IL-17-producing NKT cells depend exclusively on IL-7 for homeostasis and survival

Natural killer T (NKT) cells are innate-like T cells that rapidly recognize pathogens and produce cytokines that shape the ensuing immune response. IL-17-producing NKT cells are enriched in barrier tissues, such as the lung, skin, and peripheral lymph nodes, and the factors that maintain this population in the periphery have not been elucidated. Here we show that NKT17 cells deviate from other NKT cells in their survival requirements. In contrast to conventional NKT cells that are maintained by IL-15, RORγt(+) NKT cells are IL-15 independent and instead rely completely on IL-7. IL-7 initiates a T-cell receptor-independent (TCR-independent) expansion of NKT17 cells, thus supporting their homeostasis. Without IL-7, survival is dramatically impaired, yet residual cells remain lineage committed with no downregulation of RORγt evident. Their preferential response to IL-7 does not reflect enhanced signaling through STAT proteins, but instead is modulated via the PI3K/AKT/mTOR signaling pathway. The ability to compete for IL-7 is dependent on high-density IL-7 receptor expression, which would promote uptake of low levels of IL-7 produced in the non-lymphoid sites of lung and skin. This dependence on IL-7 is also reported for RORγt(+) innate lymphoid cells and CD4(+) Th17 cells, and suggests common survival requirements for functionally similar cells.

Selectively expanding subsets of T cells in mice by injection of interleukin-2/antibody complexes: implications for transplantation tolerance

The biological activity of interleukin (IL)-2 and other cytokines in vivo can be augmented by binding to certain anti-cytokine monoclonal antibodies (mAb). Here, we review evidence on how IL-2/anti-IL-2 mAb complexes can be used to cause selective stimulation and expansion of certain T-cell subsets. With some anti-IL-2 mAbs, injection of IL-2/mAb complexes leads to expansion of CD8 T effector cells but not CD4 T regulatory cells (Tregs); these complexes exert less adverse side effects than soluble IL-2 and display powerful antitumor activity. Other IL-2/mAb complexes have minimal effects on CD8 T cells but cause marked expansion of Tregs. Preconditioning mice with these complexes leads to permanent acceptance of MHC-disparate pancreatic islets in the absence of immunosuppression.

Regulatory T cells expressing granzyme B play a critical role in controlling lung inflammation during acute viral infection

The inflammatory response to lung infections must be tightly regulated, enabling pathogen elimination while maintaining crucial gas exchange. Using recently described "depletion of regulatory T cell" (DEREG) mice, we found that selective depletion of regulatory T cells (Tregs) during acute respiratory syncytial virus (RSV) infection enhanced viral clearance but increased weight loss, local cytokine and chemokine release, and T-cell activation and cellular influx into the lungs. Conversely, inflammation was decreased when Treg numbers and activity were boosted using interleukin-2 immune complexes. Unexpectedly, lung (but not draining lymph node) Tregs from RSV-infected mice expressed granzyme B (GzmB), and bone marrow chimeric mice with selective loss of GzmB in the Treg compartment displayed markedly enhanced cellular infiltration into the lung after infection. A crucial role for GzmB-expressing Tregs has not hitherto been described in the lung or during acute infections, but may explain the inability of children with perforin/GzmB defects to regulate immune responses to infection. The effects of RSV infection in mice with defective immune regulation closely parallel the observed effects of RSV in children with bronchiolitis, suggesting that the pathogenesis of bronchiolitis may involve an inability to regulate virus-induced inflammation.

In vivo anergized T cells form altered immunological synapses in vitro

T cells contact allogeneic antigen presenting cells (APCs) and assemble, at their contact interface, a molecular platform called the immunological synapse. Synapse-based molecules provide directional signals for the T cell--either positive signals, resulting in T-cell activation, or negative signals causing T-cell inactivation or anergy. To better understand the molecular basis of in vivo T-cell anergy we analyzed the contacts made between in vivo anergized T cells and APCs, and determined which signaling molecules were included or excluded from their immunological synapses. Anergy was induced in TCR transgenic mice by the intravenous injection of semiallogeneic donor spleen cells. T cells from anergized mice were mixed with APCs, the T-cell/APC synapses imaged using deconvolution microscopy, and their molecular compositions were determined. T cells from anergic mice formed unstable immunological synapses in vitro with allogeneic APCs and failed to recruit the signaling proteins necessary to initiate T-cell activation. These findings suggest that T-cell anergy induced by exposure to semiallogeneic donor cells is associated with defects in the earliest events of T-cell activation, immunological synapse formation and recruitment of TCR-mediated signaling proteins.

A defect in central tolerance in NOD mice

The predisposition of nonobese diabetic (NOD) mice to develop autoimmune disease is usually attributed to defects in peripheral tolerance mechanisms. Here, evidence is presented that NOD mice display a defect in central tolerance (negative selection) of thymocytes. Impaired central tolerance in NOD mice was most prominent in a population of semi-mature thymocytes found in the medulla. The defect was apparent in vivo as well as in vitro, was independent of IAbetag7 expression and affected both Fas-dependent and Fas-independent pathways of apoptosis; for Fas-dependent apoptosis, the defective tolerance of NOD thymocytes correlated with the strong T cell receptor-mediated up-regulation of caspase 8-homologous FLICE (Fas-associated death-domain-like interleukin 1beta-converting enzyme)-inhibitory protein. In light of these findings, disease onset in NOD mice may reflect defects in central as well as peripheral tolerance.

