Early effector T cells producing significant IFN-gamma develop into memory

Currently, transition of T cells from effector to memory is believed to occur as a consequence of exposure to residual suboptimal Ag found in lymphoid tissues at the waning end of the effector phase and microbial clearance. This led to the interpretation that memory arises from slightly activated late effectors producing reduced amounts of IFN-gamma. In this study, we show that CD4 T cells from the early stage of the effector phase in which both the Ag and activation are optimal also transit to memory. Moreover, early effector T cells that have undergone four divisions expressed significant IL-7R, produced IFN-gamma, and yielded rapid and robust memory responses. Cells that divided three times that had marginal IL-7R expression and no IFN-gamma raised base level homeostatic memory, whereas those that have undergone only two divisions and produced IFN-gamma yielded conditioned memory despite low IL-7R expression. Thus, highly activated early effectors generated under short exposure to optimal Ag in vivo develop into memory, and such transition is dependent on a significant production of the cell's signature cytokine, IFN-gamma.     

CD4+ T cell subsets. Lymphokine secretion of memory cells and of effector cells that develop from precursors in vitro

We have studied the properties of several developmentally defined subpopulations of CD4+ T cells from normal animals which can be stimulated to secrete lymphokines. We find that the Th cells responsible for direct secretion of lymphokines after stimulation are from a resting, very long lived subpopulation of CD4+ T cells which persists for over 25 wk after adult thymectomy. These T cells are depleted by in vivo administration of antithymocyte serum and they are enriched among T cells which express high levels of Pgp-1. This phenotype suggests that the T cells responsible are most likely memory T cells which have resulted from antigen exposure in vivo. T cells in this subset secrete predominantly IL-2 with small quantities of IL-3, granulocyte/macrophage CSF, and IFN-gamma. In contrast, the CD4+ T cells which require in vitro culture and restimulation before they develop into an effector population with the ability to secrete lymphokines after restimulation, differ dramatically by most of these criteria. The precursors we study are resting Th cells which are considerably shorter lived after adult thymectomy (5 to 10 wk) and resistant to the same doses of antithymocyte serum which deplete the putative memory population. We hypothesize that this precursor population represents naive helper cells which have not yet encountered Ag. The effectors derived from such precursors can be stimulated to secrete high levels of both Th cell types 1 and 2 lymphokines (IFN-gamma, IL-4, IL-5, granulocyte/macrophage CSF, and IL-3). Generation of effectors requires proliferation and differentiation events which occur during a mandatory culture with lymphokines and antigen presenting cells for 3 to 4 days. We discuss the striking phenotypic and functional differences among these subpopulations of helper cells--the precursor population and the two types--memory and cultured effector Th which secrete lymphokines. We also discuss the relationship of these populations to CD4+ T cell subsets defined by other studies of patterns of lymphokine secretion and by cell surface phenotype.     

Effector CD4 T cells are biochemically distinct from the memory subset: evidence for long-term persistence of effectors in vivo.

Memory T cell responses are believed to be mediated by long-lived memory T cells that arise directly from a subset of short-lived, activated effector T cells that have reverted to the resting state. Although widely accepted, definitive proof that memory T cells arise from effectors is lacking because of the inability to reliably distinguish these subsets based on known phenotypic or functional parameters. We have used a biochemical approach to distinguish effector and memory CD4 T cell subsets and follow the differentiative fate of effector cells in vivo. When examined biochemically, effector and memory CD4 T cells are strikingly distinct and exhibit qualitative and quantitative differences in tyrosine phosphorylation. These effector-specific patterns were identical in effectors derived either from naive CD4 T cells (primary effectors) or memory CD4 T cells (memory effectors). To monitor the fate of effector cells in vivo, Ag-activated CD4+ TCR-transgenic T cells were transferred into irradiated BALB/c mice. These TCR-transgenic CD4 T cells persisted in adoptive hosts for several months, gave a recall response to Ag, yet exhibited effector-specific biochemical profiles. These results suggest that a subset of effector CD4 T cells can persist in vivo and contribute to long-term immunity by mediating secondary immune responses.     

