fail or if nonresponsive T cells can specifically be fixed to eliminate infection. Although evidence indicates that T cell expansion is permanently programmed during the initial priming events, the mechanisms that determine the acquisition of T cell function are less clear. Herein we show that in contrast to expansion, the functional programming of T cell effector and memory responses in vivo in mice is not hardwired during priming but is alterable and responsive to continuous instruction from the antigenic environment. As a direct consequence, dysfunctional T cells can be functionally reactivated during persistent infection even after an initial program of inactivation has been instituted. We also show that early therapeutic reductions in viral replication facilitate the preservation of antiviral CD4+ T cell activity, enabling the long-term control of viral replication. Thus, dysfunctional antiviral T cells can regain activity, providing a basis for future therapeutic strategies to treat persistent viral infections.

Authors

David G. Brooks, Dorian B. McGavern, Michael B.A. Oldstone

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Figure 6

Decreasing viral replication increases CD4+ T cell stimulation and costimulatory molecule expression by APCs.

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Decreasing viral replication increases CD4+ ...
(AC) On day 9 after infection, splenocytes were isolated from mice infected with LCMV Cl 13 and either left untreated (Cl 13) or treated with ribavirin (Cl 13 + Rb). DCs (A), B cells (B), or macrophages (C) were then sorted and cultured separately with CFSE-labeled naive SMARTA, or P14 cells. No exogenous peptide was added to the cultures. Histograms show gating on SMARTA (left histograms) and P14 (right histograms) cells and illustrate CFSE dilution 3 days after culture. The number in each histogram represents the percentage of cells in each culture that divided. The MFI of the indicated costimulatory molecules on DCs (A), B cells (B), and macrophages (C) from untreated (gray bars) and ribavirin-treated (black bars) Cl 13–infected animals was determined on day 9 after infection. These data represent 2 experiments containing 4 mice per group. PD-L1, programmed death ligand; OX40L, OX40 ligand (CD134); 4-1BBL, 41BB ligand (CD137L); ICOSL, inducible costimulatory molecule ligand. *P < 0.05; **P < 0.01.