The thymus and central tolerance

T-cell differentiation in the thymus generates a peripheral repertoire of mature T cells that mounts strong responses to foreign antigens but is largely unresponsive to self-antigens. This state of specific immunological tolerance to self-components involves both central and peripheral mechanisms. Here we review the process whereby many T cells with potential reactivity for self-antigens are eliminated in the thymus during early T-cell differentiation. This process of central tolerance (negative selection) reflects apoptosis and is a consequence of immature T cells receiving strong intracellular signalling through T-cell receptor (TCR) recognition of peptides bound to major histocompatibility complex (MHC) molecules. Central tolerance occurs mainly in the medullary region of the thymus and depends upon contact with peptide-MHC complexes expressed on bone-marrow-derived antigen-presenting cells (APCs); whether tolerance also occurs in the cortex is still controversial. Tolerance induction requires a combination of TCR ligation and co-stimulatory signals. Co-stimulation reflects interaction between complementary molecules on T cells and APCs and probably involves multiple molecules acting in consort, which may account for why deletion of individual molecules with known or potential co-stimulatory function has little or no effect on central tolerance. The range of self-antigens that induce central tolerance is considerable and, via low-level expression in the thymus, may also include tissue-specific antigens; central tolerance to these latter antigens, however, is likely to be limited to high-affinity T cells, leaving low-affinity cells to escape. Tolerance to alloantigens and the possibility of using central tolerance to promote acceptance of allografts are discussed.

IL-7 is critical for homeostatic proliferation and survival of naive T cells

In T cell-deficient conditions, naive T cells undergo spontaneous "homeostatic" proliferation in response to contact with self-MHC/peptide ligands. With the aid of an in vitro system, we show here that homeostatic proliferation is also cytokine-dependent. The cytokines IL-4, IL-7, and IL-15 enhanced homeostatic proliferation of naive T cells in vitro. Of these cytokines, only IL-7 was found to be critical; thus, naive T cells underwent homeostatic proliferation in IL-4(-) and IL-15(-) hosts but proliferated minimally in IL-7(-) hosts. In addition to homeostatic proliferation, the prolonged survival of naive T cells requires IL-7. Thus, naïve T cells disappeared gradually over a 1-month period upon adoptive transfer into IL-7(-) hosts. These findings indicate that naive T cells depend on IL-7 for survival and homeostatic proliferation.

T cell death and memory

In typical immune responses, contact with antigen causes naive T cells to proliferate and differentiate into effector cells. After the pathogen is destroyed, most effector T cells are eliminated-thereby preserving the primary T cell repertoire-but some cells survive and form long-lived memory cells. During each stage of this process, the life or death fate of T cells is strictly regulated.

Burnet oration. T-cell survival and the role of cytokines

Typical T cells are long-lived resting cells. Despite their quiescent appearance, there is increasing evidence that T cells are subjected to continuous stimulation through contact with various stimuli, notably by self peptide/MHC complexes and cytokines. These stimuli keep T cells alive and also cause intermittent entry into cell cycle.

An IFN-gamma-dependent pathway controls stimulation of memory phenotype CD8+ T cell turnover in vivo by IL-12, IL-18, and IFN-gamma

Unlike naive T cells, memory phenotype (CD44(high)) T cells exhibit a high background rate of turnover in vivo. Previous studies showed that the turnover of memory phenotype CD8(+) (but not CD4(+)) cells in vivo can be considerably enhanced by products of infectious agents such as LPS. Such stimulation is TCR independent and hinges on the release of type I IFNs (IFN-I) which leads to the production of an effector cytokine, probably IL-15. In this study, we describe a second pathway of CD44(high) CD8(+) stimulation in vivo. This pathway is IFN-gamma rather than IFN-I dependent and is mediated by at least three cytokines, IL-12, IL-18, and IFN-gamma. As for IFN-I, these three cytokines are nonstimulatory for purified T cells and under in vivo conditions probably act via production of IL-15.

Role of the actin cytoskeleton in T cell absorption and internalization of ligands from APC

A feature of T-APC interaction is that, via either TCR or CD28, T cells can absorb molecules from APC on to the cell surface and then internalize these molecules. Here, using both normal and TCR-transgenic T cells, we investigated the mechanism of T cell absorption of molecules from APC and the role of the cytoskeleton. The results show that although activated T cells could absorb APC molecules in the form of cell fragments, uptake of molecules by resting T cells required direct T-APC interaction. Based on studies with latrunculin B, surface absorption of molecules by resting T cells was crucially dependent upon the actin cytoskeleton for both CD28- and TCR-mediated absorption. Significantly, however, TCR-mediated absorption became strongly resistant to latrunculin B when the concentration of MHC-bound peptide on APC was raised to a high level, implying that the actin cytoskeleton is only important for absorption when the density of receptor/ligand interaction is low. By contrast, in all situations tested, the actin cytoskeleton played a decisive role in controlling T cell internalization of ligands from the cell surface.