Antigen Experience Shapes Phenotype and Function of Memory Th1 Cells

Primary and secondary (boosted) memory CD8 T cells exhibit differences in gene expression, phenotype and function. The impact of repeated antigen stimulations on memory CD4 T cells is largely unknown. To address this issue, we utilized LCMV and Listeria monocytogenes infection of mice to characterize primary and secondary antigen (Ag)-specific Th1 CD4 T cell responses. Ag-specific primary memory CD4 T cells display a CD62L^loCCR7^hi CD27^hi CD127^hi phenotype and are polyfunctional (most produce IFNγ, TNFα and IL-2). Following homologous prime-boost immunization we observed pathogen-specific differences in the rate of CD62L and CCR7 upregulation on memory CD4 T cells as well as in IL-2+IFNγco-production by secondary effectors. Phenotypic and functional plasticity of memory Th1 cells was observed following heterologous prime-boost immunization, wherein secondary memory CD4 T cells acquired phenotypic and functional characteristics dictated by the boosting agent rather than the primary immunizing agent. Our data also demonstrate that secondary memory Th1 cells accelerated neutralizing Ab formation in response to LCMV infection, suggesting enhanced capacity of this population to provide quality help for antibody production. Collectively these data have important implications for prime-boost vaccination strategies that seek to enhance protective immune responses mediated by Th1 CD4 T cell responses.     

Qualitative changes accompany memory T cell generation: faster, more effective responses at lower doses of antigen

The generation of memory T cells is critically important for rapid clearance and neutralization of pathogens encountered previously by the immune system. We have studied the kinetics of response and Ag dose requirements for proliferation and cytokine secretion of CD4+ memory T cells to examine whether there are qualitative changes which might lead to improved immunity. TCR Tg CD4+ T cells were primed in vitro and transferred into T cell-deficient hosts. After 6 or more weeks, the persisting T cells were exclusively small resting cells with a memory phenotype: CD44high CD62L+/- CD25-. Memory CD4 T cells showed a similar pattern of response as naive cells to peptide analogues with similar Ag dose requirements for IL-2 secretion. However, memory cells (derived from both Th2 and Th1 effectors) displayed faster kinetics of cytokine secretion, cell division, and proliferation, enhanced proliferation in response to low doses of Ag or peptide analogues, and production of IL-4, IL-5, and IFN-gamma. These results suggest there is a much more efficient response of CD4 memory T cells to Ag re-exposure and that the expanded functional capacity of memory cells will promote a rapid development of effector functions, providing more rapid and effective immunity.     

Stimulation by soluble CD70 promotes strong primary and secondary CD8+ cytotoxic T cell responses in vivo

Identification of the signals required for optimal differentiation of naive CD8(+) T cells into effector and memory cells is critical for the design of effective vaccines. In this study we demonstrate that CD27 stimulation by soluble CD70 considerably enhances the magnitude and quality of the CD8(+) T cell response. Stimulation with soluble CD70 in the presence of Ag significantly enhanced the proliferation of CD8(+) T cells and their ability to produce IL-2 and IFN-gamma in vitro. Administration of Ag and soluble CD70 resulted in a massive (>300-fold) expansion of Ag-specific CD8(+) T cells in vivo, which was due to the enhanced proliferation and survival of activated T cells. In mice that received Ag and soluble CD70, CD8(+) T cells developed into effectors with direct ex vivo cytotoxicity. Furthermore, unlike peptide immunization, which resulted in a diminished response after rechallenge, CD27 stimulation during the primary challenge evoked a strong secondary response upon rechallenge with the antigenic peptide. Thus, in addition to increasing the frequency of primed Ag-specific T cells, CD27 signaling during the primary response instills a program of differentiation that allows CD8(+) T cells to overcome a state of unresponsiveness. Taken together these results demonstrate that soluble CD70 has potent in vivo adjuvant effects for CD8(+) T cell responses.     

OX40 signals during priming on dendritic cells inhibit CD4 T cell proliferation: IL-4 switches off OX40 signals enabling rapid proliferation of Th2 effectors

In this study we examined the role and regulation of OX40 signals during CD4 T cell priming on dendritic cells (DCs). Contrary to expectation, OX40-deficient cells proliferated more rapidly than their normal counterparts, particularly when stimulated with peptide in the absence of added cytokines. This proliferative advantage was not apparent for Th2-differentiated cells. When the reasons for this were investigated, we found that the cytokine IL-4 specifically down-regulated expression of OX40 ligand on T, B, and DCs, but not on the CD4(+)CD3(-) cells linked with selection of Th2 cells into the memory compartment. OX40 ligand expression was also down-regulated on rapidly proliferating Th1 effectors. These data are compatible with OX40 signals acting during priming as a check on naive T cell proliferation while T cells integrate additional DC signals. This would serve to limit inappropriate T cell responses. In contrast, OX40 signals from CD4(+)CD3(-) cells located in the outer T zone select proliferating Th2 effectors into the memory T cell pool.     

