Abstract
Interleukin-15 (IL-15) is generally considered to be a regulator of T cell homeostasis because it works with other common gamma-chain cytokines like IL-2 and IL-7 to control the maintenance of naive and memory T cell populations. However, recent reports highlight new roles for IL-15 during the primary immune responses that involve promoting the survival of antigen-specific CD8+ T cells. These findings illuminate a previously unanticipated role for IL-15 in the generation and resolution of the effector CD8+ T cell response to pathogens.
Introduction and context
IL-15 plays a pivotal role in T-cell activation and effector functions, including T cell proliferation [1], interferon-γ and tumor necrosis factor-α production [2,3], chemokine production [4], and cytotoxicity [5]. In combination with other common gamma-chain cytokines, IL-15 also influences memory T cell homeostasis through the regulation of memory T cell numbers [6-8]. In this context, IL-15 drives the generation of antigen-specific memory T cells [8], promotes the survival of memory CD8+ T cells [9], and stimulates the homeostatic proliferation of memory phenotype CD8+ T cells [10-12]. Recent publications have described new roles for IL-15 in primary immune responses, where it provides a survival signal to effector CD8+ T cells during primary responses to pathogens [13,14].
Major recent advances
Recently, Sanjabi et al. [14] demonstrated that transforming growth factor-βTGF-β and IL-15 have opposing effects on the survival of the short-lived effector T cells (defined on the basis of KLRG1 [killer cell lectin-like receptor G1] and CD127 expression). Using a model system of Listeria monocytogenes infection, the authors demonstrated that TGF-β promoted apoptosis of effector CD8+ T cells whereas IL-15 promoted their survival. The opposing effects of TGF-β and IL-15 were not a result of direct inhibition of signaling in the respective signaling pathways; rather, the differential survival appeared to result from the competing effects of these pathways on the anti-apoptosis molecule Bcl-2 (B-cell lymphoma 2). Importantly, these data supported a role for IL-15 in promoting the survival of effector T cells during the contraction phase of the T-cell response to infection.
This concept was extended by McGill et al. [15], who revealed a role for IL-15 in promoting the survival of antigen-specific CD8+ T cells in the lung after influenza virus infection. Using a dendritic cell (DC) depletion/reconstitution model, their previous work had demonstrated that influenza-specific CD8+ T cell responses in the lung depended on T-cell interactions with pulmonary DCs [15]. When pulmonary DCs were depleted using clodronate-liposomes, antigen-specific CD8+ T cell responses were decreased, and the virus was not cleared as efficiently. The blunting of the CD8+ T-cell response was not due to reduced proliferation of T cells in the absence of DC signals, as DC depletion did not significantly alter the proliferation of antigen-specific CD8+ T cells responding to the infection. Instead, it appeared that the pulmonary DCs were promoting the survival of the antigen-specific T cells in the lung environment. This enhanced CD8+ T-cell survival was dependent on trans-presentation of IL-15/IL-15 receptor (IL-15R) complexes by pulmonary DCs, as blocking IL-15 or IL-15R on DCs resulted in increased CD8+ T-cell apoptosis in the lung. Together, these data support a two-hit model for promoting effective CD8+ T cell responses: a first hit in the lymph node that primes T-cell proliferation and migration to infected tissue, and a second hit that provides a survival signal to the effector T cells.
Future directions
While IL-15 has been best-appreciated for its contributions to memory T cell homeostasis, these new findings highlight the importance of IL-15 in promoting the survival of antigen-specific CD8+ T cells during primary responses to infection and suggest several areas for further investigation. First, the location of the DC-T-cell interaction that promotes the survival of the CD8+ T cells needs to be determined. One possibility is that IL-15 trans-presentation by DCs takes place in inducible bronchus-associated lymphoid tissue that develops in the lungs after infection [16]. Alternatively, the DC-T-cell interactions could take place in the lung-draining lymph node, as the pulmonary DC subsets continue to migrate to the lung-draining lymph node through day 9 post-infection [17]. Second, the importance of IL-15 for the survival of memory T cell populations during a secondary pathogen challenge needs to be examined [18,19]. Finally, the contribution of IL-15 trans-presentation to the survival of CD4+ T cells during the primary immune response to pathogens needs to be determined. In this regard, IL-15 promotes the activation of CD4+ T cells – including their cytokine production [20], CD154 expression [21], proliferation [22], and the maintenance of memory populations [23] – yet the effect of IL-15 on CD4+ T-cell survival during primary immune responses is unknown.
Manipulating T cell survival via the IL-15 pathway offers the potential for the development of novel disease therapies. One such therapeutic approach was recently reported by Wang et al. [24], who alleviated joint inflammation in a model of arthritis by targeting toxins to IL-15R-expressing cells. This report revealed the potential for elimination of immunopathogenic T cells and offers a possible therapeutic pathway to treat T-cell-mediated diseases like multiple sclerosis or type I diabetes. Alternatively, the anti-apoptotic effects of IL-15 could also be utilized to enhance survival of effector T cells. Toward this end, Hoyos et al. [25] engineered tumor-specific T cells with an IL-15 construct, which enhanced T-cell survival and resulted in improved anti-tumor effects. Together, these studies reveal the potential for therapies targeting the IL-15 pathway in the treatment of disease and reinforce a role for IL-15 in promoting the survival of effector CD8+ T cells during the immune response.
Acknowledgments
Work performed in the senior author's laboratory was supported by National Institutes of Health grants AI67967, AI76499, and T32 AI49823.
Abbreviations
- DC
dendritic cell
- IL
interleukin
- IL-15R
IL-15 receptor
- TGF-β
transforming growth factor β
Competing Interests
The authors declare that they have no competing interests.
The electronic version of this article is the complete one and can be found at: http://f1000.com/reports/b/2/67
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