Generation and maintenance of memory T cells

Typical immune responses lead to the prominent clonal expansion of antigen-specific T cells followed by their differentiation into effector cells. Most effector cells die at the end of the immune response but some of the responding cells survive and form long-lived memory cells. The factors controlling the formation and survival of memory T cells are discussed. Recent evidence suggests that T memory cells arise from a subset of effector cells. The longevity of T memory cells may require continuous contact with cytokines, notably IL-15 for CD8(+) cells.

The thymus and negative selection

Self-tolerance induction is largely a reflection of negative selection (deletion) of autoreactive T cells in the thymus. Evidence is presented that negative selection occurs at a relatively late stage of thymocyte differentiation and affects a population of semimature HSA(hi) CD4+8- cells found in the medulla. Negative selection involves a number of cell-surface molecules on T cells, including Fas, CD28, CD5, and CD43. These molecules appear to act in consort, thereby ensuring that negative selection is highly efficient.

The thymus and central tolerance

T cell tolerance to self-components occurs largely in the thymus during early differentiation and leads to death (negative selection) of T cells with overt autoreactivity. In this article we review the evidence that negative selection in mice occurs mainly in the medulla at the level of a population of semimature T cells. The role of Fas and several costimulatory molecules on negative selection and the inhibitory role of certain cytokines are discussed.

T-cell proliferation in vivo and the role of cytokines

Unlike typical naive T cells, T cells with an activated (CD44hi) memory phenotype show a rapid rate of proliferation in vivo. The turnover of memory-phenotype CD8+ T cells can be considerably augmented by injecting mice with various compounds, including polyinosinic polycytidylic acid, lipopolysaccharide and immunostimulatory DNA (CpG DNA). Certain cytokines, notably type I (alpha, beta) interferons (IFN-I), have a similar effect. These agents appear to induce proliferation of CD44hi CD8+ cells in vivo by an indirect process involving production of effector cytokines, possibly interleukin-15, by antigen-presenting cells. Although none of the agents tested induces proliferation of naive-phenotype T cells, IFN-I has the capacity to cause upregulation of surface markers on purified naive T cells. Depending upon the experimental conditions used, IFN-I can either inhibit or enhance primary responses of naive T cells to specific antigen.

Stimulation of memory T cells by cytokines

Mature T cells can be classified on the basis of cell surface markers into naïve- and memory-phenotype cells. These phenotypically-defined subsets exhibit distinct kinetic behaviour in vivo. Thus, naïve-phenotype T cells persist long-term in a non-dividing state, while memory-phenotype T cells include cycling cells and have a more rapid rate of turnover. We have investigated the possibility that the different kinetic behaviour of naïve- and memory-phenotype T cells reflects a differential responsiveness to cytokines. It was discovered that memory-, but not naïve-, phenotype T cells were stimulated to proliferate by a variety of infection-induced cytokines. These results suggest that cytokines contribute to the high background rate of turnover exhibited by memory T cells.

Multiple effects of immunostimulatory DNA on T cells and the role of type I interferons

In addition to stimulating antigen-specific immune responses, infectious agents cause nonspecific activation of the innate immune system, notably up-regulation of costimulatory/adhesion molecules on APCs and cytokine production. In recent years it has become apparent that stimulation of the immune system by microorganisms is a property of a number of different cellular components, including DNA. As discussed earlier and elsewhere in this volume, the DNA of infectious agents--and indeed of all non-vertebrates tested--differs from mammalian DNA in being enriched for unmethylated CpG motifs. With appropriate flanking sequences, CpG DNA and synthetic CpG ODNs cause strong activation of APCs and other cells. In this article we have focussed on the capacity of CpG DNA/ODNs to alter T cell function. Whether these compounds act directly on T cells or function indirectly by activating other cells, especially APCs, is controversial [7, 8, 13, 14]. In contrast to other workers [8], we have yet to find definitive evidence that CpG DNA/ODNs can provide a co-stimulatory signal for purified T cells subjected to TCR ligation ([14] and unpublished data of authors). For this reason we lean to the notion that CpG DNA/ODNs modulate T cell function by inducing activation of APC rather than by acting directly on T cells. When injected in vivo in the absence of specific antigen, CpG DNA/ODNs have two striking effects on T cells, namely (1) induction of overt activation (proliferation) of memory-phenotype CD8+ cells, and (2) partial activation of all T cells, including naïve-phenotype T cells. Both actions of CpG DNA/ODNs are heavily dependent on the production of IFN-I by APC. For memory-phenotype (CD44hi) CD8+ cells, neither CpG DNA nor IFN-I can cause proliferation of purified APC-depleted T cells in vitro. Hence, under in vivo conditions, CpG DNA-induced proliferation of CD44hi CD8+ cells is probably mediated through the production of a secondary cytokine, i.e., by a cytokine that is directly stimulatory for CD44hi CD8+ cells. Based on the available evidence, it is highly likely that the effector cytokine is IL-15. With this assumption, our current model is that proliferation of CD44hi CD8+ cells induced by injection of CpG DNA/ODNs reflects production of IFN-I which, in turn, leads to synthesis of IL-15. Which particular cell types produce these two cytokines is unclear, although APCs are probably of prime importance. In addition to inducing proliferation of memory-phenotype CD8+ cells via IL-15, the IFN-I induced by CpG DNA/ODNs can also induce partial activation of naive T cells. This form of activation leads to up-regulation of CD69 and other molecules but does not cause entry into cell cycle. It is of interest that the partial activation of naive T cells induced by IFN-I is associated with decreased T proliferative responses. Thus, proliferation of purified naïve T cells elicited by combined TCR/CD28 ligation in vitro is greatly reduced by addition of IFN-I. This inhibitory effect of IFN-I does not influence cytokine production and probably reflects production of cell cycle inhibitors. Surprisingly, except at high doses, IFN-I fails to exert an anti-proliferative effect when T proliferative responses are driven by viable APCs. Indeed, in this situation, IFN-I enhances antigen-specific T proliferative responses, both in vivo and in vitro. This adjuvant effect of IFN-I is presumably a reflection of APC activation, but direct evidence on this issue is still lacking. In this article we have emphasized that contact with CpG DNA/ODNs has multiple effects on T cell function in vivo. Many of these effects seem to be related to the production of certain cytokines by APCs, notably IFN-I and IL-15. It should be stressed, however, that CpG DNA/ODNs probably lead to the production of many other cytokines. Hence, our current models of how CpG DNA/ODNs influence T cell function are undoubtedly oversimplified.

