Multipronged CD4(+) T-cell effector and memory responses cooperate to provide potent immunity against respiratory virus.

Over the last decade, the known spectrum of CD4(+) T-cell effector subsets has become much broader, and it has become clear that there are multiple dimensions by which subsets with a particular cytokine commitment can be further defined, including their stage of differentiation, their location, and, most importantly, their ability to carry out discrete functions. Here, we focus on our studies that highlight the synergy among discrete subsets, especially those defined by helper and cytotoxic function, in mediating viral protection, and on distinctions between CD4(+) T-cell effectors located in spleen, draining lymph node, and in tissue sites of infection. What emerges is a surprising multiplicity of CD4(+) T-cell functions that indicate a large arsenal of mechanisms by which CD4(+) T cells act to combat viruses.

Multiple redundant effector mechanisms of CD8+ T cells protect against influenza infection.

We have previously shown that mice challenged with a lethal dose of A/Puerto Rico/8/34-OVA(I) are protected by injection of 4-8 × 10(6) in vitro-generated Tc1 or Tc17 CD8(+) effectors. Viral load, lung damage, and loss of lung function are all reduced after transfer. Weight loss is reduced and survival increased. We sought in this study to define the mechanism of this protection. CD8(+) effectors exhibit multiple effector activities, perforin-, Fas ligand-, and TRAIL-mediated cytotoxicity, and secretion of multiple cytokines (IL-2, IL-4, IL-5, IL-9, IL-10, IL-17, IL-21, IL-22, IFN-γ, and TNF) and chemokines (CCL3, CCL4, CCL5, CXCL9, and CXCL10). Transfer of CD8(+) effectors into recipients, before infection, elicits enhanced recruitment of host neutrophils, NK cells, macrophages, and B cells. All of these events have the potential to protect against viral infections. Removal of any one, however, of these potential mechanisms was without effect on protection. Even the simultaneous removal of host T cells, host B cells, and host neutrophils combined with the elimination of perforin-mediated lytic mechanisms in the donor cells failed to reduce their ability to protect. We conclude that CD8(+) effector T cells can protect against the lethal effects of viral infection by means of a large number of redundant mechanisms.

Adoptive transfer of tumor-specific Tc17 effector T cells controls the growth of B16 melanoma in mice.

In vitro generated OVA-specific IL-17-producing CD8 T effector cells (Tc17) from OT-1 mice, adoptively transferred into B16-OVA tumor-bearing mice, controlled tumor growth in early and late stage melanoma. IL-17, TNF, and IFN-gamma from the Tc17 effectors all played a role in an enhanced recruitment of T cells, neutrophils, and macrophages to the tumor. In addition, Tc17 cells and recently recruited, activated neutrophils produced further chemokines, including CCL3, CCL4, CCL5, CXCL9, and CXCL10, responsible for the attraction of type 1 lymphocytes (Th1 and Tc1) and additional neutrophils. Neutrophils were rapidly attracted to the tumor site by an IL-17 dependent mechanism, but at later stages the induction of the chemokine CXCL2 by Tc17-derived TNF and IFN-gamma contributed to sustain neutrophil recruitment. Approximately 10-50 times as many Tc17 effectors were required compared with Tc1 effectors to exert the same level of control over tumor growth. The recruitment of neutrophils was more prominent when Tc17 rather than Tc1 were used to control tumor and depletion of neutrophils resulted in a diminished capacity to control tumor growth.

Tc17 cells are capable of mediating immunity to vaccinia virus by acquisition of a cytotoxic phenotype.