The central memory CD4+ T cell population generated during Leishmania major infection requires IL-12 to produce IFN-gamma

Central memory CD4(+) T cells provide a pool of lymph node-homing, Ag-experienced cells that are capable of responding rapidly after a secondary infection. We have previously described a population of central memory CD4(+) T cells in Leishmania major-infected mice that were capable of mediating immunity to a secondary infection. In this study, we show that the Leishmania-specific central memory CD4(+) T cells require IL-12 to produce IFN-gamma, demonstrating that this population needs additional signals to develop into Th1 cells. In contrast, effector cells isolated from immune mice produced IFN-gamma in vitro or in vivo in the absence of IL-12. In addition, we found that when central memory CD4(+) T cells were adoptively transferred into IL-12-deficient hosts, many of the cells became IL-4 producers. These studies indicate that the central memory CD4(+) T cell population generated during L. major infection is capable of developing into either Th1 or Th2 effectors. Thus, continued IL-12 production may be required to ensure the development of Th1 cells from this central memory T cell pool, a finding that has direct relevance to the design of vaccines dependent upon central memory CD4(+) T cells.     

Duration of antigen availability influences the expansion and memory differentiation of T cells

The initial engagement of the TCR through interaction with cognate peptide-MHC is a requisite for T cell activation and confers Ag specificity. Although this is a key event in T cell activation, the duration of these interactions may affect the proliferative capacity and differentiation of the activated cells. In this study, we developed a system to evaluate the temporal requirements for antigenic stimulation during an immune response in vivo. Using Abs that target specific Ags in the context of MHC, we were able to manipulate the duration of Ag availability to both CD4 and CD8 T cells during an active infection. During the primary immune response, the magnitude of the CD4 and CD8 T cell response was dependent on the duration of Ag availability. Both CD4 and CD8 T cells required sustained antigenic stimulation for maximal expansion. Memory cell differentiation was also dependent on the duration of Ag exposure, albeit to a lesser extent. However, memory development did not correlate with the magnitude of the primary response, suggesting that the requirements for continued expansion of T cells and memory differentiation are distinct. Finally, a shortened period of Ag exposure was sufficient to achieve optimal expansion of both CD4 and CD8 T cells during a recall response. It was also revealed that limiting exposure to Ag late during the response may enhance the CD4 T cell memory pool. Collectively, these data indicated that Ag remains a critical component of the T cell response after the initial APC-T cell interaction.     

Fully functional memory CD8 T cells in the absence of CD4 T cells

The role of CD4 T cells in providing help to CD8 T cells in primary and secondary responses to infection remains controversial. Using recombinant strains of virus and bacteria expressing the same Ag, we determined the requirement for CD4 T cells in endogenous CD8 T cell responses to infection with vesicular stomatitis virus and Listeria monocytogenes (LM). Depletion of CD4 T cells had no effect on the frequency of primary or secondary vesicular stomatitis virus-specific CD8 T cells in either lymphoid or nonlymphoid tissues. In contrast, the primary LM-specific CD8 T cell response was CD4 T cell dependent. Surprisingly, the LM-specific CD8 T cell recall response was also CD4 T cell dependent, which correlated with a requirement for CD40/CD40L interactions. However, concomitant inhibition of CD40L and CD4 T cell removal revealed that these pathways may be operating independently. Importantly, despite the absence of CD4 T cells during the recall response or throughout the entire response, CD8 memory T cells were functional effectors and proliferated equivalently to their "helped" counterparts. These data call into question the contention that CD4 T cells condition memory CD8 T cells during the primary response and indicate that the principal role of CD4 T cells in generating CD8 memory cells after infection is augmentation of proliferation or survival through costimulatory signals.     

Selective delivery of augmented IL-2 receptor signals to responding CD8+ T cells increases the size of the acute antiviral response and of the resulting memory T cell pool

CD8(+) T cells respond to IL-2 produced both endogenously and by CD4(+) Th during an antiviral response. However, IL-2R signals can potentially promote CD8(+) T cell death as well as proliferation, making it unclear whether IL-2R signals provide a predominantly positive or negative effect upon CD8(+) T cell responses to viral infection. To more precisely define the direct role of IL-2R signaling on CD8(+) T cells during the response to a virus, we examined the effect of delivering augmented IL-2R signals selectively to CD8(+) T cells responding to lymphocytic choriomeningitis virus infection. Although naive CD8(+) T cells are competent to produce IL-2, CD8(+) T cells lose this capacity upon differentiation into effector CD8(+) T cells. However, effector CD8(+) T cells do retain the capacity to produce GM-CSF upon Ag stimulation. Thus, to deliver enhanced autocrine IL-2R signals to CD8(+) T cells, we established a transgenic mouse strain expressing a chimeric GM-CSF/IL-2R (GMIL2R). As GM-CSF production is Ag dependent, the GMIL2R delivers an augmented IL-2R signal exclusively to CD8(+) T cells responding to Ag. Following lymphocytic choriomeningitis virus infection, GMIL2R transgenic mice exhibited an increase in both the peak CD8(+) T cell response achieved and the size of the resulting memory pool established. Upon secondary viral challenge, the GMIL2R also enhanced the proliferative response of memory CD8(+) T cells. Thus, our findings indicate that IL-2 delivery to responding CD8(+) T cells is a limiting factor in both the acute and memory antiviral responses.     