TCR-Mediated internalization of peptide-MHC complexes acquired by T cells

Peptide-major histocompatibility complex protein complexes (pMHCs) on antigen-presenting cells (APCs) are central to T cell activation. Within minutes of peptide-specific T cells interacting with APCs, pMHCs on APCs formed clusters at the site of T cell contact. Thereafter, these clusters were acquired by T cells and internalized through T cell receptor-mediated endocytosis. During this process, T cells became sensitive to peptide-specific lysis by neighboring T cells (fratricide). This form of immunoregulation could explain the "exhaustion" of T cell responses that is induced by high viral loads and may serve to down-regulate immune responses.

Strong TCR ligation without costimulation causes rapid onset of Fas-dependent apoptosis of naive murine CD4+ T cells

Activation-induced cell death of T cells typically occurs late in the primary response after a prior proliferative response. Here, we describe a novel form of cell death in which purified naive murine CD4+ cells undergo apoptosis within 18 h in vitro after strong TCR ligation. Such rapid-onset TCR-mediated death of T cells does not involve cell division and is Fas-dependent, inhibited by CD28 (and IL-6) costimulation and enhanced by IL-4 and IL-7; by contrast, spontaneous death of CD4+ cells cultured alone is Fas-independent and inhibited by IL-4 and IL-7. TCR-mediated Fas-dependent death of CD4+ cells is prevented by combined TCR/Fas ligation and by drugs that inhibit calcineurin-dependent signaling and mitogen-activated protein kinase MEK1 activation.

The peptide ligands mediating positive selection in the thymus control T cell survival and homeostatic proliferation in the periphery

Positive selection to self-MHC/peptide complexes has long been viewed as a device for skewing the T cell repertoire toward recognition of foreign peptides presented by self-MHC molecules. Here, we provide evidence for an alternative possibility, namely, that the self-peptides controlling positive selection in the thymus serve to maintain the longevity of mature T cells in the periphery. Surprisingly, when total T cell numbers are reduced, these self-ligands become overtly stimulatory and cause naive T cells to proliferate and undergo homeostatic expansion.

Stimulation of naïve and memory T cells by cytokines

On the basis of cell surface markers, mature T cells are considered to have either a naïve or a memory phenotype. These cells exhibit distinct types of kinetic behaviour in vivo. While naïve-phenotype cells persist long term in a non-dividing state, memory-phenotype T cells include cycling cells and exhibit a more rapid rate of turnover; this has also been shown to be true for cells that can be definitively identified as naïve or memory T cells respectively. The number of memory-phenotype (CD44hi) CD8+ T cells entering cell cycle is greatly increased after in vivo exposure to viruses, bacteria or components of bacteria. Accelerated turnover of memory T cells also occurs after the injection of a variety cytokines that are induced by infectious agents, including type I interferon (IFN-I). Although naïve-phenotype T cells do not divide in response to these cytokines, they do exhibit signs of activation, including upregulation of CD69 after exposure to IFN-I. These findings suggest that the dissimilar in vivo kinetics of naïve- and memory-phenotype T cells might reflect their divergent responses to cytokines. Furthermore, the ability of infection-induced cytokines to stimulate non-specific proliferation of memory-phenotype T cells and partial activation of naïve-phenotype T cells implies that they play a complex role during primary immune responses to infectious agents.

Several different cell surface molecules control negative selection of medullary thymocytes

Repeated attempts to show that costimulation for negative selection is controlled by a single cell surface molecule have been unsuccessful. Thus, negative selection may involve multiple cell surface molecules acting in consort. In support of this idea, we show here that at least three cell surface molecules, namely CD28, CD5, and CD43, contribute to Fas-independent negative selection of the tolerance-susceptible population of heat-stable antigen (HSA)hiCD4+8- cells found in the medulla. The costimulatory function of these three molecules can be blocked by certain cytokines, IL-4 and IL-7, and coinjecting these cytokines with antigen in vivo abolishes negative selection; Fas-dependent negative selection, however, is maintained. The results suggest that efficient negative selection requires the combined functions of at least four cell surface molecules: CD28, CD5, CD43, and Fas.