CD8 T cells can acquire cytokine-secreting phenotypes paralleling cytokine production from Th cells. IL-17-secreting CD8 T cells, termed Tc17 cells, were shown to promote inflammation and mediate immunity to influenza. However, most reports observed a lack of cytotoxic activity by Tc17 cells. In this study, we explored the anti-viral activity of Tc17 cells using a vaccinia virus (VV) infection model. Tc17 cells expanded during VV infection, and TCR transgenic Tc17 cells were capable of clearing recombinant VV infection. In vivo, adoptively transferred Tc17 cells lost the IL-17-secreting phenotype, even in the absence of stimulation, but they did not acquire IFN-gamma-secreting potential unless stimulated with a virus-encoded Ag. However, examination of cells following infection demonstrated that these cells acquired cytotoxic potential in vivo, even in the absence of IFN-gamma. Cytotoxic potential correlated with Fasl expression, and the cytotoxic activity of postinfection Tc17 cells was partially blocked by the addition of anti-FasL. Thus, Tc17 cells mediate VV clearance through expression of specific molecules associated with cytotoxicity but independent of an acquired Tc1 phenotype.

Tc17, a unique subset of CD8 T cells that can protect against lethal influenza challenge.

We show here that IL-17-secreting CD4 T (Th)17 and CD8 T (Tc)17 effector cells are found in the lung following primary challenge with influenza A and that blocking Ab to IL-17 increases weight loss and reduces survival. Tc17 effectors can be generated in vitro using naive CD8 T cells from OT-I TCR-transgenic mice. T cell numbers expand 20-fold and a majority secretes IL-17, but little IFN-gamma. Many of the IL-17-secreting cells also secrete TNF and some secrete IL-2. Tc17 are negative for granzyme B, perforin message, and cytolytic activity, in contrast to Tc1 effectors. Tc17 populations express message for orphan nuclear receptor gammat and FoxP3, but are negative for T-bet and GATA-3 transcription factors. The FoxP3-positive, IL-17-secreting and IFN-gamma-secreting cells represent three separate populations. The IFN-gamma-, granzyme B-, FoxP3-positive cells and cells positive for IL-22 come mainly from memory cells and decrease in number when generated from CD44(low) rather than unselected CD8 T cells. Cells of this unique subset of CD8 effector T cells expand greatly after transfer to naive recipients following challenge and can protect them against lethal influenza infection. Tc17 protection is accompanied by greater neutrophil influx into the lung than in Tc1-injected mice, and the protection afforded by Tc17 effectors is less perforin but more IFN-gamma dependent, implying that different mechanisms are involved.

IL-10 deficiency unleashes an influenza-specific Th17 response and enhances survival against high-dose challenge.

We examined the expression and influence of IL-10 during influenza infection. We found that IL-10 does not impact sublethal infection, heterosubtypic immunity, or the maintenance of long-lived influenza Ag depots. However, IL-10-deficient mice display dramatically increased survival compared with wild-type mice when challenged with lethal doses of virus, correlating with increased expression of several Th17-associated cytokines in the lungs of IL-10-deficient mice during the peak of infection, but not with unchecked inflammation or with increased cellular responses. Foxp3(-) CD4 T cell effectors at the site of infection represent the most abundant source of IL-10 in wild-type mice during high-dose influenza infection, and the majority of these cells coproduce IFN-gamma. Finally, compared with predominant Th1 responses in wild-type mice, virus-specific T cell responses in the absence of IL-10 display a strong Th17 component in addition to a strong Th1 response and we show that Th17-polarized CD4 T cell effectors can protect naive mice against an otherwise lethal influenza challenge and utilize unique mechanisms to do so. Our results show that IL-10 expression inhibits development of Th17 responses during influenza infection and that this is correlated with compromised protection during high-dose primary, but not secondary, challenge.

Durable CD4 T-Cell Memory Generation Depends on Persistence of High Levels of Infection at an Effector Checkpoint that Determines Multiple Fates.

