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

CD8 T cell dysfunction during chronic viral infection

Clearance of primary infection often leads to the development of highly functional memory T cells capable of rapid and long-lasting protective immunity. By contrast, chronic infections can result in T cell dysfunction and poor pathogen control. In this review, we will discuss recent work that highlights two main types of T cell dysfunction during chronic infection: exhaustion of effector functions and altered memory T cell development.

Early virus-associated bystander events affect the fitness of the CD8 T cell response to persistent virus infection

Chronic Ag exposure during persistent viral infection erodes virus-specific CD8 T cell numbers and effector function, with a concomitant loss of pathogen control. Less clear are the respective contributions of Ag-specific and Ag-nonspecific (bystander) events on the quantity, quality, and maintenance of antiviral CD8 T cells responding to persistent virus infection. In this study, we show that low-dose inoculation with mouse polyomavirus (PyV) elicits a delayed, but numerically equivalent, antiviral CD8 T cell response compared with high-dose inoculation. Low-dose infection generated virus-specific CD8 T cells endowed with multicytokine functionality and a superior per cell capacity to produce IFN-gamma. PyV-specific CD8 T cells primed by low-dose inoculation also expressed higher levels of IL-7Ralpha and bcl-2 and possessed enhanced Ag-independent survival. Importantly, the quantity and quality of the antiviral CD8 T cell response elicited by dendritic cell-mediated immunization were mitigated by infection with a mutant PyV lacking the dominant CD8 T cell viral epitope. These findings suggest that the fitness of the CD8 T cell response to persistent virus infection is programmed in large part by early virus-associated Ag-nonspecific factors, and imply that limiting bystander inflammation at the time of inoculation, independent of Ag load, may optimize adaptive immunity to persistent viral infection.

A suspenseful game of 'hide and seek' between virus and host

As part of the most important contributions to the understanding of viral immunity, Michael Oldstone recounts his pioneering work on lymphocytic choriomeningitis virus.

Nasopharyngeal carcinoma-associated Epstein-Barr virus-encoded oncogene latent membrane protein 1 potentiates regulatory T-cell function

Sequence variation in the Epstein-Barr virus (EBV) latent membrane protein 1 (LMP1) oncogene structure may affect antigen-presenting cell (APC) function of infected B cells and immune escape by EBV-specific T cells and thus contribute to the development of malignancy. Normal B cell-associated LMP1 (B-LMP1) upregulates B cell APC function through activation of the necrosis factor (NF)-kappaB subunit, RelB. We examined the ability of B-LMP1 and a nasopharyngeal carcinoma-associated LMP1 (NPC-LMP1) to modulate B cell APC function and T-cell responses. B lymphoma cells transfected with NPC-LMP1 stimulated resting T cells in mixed lymphocyte reaction less efficiently than B-LMP1 transfectants. Unexpectedly, antigen presentation to CD4(+) T helper cells was reduced owing to potentiation of regulatory T-cell function by NPC-LMP1 transfectants, which produce increased levels of interleukin-10, rendering CD4(+) T cells hyporesponsive. Thus, after primary EBV infection, T cells may escape activation by NPC-LMP1. These observations have important implications for the establishment of EBV-associated malignancy in the context of infection with tumour-associated EBV LMP1 variants.

Interleukin-10 determines viral clearance or persistence in vivo

Persistent viral infections are a major health concern. One obstacle inhibiting the clearance of persistent infections is functional inactivation of antiviral T cells. Although such immunosuppression occurs rapidly after infection, the mechanisms that induce the loss of T-cell activity and promote viral persistence are unknown. Herein we document that persistent viral infection in mice results in a significant upregulation of interleukin (IL)-10 by antigen-presenting cells, leading to impaired T-cell responses. Genetic removal of Il10 resulted in the maintenance of robust effector T-cell responses, the rapid elimination of virus and the development of antiviral memory T-cell responses. Therapeutic administration of an antibody that blocks the IL-10 receptor restored T-cell function and eliminated viral infection. Thus, we identify a single molecule that directly induces immunosuppression leading to viral persistence and demonstrate that a therapy to neutralize IL-10 results in T-cell recovery and the prevention of viral persistence.