Thymic selection by a single MHC/peptide ligand: autoreactive T cells are low-affinity cells

In H2-M- mice, the presence of a single peptide, CLIP, bound to MHC class II molecules generates a diverse repertoire of CD4+ cells. In these mice, typical self-peptides are not bound to class II molecules, with the result that a very high proportion of H2-M- CD4+ cells are responsive to the various peptides displayed on normal MHC-compatible APC. We show here, however, that such "self" reactivity is controlled by low-affinity CD4+ cells. These cells give spectacularly high proliferative responses but are virtually unreactive in certain other assays, e.g., skin graft rejection; responses to MHC alloantigens, by contrast, are intense in all assays. Possible explanations for why thymic selection directed to a single peptide curtails self specificity without affecting alloreactivity are discussed.

T-cell turnover in vivo and the role of cytokines

In addition to responding to specific antigen, CD8+ T-cells with a memory (CD44hi) phenotype undergo bystander proliferation when exposed to certain cytokines, notably type I interferons (IFN I), in vivo; such proliferation does not require T-cell receptor ligation. Since IFN I is unable to induce proliferation of purified CD44hi CD8+ cells in vitro, stimulation of these cells in vivo may reflect IFN I-dependent release of other cytokines. Evidence is presented that IFN I induces macrophages to synthesize IL-15 mRNA and that, at the protein level, IL-15 causes selective stimulation of CD44hi CD8+ (but not CD4+) cells, both in vitro and in vivo. This finding raises the possibility that synthesis of IL-15 during infection may induce bystander proliferation of memory-phenotype CD8+ cells.

Type I interferon-mediated stimulation of T cells by CpG DNA

Immunostimulatory DNA and oligodeoxynucleotides containing unmethylated CpG motifs (CpG DNA) are strongly stimulatory for B cells and antigen-presenting cells (APCs). We report here that, as manifested by CD69 and B7-2 upregulation, CpG DNA also induces partial activation of T cells, including naive-phenotype T cells, both in vivo and in vitro. Under in vitro conditions, CpG DNA caused activation of T cells in spleen cell suspensions but failed to stimulate highly purified T cells unless these cells were supplemented with APCs. Three lines of evidence suggested that APC-dependent stimulation of T cells by CpG DNA was mediated by type I interferons (IFN-I). First, T cell activation by CpG DNA was undetectable in IFN-IR-/- mice. Second, in contrast to normal T cells, the failure of purified IFN-IR-/- T cells to respond to CpG DNA could not be overcome by adding normal IFN-IR+ APCs. Third, IFN-I (but not IFN-gamma) caused the same pattern of partial T cell activation as CpG DNA. Significantly, T cell activation by IFN-I was APC independent. Thus, CpG DNA appeared to stimulate T cells by inducing APCs to synthesize IFN-I, which then acted directly on T cells via IFN-IR. Functional studies suggested that activation of T cells by IFN-I was inhibitory. Thus, exposing normal (but not IFN-IR-/-) T cells to CpG DNA in vivo led to reduced T proliferative responses after TCR ligation in vitro.

The induction of in vivo proliferation of long-lived CD44hi CD8+ T cells after the injection of tumor cells expressing IFN-alpha1 into syngeneic mice

The tumorigenicity of transplantable tumor cells in mice is reduced by transduction with cytokine genes, including IFN-alpha and interleukin (IL) 12. Although T cells are considered important in tumor rejection, the mechanism by which genetically modified tumor cells stimulate the immune system has not been examined. In this study, the in vivo proliferation of T-cell subsets in mice transplanted with cytokine-producing syngeneic tumor cells was assessed by administering the DNA precursor bromodeoxyuridine. The injection of viable cells producing IFN-alpha or IL-12 caused a marked proliferation of CD8+ T lymphocytes in both the spleen and lymph nodes. Proliferation was most prominent among memory-phenotype CD44hi CD8+ T cells. In contrast, proliferation of CD8+ T cells did not occur in mice injected with control cells or with cells expressing IL-4, granulocyte colony-stimulating factor, or IFN-gamma. Pulse-chase studies in mice injected with IFN-alpha-producing cells showed that a proportion of proliferating CD8+ T cells survived for at least 70 days, suggesting that long-lived memory cells are induced using such an approach. In summary, these results, together with previous studies on the host immune reactivity triggered by the injection of tumor cells expressing IFN-alpha, represent a strong rationale for considering IFN-alpha as a powerful T-cell adjuvant for the generation of more effective cancer vaccines.

Requirements for stimulating naive CD8+ T cells via signal 1 alone

In the absence of costimulation, TCR recognition of peptide/MHC complexes is generally considered to be nonimmunogenic. In agreement with this view, naive TCR transgenic CD8+ cells failed to respond to specific peptides presented by MHC class I (Ld) molecules bound to mouse RBC. However, peptide/Ld complexes presented by cell-sized beads or bound to plastic led to overt proliferative responses in the absence of added cytokines. Significantly, equivalent strong proliferative responses occurred when mouse RBC were fixed with glutaraldehyde before Ld coupling. The implication therefore is that the intensity of signaling via the TCR is a reflection of the mobility of the ligand being recognized; TCR signaling is weak when the ligand can move laterally on the cell membrane but strong when the ligand is immobilized.