We have discovered that the determination of CD4 effector and memory fates after infection is regulated not only by initial signals from antigen and pathogen recognition, but also by a second round of such signals at a checkpoint during the effector response. Signals to effectors determine their subsequent fate, inducing further progression to tissue-restricted follicular helpers, cytotoxic CD4 effectors, and long-lived memory cells. The follicular helpers help the germinal center B-cell responses that give rise to high-affinity long-lived antibody responses and memory B cells that synergize with T-cell memory to provide robust long-lived protection. We postulate that inactivated vaccines do not provide extended signals from antigen and pathogen beyond a few days, and thus elicit ineffective CD4 T- and B-cell effector responses and memory. Defining the mechanisms that underlie effective responses should provide insights necessary to develop vaccine strategies that induce more effective and durable immunity.

Heterogeneity of CD4(+) and CD8(+) T cells.

There is extensive plasticity in the T-cell response to antigen. Helper CD4(+) T cells, cytotoxic CD8(+) T cells, the progression from naïve to effector and memory T cells, and differentiation into Th1, Tc1, Th2 and Tc2 subsets have long been recognized. More recently it has become apparent that T-cell populations display additional diversity in terms of phenotype, anatomical distribution and effector function.

Vaccines against pandemic influenza.

Vaccination with live attenuated influenza A virus (LAIV) has the potential to provide protection against the more severe consequences of pandemic flu regardless of subtype. This possibility should be explored.

Effector cell-derived lymphotoxin alpha and Fas ligand, but not perforin, promote Tc1 and Tc2 effector cell-mediated tumor therapy in established pulmonary metastases.

Cytolytic CD8(+) effector cells fall into two subpopulations based on cytokine secretion. Type 1 CD8(+) T cells (Tc1) secrete IFN-gamma, whereas type 2 CD8(+) T cells (Tc2) secrete interleukin (IL)-4 and IL-5. Although both effector cell subpopulations display Fas ligand (FasL) and tumor necrosis factor (TNF), tumor lysis is predominantly perforin dependent in vitro. Using an ovalbumin-transfected B16 lung metastasis model, we show that heightened numbers of adoptively transferred ovalbumin-specific Tc1 and Tc2 cells accumulated at the tumor site by day 2 after therapy and induced tumor regression that enhanced survival in mice with pulmonary metastases. Transfer of either TNF-alpha- or perforin-deficient Tc1 or Tc2 effector cells generated from specified gene-deficient mice showed no differences in therapeutic efficiency when compared with corresponding wild-type cells. In contrast, both Tc1 and Tc2 cells, derived from either FasL or TNF-alpha/lymphotoxin (LT) alpha double knockout mice, showed that therapeutic effects were dependent, in part, on effector cell-derived FasL or LTalpha. Six days after effector cell therapy, elevated levels of activated endogenous CD8/CD44(High) and CD4/CD44(High) T cells localized and persisted at sites of tumor growth, whereas donor cell numbers concomitantly decreased. Both Tc1 and Tc2 effector cell subpopulations induced endogenous antitumor responses that were dependent, in part, on recipient-derived IFN-gamma and TNF-alpha. However, neither effector cell-mediated therapy was dependent on recipient-derived perforin, IL-4, IL-5, or nitric oxide. Collectively, tumor antigen-specific Tc1 and Tc2 effector cell-mediated therapy is initially dependent, in part, on effector cell-derived FasL or LTalpha that may subsequently potentiate endogenous recipient-derived type 1 antitumor responses dependent on TNF-alpha and IFN-gamma.

T cell responses to influenza virus infection: effector and memory cells.

New approaches to visualizing antigen-specific primary responses to influenza and the development of memory subsets in distinct sites suggest that both CD4 and CD8 T cells play complex roles in primary viral clearance and have the potential to contribute to protection from secondary infection.

Intraepithelial T-cell cytotoxicity, induced bronchus-associated lymphoid tissue, and proliferation of pneumocytes in experimental mouse models of influenza.