Inhibition of terminal differentiation of B cells mediated by CD27 and CD40 involves signaling through JNK

B cells responding to cognate Ag in vivo undergo clonal expansion that is followed by differentiation into Ab-secreting plasma cells or into quiescent restimulable memory. Both these events occur in the germinal center and require that cells exit from proliferation, but the signals that lead to one or the other of these mutually exclusive differentiation pathways have not been definitively characterized. Previous experiments have shown that signals transduced through the TNFRs CD27 and CD40 at the time of B cell stimulation in vitro or in vivo can influence this cell fate decision by inhibiting terminal differentiation and promoting memory. In this study, we show that the PIQED domain of the cytoplasmic tail of murine CD27 and the adapter molecule TNFR-associated factor 2 are involved in this effect. Using pharmacological inhibitors of signaling intermediates, we identify JNK as being necessary and sufficient for the observed inhibition of terminal differentiation. While JNK is involved downstream of CD40, inhibition of the MEK pathway can also partially restore plasma cell generation, indicating that both signaling intermediates may be involved. We also show that inhibition of induction of IFN regulatory factor 4 and B lymphocyte induced maturation protein 1 are downstream events common to both receptors.     

CD40 on APCs is needed for optimal programming, maintenance, and recall of CD8+ T cell memory even in the absence of CD4+ T cell help

CD40 stimulation is one of the many signals that can activate APCs and we have recently shown it to have a unique function in generating maximum primary CD8(+) T cell responses. However, whether CD40 signaling plays a role in memory CD8(+) T cell responses is still not completely understood. In this study, we show that in the absence of CD40 on all APCs or specifically on dendritic cells, memory CD8(+) T cells are generated but at significantly reduced levels. This reduction is due to a contribution of CD40 at several different steps in the generation of CD8(+) memory. In the initial T cell response, CD40 contributes to maximizing not only the number of effector cells that are generated but also the programming of ones that will differentiate into memory. Subsequently, CD40 is needed to maintain maximal numbers of the committed memory cells in a manner that is independent of the immunizing Ag. Finally, when memory CD8(+) T cells are reactivated there is a variable requirement for CD40 depending on whether CD40 or CD4(+) Th cells were present during the primary response. Therefore, CD40 signaling on APCs plays an important role in all phases of a memory CD8(+) T cell response.     

Ex vivo IL-1 receptor type I expression in human CD4+ T cells identifies an early intermediate in the differentiation of Th17 from FOXP3+ naive regulatory T cells

IL-17-producing CD4(+) Th (Th17) cells are a unique subset of proinflammatory cells expressing the retinoic acid-related orphan receptor γt and associated with different forms of inflammatory autoimmune pathologies. The development of Th17 cells, mediated by TGF-β and IL-1, is closely related to that of FOXP3(+) suppressor/regulatory T cells (Treg). In this study, we report that ex vivo expression of IL-1RI in human circulating CD4(+) T cells identifies a subpopulation of FOXP3(+) Treg that coexpress retinoic acid-related orphan receptor γt, secrete IL-17, and are highly enriched among CCR7(+) central memory cells. Consistent with the concept that IL-1RI expression in Treg identifies a subpopulation at an early stage of differentiation, we show that, in Th17 populations differentiated in vitro from natural naive FOXP3(+) Treg, IL-1RI(+) IL-17-secreting cells are central memory cells, whereas IL-1RI(-) cells secreting IL-17 are effector memory cells. Together with the absence of detectable IL-1RI and IL-17 expression in resting naive CD4(+) T cells, these data identify circulating CCR7(+) Treg expressing IL-1RI ex vivo as early intermediates along an IL-1-controlled differentiation pathway leading from naive FOXP3(+) Treg to Th17 effectors. We further show that, whereas IL-1RI(+) central memory Treg respond to stimulation in the presence of IL-1 by generating IL-17-secreting effectors, a significant fraction of them maintain FOXP3 expression, consistent with an important role of this population in maintaining the Treg/Th17 memory pool in vivo.     