Probing the activation requirements for naive CD8+ T cells with Drosophila cell transfectants as antigen presenting cells

Activation of T cells involves multiple receptor-ligand interactions between T cells and antigen presenting cells (APC). At least two signals are required for T-cell activation: Signal 1 results from recognition of MHC/peptide complexes on the APC by cell surface T-cell receptors (TCR), whereas Signal 2 is induced by the interactions of co-stimulatory molecules on APC with their complementary receptors on T cells. This review focuses on our attempts to understand these various signals in a model system involving the 2C TCR. The structural basis of Signal 1 was investigated by determining the crystal structure of 2C TCR alone and in complex with MHC/peptide. Analysis of these structures has provided some basic rules for how TCR and MHC/peptide interact; however, the critical question of how this interaction transduces Signal 1 to T cells remains unclear. The effects of Signal 1 and Signal 2 on T-cell activation were examined with naive T cells from the 2C TCR transgenic mice, defined peptides as antigen and transfected Drosophila cells as APC. The results suggest that, except under extreme conditions, Signal 1 alone is unable to activate naive CD8 T cells despite the induction of marked TCR downregulation. Either B7 or intercellular adhesion molecule (ICAM)-1 can provide the second signal for CD8 T-cell activation. However, especially at low MHC/peptide densities, optimal activation and differentiation of CD8 T cells required interaction with both B7 and ICAM-1 on the same APC. Thus, the data suggest that at least two qualitatively different co-stimulation signals are required for full activation of CD8 T cells under physiological conditions.

CD40 ligand-mediated interactions are involved in the generation of memory CD8(+) cytotoxic T lymphocytes (CTL) but are not required for the maintenance of CTL memory following virus infection

CD8(+) cytotoxic T lymphocytes (CTL) play a key role in the control of many virus infections, and the need for vaccines to elicit strong CD8(+) T-cell responses in order to provide optimal protection in such infections is increasingly apparent. However, the mechanisms involved in the induction and maintenance of CD8(+) CTL memory are currently poorly understood. In this study, we investigated the involvement of CD40 ligand (CD40L)-mediated interactions in these processes by analyzing the memory CTL response of CD40L-deficient mice following infection with lymphocytic choriomeningitis virus (LCMV). The maintenance of memory CD8(+) CTL precursors (CTLp) at stable frequencies over time was not impaired in CD40L-deficient mice. By contrast, the initial generation of memory CTLp was affected. CD40L-deficient mice produced lower levels of CD8(+) CTLp during the primary immune response to LCMV than did wild-type controls, despite the fact that the LCMV-specific effector CTL response of CD40L-deficient mice was indistinguishable from that of control animals. The differentiation of naïve CD8(+) T cells into effector and memory CTL thus involves pathways that can be discriminated from each other by their requirement for CD40L-mediated interactions. Expression of CD40L by CTLp themselves was not an essential step during their expansion and differentiation from naïve CD8(+) cells into memory CTLp; instead, the reduction in memory CTLp generation in CD40L-deficient mice was likely a consequence of defects in the CD4(+) T-cell response mounted by these animals. These results thus suggest a previously unappreciated role for CD40L in the generation of CD8(+) memory CTLp, the probable nature of which is discussed.

Anti-viral immunity: spotting virus-specific T cells

Historically, quantitation of virus-specific CD8+ T cells has been accomplished by limiting dilution analysis of cytotoxic precursor cells. Recent studies have shown that this technique greatly underestimates the actual number of antigen-specific cells and have provided new insight into anti-viral immune responses.

Bystander stimulation of T cells in vivo by cytokines

Immune responses to infectious agents, especially viruses, are often associated with extensive proliferation of T cells and transient enlargement of the lymphoid tissues. Since the precursor frequency of T cells for specific antigen is low, the bulk of the T cells proliferating in the primary response are presumably stimulated via non-antigen-specific mechanisms, e.g. via cytokines elicited by the infectious agent concerned. Such 'bystander' stimulation of T cells occurs in mice injected with agents that elicit production of type I interferon (IFN I). Induction of IFN I in vivo causes marked stimulation of the CD44hi subset of CD8+ T cells and is prominent after injection of live viruses or products of bacteria such as lipopolysaccharide. Cytokines elicited by infectious agents may act as adjuvants during the primary response and could serve to boost the survival of long-lived memory cells.

A role for Fas in negative selection of thymocytes in vivo

To seek information on the role of Fas in negative selection, we examined subsets of thymocytes from normal neonatal mice versus Fas-deficient lpr/lpr mice injected with graded doses of antigen. In normal mice, injection of 1-100 microg of staphylococcal enterotoxin B (SEB) induced clonal elimination of SEB-reactive Vbeta8+ cells at the level of the semi-mature population of HSAhi CD4+ 8- cells found in the thymic medulla; deletion of CD4+ 8+ cells was minimal. SEB injection also caused marked elimination of Vbeta8+ HSAhi CD4+ 8- thymocytes in lpr/lpr mice. Paradoxically, however, elimination of these cells in lpr/lpr mice was induced by low-to-moderate doses of SEB ( Collapse

Key Words Collapse

MESH Headings

• Amino Acid Sequence
• Animals
• Antibodies, Monoclonal/immunology
• Antibodies, Monoclonal/metabolism
• CD4-Positive T-Lymphocytes/immunology
• CD8-Positive T-Lymphocytes/immunology
• Clone Cells/immunology
• Enterotoxins/immunology
• Flow Cytometry
• Immune Tolerance/immunology
• Mice
• Mice, Inbred Strains
• Mice, Transgenic
• Molecular Sequence Data
• Ovalbumin/immunology
• Peptide Fragments/immunology
• Receptors, Antigen, T-Cell/genetics
• Thymus Gland/physiology
• fas Receptor/physiology