Immunopathologic examination of the lungs of mice with experimental influenza virus infection reveals three prominent findings. (i) There is rapidly developing perivascular (arterial) and peribronchial infiltration with T-cells and invasion of T-cells into the bronchiolar epithelium, separation of epithelial cells from each other and from the basement membrane, leading to defoliation of the bronchial epithelium. This reaction is analogous to a viral exanthema of the skin, such as measles and smallpox. This previously described but unappreciated reaction most likely is an effective way to eliminate virus-infected cells, but may contribute to acute toxicity and mortality. (ii) After this, there is formation of dense collections of lymphocytes adjacent to bronchi consisting mainly of B-cells, with a scattering of T-cells and macrophages. This is known as induced bronchial-associated lymphoid tissue (iBALT) and correlates with increased interleukin (IL)-17 in the lung. iBALT provides sites for a local immune reaction in the lung to both the original infection and related viral infections (heterologous immunity). (iii) Within the first 2-3 weeks, there is proliferation of type II pneumocytes and/or terminal bronchial epithelial cells extending from the terminal bronchioles into the adjacent alveoli, eventually leading to large zones of the lung filled with tumor-like epithelial cells with squamous metaplasia. The proliferation correlates with IL-17 and IL-22 expression, and the extent of this reaction appears to be determined by the availability of T-regulatory cells.

Memory CD4 T cell-mediated immunity against influenza A virus: more than a little helpful.

Recent observations have uncovered multiple pathways whereby CD4 T cells can contribute to protective immune responses against microbial threats. Incorporating the generation of memory CD4 T cells into vaccine strategies thus presents an attractive approach toward improving immunity against several important human pathogens, especially those against which antibody responses alone are inadequate to confer long-term immunity. Here, we review how memory CD4 T cells provide protection against influenza viruses. We discuss the complexities of protective memory CD4 T cell responses observed in animal models and the potential challenges of translating these observations into the clinic. Specifically, we concentrate on how better understanding of organ-specific heterogeneity of responding cells and defining multiple correlates of protection might improve vaccine-generated memory CD4 T cells to better protect against seasonal, and more importantly, pandemic influenza.

Memory CD4+ T cells protect against influenza through multiple synergizing mechanisms.

Memory CD4+ T cells combat viral infection and contribute to protective immune responses through multiple mechanisms, but how these pathways interact is unclear. We found that several pathways involving memory CD4+ T cells act together to effectively clear influenza A virus (IAV) in otherwise unprimed mice. Memory CD4+ T cell protection was enhanced through synergy with naive B cells or CD8+ T cells and maximized when both were present. However, memory CD4+ T cells protected against lower viral doses independently of other lymphocytes through production of IFN-γ. Moreover, memory CD4+ T cells selected for epitope-specific viral escape mutants via a perforin-dependent pathway. By deconstructing protective immunity mediated by memory CD4+ T cells, we demonstrated that this population simultaneously acts through multiple pathways to provide a high level of protection that ensures eradication of rapidly mutating pathogens such as IAV. This redundancy indicates the need for reductionist approaches for delineating the individual mechanisms of protection mediated by memory CD4+ T cells responding to pathogens.

Memory CD4+ T cells induce innate responses independently of pathogen.

Inflammation induced by recognition of pathogen-associated molecular patterns markedly affects subsequent adaptive responses. We asked whether the adaptive immune system can also affect the character and magnitude of innate inflammatory responses. We found that the response of memory, but not naive, CD4(+) T cells enhances production of multiple innate inflammatory cytokines and chemokines (IICs) in the lung and that, during influenza infection, this leads to early control of virus. Memory CD4(+) T cell-induced IICs and viral control require cognate antigen recognition and are optimal when memory cells are either T helper type 1 (T(H)1) or T(H)17 polarized but are independent of interferon-gamma (IFN-gamma) and tumor necrosis factor-alpha (TNF-alpha) production and do not require activation of conserved pathogen recognition pathways. This represents a previously undescribed mechanism by which memory CD4(+) T cells induce an early innate response that enhances immune protection against pathogens.

Priming with cold-adapted influenza A does not prevent infection but elicits long-lived protection against supralethal challenge with heterosubtypic virus.