IFN-gamma mediates the death of Th1 cells in a paracrine manner

Th1 cells have different capacities to develop into memory cells based on their production of IFN-gamma. In this study, the mechanism by which a homogenous population of IFN-gamma-producing CD4 T cells was eliminated in vivo was assessed. When such cells were transferred into naive mice and activated with Ag, a striking decrease in the frequency of cells in the spleen and lung was observed. However, administration of neutralizing anti-IFN-gamma Ab at the time of Ag challenge largely prevented the elimination of such cells. To determine whether IFN-gamma was mediating its effects directly and/or indirectly, the ability of IFN-gamma to effectively signal in such cells was assessed in vitro. Indeed, there was reduced phosphorylation of STAT1 in response to IFN-gamma as well as markedly reduced expression of the IFN-gammaR beta-chain. Furthermore, transfer of such cells into IFN-gammaR-deficient mice limited their death following activation with Ag. Together, these data suggest that IFN-gamma acts in a paracrine manner to mediate the death of activated IFN-gamma-producing Th1 cells. In contrast to Ag stimulation, administration of CpG alone resulted in the elimination of Th1 cells in IFN-gammaR-/- mice. These results show that in response to Ag stimulation, the death of IFN-gamma-producing effector Th1 cells is controlled in an IFN-gamma-dependent manner, whereas in response to innate activation, the death of IFN-gamma-producing Th1 cells can occur through an IFN-gamma-independent pathway. Collectively, these data show the multiple mechanisms by which Th1 effector cells are efficiently eliminated in vivo.     

Combined triggering of dendritic cell receptors results in synergistic activation and potent cytotoxic immunity

Elimination of malignant cells and intracellular infections involves collaboration between CTLs and Th1 inflammation. Dendritic cells drive this response via costimulation and cytokines. We have defined key signals required for the exponential expansion of specific CD8(+) T cells in vivo in mice. Immunization with two or more TLR agonists, anti-CD40, IFN-gamma, and surfactant were sufficient to drive unprecedented levels of CD8 response to peptide or protein Ag and highly polarized Th1 CD4 responses. CD40 signaling was required for CD8 expansion but could be provided by a concomitant CD4 Th response in place of anti-CD40. Triggering of these pathways activated migration and activation of myeloid and plasmacytoid dendritic cells and secretion of IL-12. Cross-presentation can thus be exploited to induce potent cytotoxic responses and long-term memory to peptide/protein Ags. When combined with a tumor-associated peptide from tyrosinase-related protein 2, our combined adjuvant approach effectively halted tumor growth in an in vivo melanoma model and was more effective than anti-CD40 and a single TLR agonist. Antitumor immunity was associated with long-lived effector memory CD8 cells specific for the naturally processed and presented tumor Ag, and tumor protection was partially but not entirely dependent on CD8 T cells. This flexible strategy is more effective than existing adjuvants and provides a technological platform for rapid vaccine development.     

Long-Term CD4 Th1 and Th2 Memory following Acute Lymphocytic Choriomeningitis Virus Infection

CD4 T cells play a central role in viral immunity. They provide help for B cells and CD8 T cells and can act as effectors themselves. Despite their importance, relatively little is known about the magnitude and duration of virus-specific CD4 T-cell responses. In particular, it is not known whether both CD4 Th1 memory and CD4 Th2 memory can be induced by viral infections. To address these issues, we quantitated virus-specific CD4 Th1 (interleukin 2 [IL-2] and gamma-interferon) and Th2 (IL-4) responses in mice acutely infected with lymphocytic choriomeningitis virus (LCMV). Using two sensitive assays (enzyme-linked immunospot assay and intracellular stain) to measure cytokine production at the single-cell level, we found that both CD4 Th1 and Th2 responses were induced during primary LCMV infection. At the peak (day 8) of the response, the frequency of LCMV-specific CD4 Th1 cells was 1/35 to 1/160 CD4 T cells, and the frequency of Th2 cells was 1/400. After viral clearance, the numbers of virus-specific CD4 T cells dropped to 1/260 to 1/3,700 and then were maintained at this level indefinitely. Upon rechallenge with LCMV, both CD4 Th1 and Th2 memory cells made an anamnestic response in vivo. These results show that unlike some microbial infections in which only Th1 or Th2 responses are seen, an acute viral infection can induce a mixed CD4 T-cell response with long-term memory.