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Grants

• P01 AG001743 NIA NIH HHS
• R37 CA038355 NCI NIH HHS
• CA25803 NCI NIH HHS
• CA38355 NCI NIH HHS
• AI21487 NIAID NIH HHS

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Affiliation(s)

H Kishimoto Department of Immunology, IMM4, The Scripps Research Institute, 10550 North Torrey Pines Road, La Jolla, California 92037, USA
C D Surh
J Sprent

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Potent and selective stimulation of memory-phenotype CD8+ T cells in vivo by IL-15

Proliferation of memory-phenotype (CD44hi) CD8+ cells induced by infectious agents can be mimicked by injection of type I interferon (IFN I) and by IFN I-inducing agents such as lipopolysaccharide and Poly I:C; such proliferation does not affect naive T cells and appears to be TCR independent. Since IFN I inhibits proliferation in vitro, IFN I-induced proliferation of CD8+ cells in vivo presumably occurs indirectly through production of secondary cytokines, e.g., interleukin-2 (IL-2) or IL-15. We show here that, unlike IL-2, IL-15 closely mimics the effects of IFN I in causing strong and selective stimulation of memory-phenotype CD44hi CD8+ (but not CD4+) cells in vivo; similar specificity applies to purified T cells in vitro and correlates with much higher expression of IL-2Rbeta on CD8+ cells than on CD4+ cells.

DNA as an adjuvant: capacity of insect DNA and synthetic oligodeoxynucleotides to augment T cell responses to specific antigen

How strong adjuvants such as complete Freund's adjuvant (CFA) promote T cell priming to protein antigens in vivo is still unclear. Since the unmethylated CpG motifs in DNA of bacteria and other nonvertebrates are stimulatory for B cells and antigen-presenting cells, the strong adjuvanticity of CFA could be attributed, at least in part, to the presence of dead bacteria, i.e., a source of stimulatory DNA. In support of this possibility, evidence is presented that insect DNA in mineral oil has even stronger adjuvant activity than CFA by a number of parameters. Synthetic oligodeoxynucleotides (ODNs) containing unmethylated CpG motifs mimic the effects of insect DNA and, even in soluble form, ODNs markedly potentiate clonal expansion of T cell receptor transgenic T cells responding to specific peptide.

Lifespan of gamma/delta T cells

Information on the turnover and lifespan of murine gamma/delta cells was obtained by administering the DNA precursor, bromodeoxyuridine (BrdU), in the drinking water and staining lymphoid cells for BrdU incorporation. For TCR-gamma/delta (Vgamma2) transgenic mice, nearly all gamma/delta thymocytes became BrdU+ within 2 d and were released rapidly into the peripheral lymphoid tissues. These recent thymic emigrants (RTEs) underwent phenotypic maturation in the periphery for several days, but most of these cells died within 4 wk. In adult thymectomized (ATx) transgenic mice, only a small proportion of gamma/delta cells survived as long-lived cells; most of these cells had a slow turnover and retained a naive phenotype. As in transgenic mice, the majority of RTEs generated in normal mice (C57BL/6) appeared to have a restricted lifespan as naive cells. However, in marked contrast to TCR transgenic mice, most of the gamma/delta cells surviving in ATx normal mice had a rapid turnover and displayed an activated/memory phenotype, implying a chronic response to environmental antigens. Hence, in normal mice many gamma/delta RTEs did not die but switched to memory cells.

Introduction: homeostasis in the immune system

No abstractCopyright 1997 Academic Press Limited Copyright 1997Academic Press Limited

Mitogenicity of DNA from different organisms for murine B cells

Recent evidence that DNA from bacteria causes polyclonal activation of mouse B cells raises the question of whether DNA from other organisms has similar properties. Extending prior studies on bacteria and insects, we show here that the capacity of DNA to stimulate B cells correlates closely with hypomethylation of DNA CpG dinucleotide motifs. Thus strong stimulation of B cells was seen with DNA from various organisms displaying little or no methylation of CpG motifs, i.e., yeast, nematodes, and molluscs in addition to bacteria and insects. For these organisms, DNA induced nearly all B cells (including small resting B cells) to up-regulate the activation marker, CD69, and caused many B cells to enter the cell cycle, indicative of polyclonal activation; this effect was not seen after selective methylation of CpG motifs (tested on yeast DNA). By contrast, no stimulation of B cells was seen with DNA from organisms whose CpG motifs are heavily methylated, i.e., various vertebrates (mammals, fish, and frogs) and plants (corn). Despite this correlation, DNA prepared from two murine cell lines exhibiting hypomethylation of CpG motifs caused little or no stimulation of B cells. Thus, the idea that the stimulatory properties of DNA correlate solely with the presence of unmethylated CpG motifs may be an oversimplification.