We show in this study several novel features of T cell-based heterosubtypic immunity against the influenza A virus in mice. First, T cell-mediated heterosubtypic protection against lethal challenge can be generated by a very low priming dose. Second, it becomes effective within 5-6 days. Third, it provides protection against a very high dose challenge for >70 days. Also novel is the finding that strong, long-lasting, heterosubtypic protection can be elicited by priming with attenuated cold-adapted strains. We demonstrate that priming does not prevent infection of the lungs following challenge, but leads to earlier clearance of the virus and 100% survival after otherwise lethal challenge. Protection is dependent on CD8 T cells, and we show that CD4 and CD8 T cells reactive to conserved epitopes of the core proteins of the challenge virus are present after priming. Our results suggest that intranasal vaccination with cold-adapted, attenuated live virus has the potential to provide effective emergency protection against emerging influenza strains for several months.

IFN-gamma regulates donor CD8 T cell expansion, migration, and leads to apoptosis of cells of a solid tumor.

We previously reported that IFN-gamma secreted by donor cytotoxic T cell 1 (Tc1) cells was the most important factor in promoting EG7 (an OVA transfection the EL4 thymoma) rejection in mice. In this study, we show that the ability of the host to respond to Tc1-secreted IFN-gamma is critical for promoting acute tumor rejection, while host production of IFN-gamma is not important. CFSE-labeled wild-type and IFN-gamma-deficient Tc1 cells divide rapidly in secondary lymphoid organs, indicating no defect in rate of cell division. However, wild-type Tc1 cells accumulate to significantly greater numbers in the tumor than deficient Tc1 cells. Hosts injected with wild-type Tc1 effectors had more T cells within the tumor at day 4, had higher levels of MCP-1, IFN-gamma-inducible protein-10, MIP-1alpha, and MIP-1beta mRNA transcripts, had greater numbers of CD11b+ and Gr-1+ cells within the tumor, and had massive regions of tumor cell apoptosis as compared with IFN-gamma knockout Tc1 cell-treated hosts. NO has a cytostatic effect on EG7 growth in vitro, and NO is important for tumor eradication by day 22. These observations are compatible with a model in which the donor CD8 Tc1 effectors expand rapidly in the host, migrate to the tumor site, and induce the secretion of a number of chemokines that in turn recruit host cells that then attack the tumor.

The immune system provides a strong response to even a low exposure to virus.

How influenza virus dose affects the size of the immune response has not been clearly documented. Mice were challenged with three doses of influenza virus spanning a 100-fold range. Increasing the viral input dose increased the degree of weight loss observed, the clinical score and eventual mortality. Maximum viral loads increased with viral input and lower doses peaked and declined earlier. The level of the immune response only varied 2-fold and was independent of viral dose with near maximal responses elicited by the lowest dose, as measured by influx of antigen-specific and non-specific leukocytes into the lungs and by influenza antibody titers. We conclude that a strong immune response is mounted to a small dose of virus and curbs the spread of virus early and prevents weight loss whereas larger doses of virus elicit a slightly greater response but the associated disease can overwhelm the host.

Uneven distribution of MHC class II epitopes within the influenza virus.

The identification of T cell epitopes is crucial for the understanding of the host immune response during infection. While much is known about the MHC class I-restricted response following influenza virus infection of C57BL/6 mice, with over 16 CD8 epitopes identified to date, less is known about the MHC class II-restricted response. Currently, only a few I-A(b)-restricted T helper epitopes have been identified. Therefore, several important questions remain about how many class II epitopes exist in this system and whether these epitopes are evenly distributed within the most abundant viral proteins. In order to address these questions, we analyzed the repertoire of epitopes that drive the CD4+ approximately 20-30 epitopes drive the CD4 T cell response and that the majority of these peptides are derived from the NP and HA proteins. We were also able to demonstrate that vaccination with one of the newly identified epitopes, HA(211-225)/A(b), resulted in increased epitope-specific T cell numbers and a significant reduction in viral titers following influenza virus challenge.