TGF-ß receptor maintains CD4 T helper cell identity during chronic viral infections.

Suppression of CD8 and CD4 T cells is a hallmark in chronic viral infections, including hepatitis C and HIV. While multiple pathways are known to inhibit CD8 T cells, the host molecules that restrict CD4 T cell responses are less understood. Here, we used inducible and CD4 T cell-specific deletion of the gene encoding the TGF-ß receptor during chronic lymphocytic choriomeningitis virus infection in mice, and determined that TGF-ß signaling restricted proliferation and terminal differentiation of antiviral CD4 T cells. TGF-ß signaling also inhibited a cytotoxic program that includes granzymes and perforin expression at both early and late stages of infection in vivo and repressed the transcription factor eomesodermin. Overexpression of eomesodermin was sufficient to recapitulate in great part the phenotype of TGF-ß receptor-deficient CD4 T cells, while SMAD4 was necessary for CD4 T cell accumulation and differentiation. TGF-ß signaling also restricted accumulation and differentiation of CD4 T cells and reduced the expression of cytotoxic molecules in mice and humans infected with other persistent viruses. These data uncovered an eomesodermin-driven CD4 T cell program that is continuously suppressed by TGF-ß signaling. During chronic viral infection, this program limits CD4 T cell responses while maintaining CD4 T helper cell identity.

Constitutive but not inducible attenuation of transforming growth factor ß signaling increases natural killer cell responses without directly affecting dendritic cells early after persistent viral infection.

UNLABELLED: Rapid innate responses to viral encounters are crucial to shaping the outcome of infection, from viral clearance to persistence. Transforming growth factor ß (TGF-ß) is a potent immune suppressor that is upregulated early upon viral infection and maintained during chronic infections in both mice and humans. However, the role of TGF-ß signaling in regulating individual cell types in vivo is still unclear. Using infections with two different persistent viruses, murine cytomegalovirus (MCMV) and lymphocytic choriomeningitis virus (LCMV; Cl13), in their natural rodent host, we observed that TGF-ß signaling on dendritic cells (DCs) did not dampen DC maturation or cytokine production in the early stages of chronic infection with either virus in vivo. In contrast, TGF-ß signaling prior to (but not during) chronic viral infection directly restricted the natural killer (NK) cell number and effector function. This restriction likely compromised both the early control of and host survival upon MCMV infection but not the long-term control of LCMV infection. These data highlight the context and timing of TGF-ß signaling on different innate cells that contribute to the early host response, which ultimately influences the outcome of chronic viral infection in vivo. IMPORTANCE: In vivo host responses to pathogens are complex processes involving the cooperation of many different immune cells migrating to specific tissues over time, but these events cannot be replicated in vitro. Viruses causing chronic infections are able to subvert this immune response and represent a human health burden. Here we used two well-characterized viruses that are able to persist in their natural mouse host to dissect the role of the suppressive molecule TGF-ß in dampening host responses to infection in vivo. This report presents information that allows an increased understanding of long-studied TGF-ß signaling by examining its direct effect on different immune cells that are activated very early after in vivo viral infection and may aid with the development of new antiviral therapeutic strategies.

Innate and Adaptive Immune Regulation During Chronic Viral Infections.

Chronic viral infections represent a unique challenge to the infected host. Persistently replicating viruses outcompete or subvert the initial antiviral response, allowing the establishment of chronic infections that result in continuous stimulation of both the innate and adaptive immune compartments. This causes a profound reprogramming of the host immune system, including attenuation and persistent low levels of type I interferons, progressive loss (or exhaustion) of CD8(+) T cell functions, and specialization of CD4(+) T cells to produce interleukin-21 and promote antibody-mediated immunity and immune regulation. Epigenetic, transcriptional, posttranscriptional, and metabolic changes underlie this adaptation or recalibration of immune cells to the emerging new environment in order to strike an often imperfect balance between the host and the infectious pathogen. In this review we discuss the common immunological hallmarks observed across a range of different persistently replicating viruses and host species, the underlying molecular mechanisms, and the biological and clinical implications.

Plasmacytoid dendritic cells are productively infected and activated through TLR-7 early after arenavirus infection.

The antiviral response is largely mediated by dendritic cells (DCs), including conventional (c) DCs that function as antigen-presenting cells, and plasmacytoid (p) DCs that produce type I interferons, making them an attractive target for viruses. We find that the Old World arenaviruses lymphocytic choriomeningitis virus clone 13 (LCMV Cl13) and Lassa virus bind pDCs to a greater extent than cDCs. Consistently, LCMV Cl13 targets pDCs early after in vivo infection of its natural murine host and establishes a productive and robust replication cycle. pDCs coproduce type I interferons and proinflammatory cytokines, with the former being induced in both infected and uninfected pDCs, demonstrating a dissociation from intrinsic virus replication. TLR7 globally mediates pDC responses, limits pDC viral load, and promotes rapid innate and adaptive immune cell activation. These early events likely help dictate the outcome of infections with arenaviruses and other DC-replicating viruses and shed light on potential therapeutic targets.

Late interleukin-6 escalates T follicular helper cell responses and controls a chronic viral infection.

Multiple inhibitory molecules create a profoundly immunuosuppressive environment during chronic viral infections in humans and mice. Therefore, eliciting effective immunity in this context represents a challenge. Here, we report that during a murine chronic viral infection, interleukin-6 (IL-6) was produced by irradiation-resistant cells in a biphasic manner, with late IL-6 being absolutely essential for viral control. The underlying mechanism involved IL-6 signaling on virus-specific CD4 T cells that caused up-regulation of the transcription factor Bcl6 and enhanced T follicular helper cell responses at late, but not early, stages of chronic viral infection. This resulted in escalation of germinal center reactions and improved antibody responses. Our results uncover an antiviral strategy that helps to safely resolve a persistent infection in vivo.

Non-redundant function of the MEK5-ERK5 pathway in thymocyte apoptosis.

The mitogen-activated protein kinases (MAPKs) ERK1/2, p38, and JNK are thought to determine survival-versus-death fate in developing thymocytes. However, this view was challenged by studies using 'MEK1-ERK1/2-specific' pharmacological inhibitors, which block both positive and negative selection. Recently, these inhibitors were also shown to affect MEK5, an upstream activator of ERK5, another class of MAPK with homology to ERK1/2. To define the contribution of the MEK5-ERK5 pathway in T-cell development, we retrovirally expressed dominant-negative or constitutively activated form of MEK5 to inhibit or activate the MEK5-ERK5 pathway. We demonstrate that MEK5 regulates apoptosis of developing thymocytes but has no function in positive selection. ERK5 activity correlates with the levels of Nur77 family members but not that of Bim, two effector pathways of thymocyte apoptosis. These results illustrate the critical involvement of the MEK5-ERK5 pathway in thymocyte development distinct from that of ERK1/2 and highlight the importance of the MAPK network in mediating differential effects pertaining to T-cell differentiation and apoptosis.