Mitogenicity of DNA from different organisms for murine B cells

Recent evidence that DNA from bacteria causes polyclonal activation of mouse B cells raises the question of whether DNA from other organisms has similar properties. Extending prior studies on bacteria and insects, we show here that the capacity of DNA to stimulate B cells correlates closely with hypomethylation of DNA CpG dinucleotide motifs. Thus strong stimulation of B cells was seen with DNA from various organisms displaying little or no methylation of CpG motifs, i.e., yeast, nematodes, and molluscs in addition to bacteria and insects. For these organisms, DNA induced nearly all B cells (including small resting B cells) to up-regulate the activation marker, CD69, and caused many B cells to enter the cell cycle, indicative of polyclonal activation; this effect was not seen after selective methylation of CpG motifs (tested on yeast DNA). By contrast, no stimulation of B cells was seen with DNA from organisms whose CpG motifs are heavily methylated, i.e., various vertebrates (mammals, fish, and frogs) and plants (corn). Despite this correlation, DNA prepared from two murine cell lines exhibiting hypomethylation of CpG motifs caused little or no stimulation of B cells. Thus, the idea that the stimulatory properties of DNA correlate solely with the presence of unmethylated CpG motifs may be an oversimplification.

Thymic selection by a single MHC/peptide ligand produces a semidiverse repertoire of CD4+ T cells

The influence of individual peptides in thymic selection was examined in H2-M- mice, in which positive selection is directed to a single peptide, class II-associated invariant chain peptide (CLIP) bound to H2-A(b). Two sensitive in vivo approaches showed that 70%-80% of CD4+ T cells undergoing positive selection to CLIP+H2-A(b) have self-reactivity to the various peptides expressed on wild-type H2-M+ antigen-presenting cells. When these self-reactive T cells were depleted, the residual CD4+ cells displayed a polyclonal repertoire in terms of alloreactivity, responses to foreign protein antigens, and Vbeta usage. Nevertheless, studies with two T cell receptor transgenic lines suggested that the repertoire of CD4+ cells induced by CLIP was less diverse than the repertoire of CD4+ cells in normal mice. Generation of a fully diverse T cell repertoire thus requires positive selection against multiple peptides.

Rat stem cells developing in irradiated SCID mice fail to become tolerized and cause lethal graft-versus-host disease

Graft-versus-host disease (GVHD) is prominent in irradiated hosts given whole allogeneic bone marrow cells but is generally undetectable when T-depleted stem cells are transferred; under these conditions, the mature T cells arising from the donor stem cells become tolerant to host antigens and fall to cause GVHD. We show here that a radically different situation can occur when hosts are reconstituted with xenogeneic stem cells. When lightly irradiated, adult C.B-17 SCID mice injected with Lewis rat fetal liver (FL) cells show near-total repopulation with rat-derived lymphohemopoietic cells, including T and B cells. However, in marked contrast to chimeras prepared with allogeneic mouse FL cells, rat FL-->SCID chimeras develop severe and often lethal chronic GVHD. In these rat-->mouse chimeras, the rat T cells show limited tolerance to host mouse antigens as determined by various parameters including mixed lymphocyte reaction and cytotoxic T lymphocyte assays in vitro, adoptive transfer of T cells to secondary SCID hosts, and the lack of V beta deletion to endogenous host mtv antigens. GVHD in irradiated rat-->SCID chimeras is most prominent with Lewis FL but also applies to Fisher 344 and Wistar Furth FL cells. The failure of newly formed rat T cells in rat-->SCID chimeras to become fully tolerant to host mouse antigens appears to be due to depletion of host antigen-presenting cells by irradiation. Thus, rat-->SCID chimeras generated by transplanting rat FL cells into unirradiated neonatal SCID mice fail to develop GVHD, and the rat T cells display self-tolerance. As allogeneic H-2-different mouse FL-->irradiated SCID chimeras display strong self-tolerance, presumably through recognition of host antigens on thymic epithelial cells, the implication is that mouse thymic epithelial cells are tolerogenic only for mouse and not for rat immature T cells.

T cell stimulation in vivo by lipopolysaccharide (LPS)

Lipopolysaccharide (LPS) from gram-negative bacteria causes polyclonal activation of B cells and stimulation of macrophages and other APC. We show here that, under in vivo conditions, LPS also induces strong stimulation of T cells. As manifested by CD69 upregulation, LPS injection stimulates both CD4 and CD8(+) T cells, and, at high doses, stimulates naive (CD44(lo)) cells as well as memory (CD44(hi)) cells. However, in terms of cell division, the response of T cells after LPS injection is limited to the CD44(hi) subset of CD8(+) cells. In contrast with B cells, proliferative responses of CD44(hi) CD8(+) cells require only very low doses of LPS (10 ng). Based on studies with LPS-nonresponder and gene-knockout mice, LPS-induced proliferation of CD44(hi) CD8(+) cells appears to operate via an indirect pathway involving LPS stimulation of APC and release of type I (alpha, beta) interferon (IFN-I). Similar selective stimulation of CD44(hi) CD8(+) cells occurs in viral infections and after injection of IFN-I, implying a common mechanism. Hence, intermittent exposure to pathogens (gram-negative bacteria and viruses) could contribute to the high background proliferation of memory-phenotype CD8(+) cells found in normal animals.

Immunological memory

Most of the antigen-specific T and B cells participating in the primary immune response are rapidly eliminated, but some of the cells survive and become long-lived memory cells. There have been a number of recent developments on the features and functions of memory cells.