Rapid αß T-cell responses orchestrate innate immunity in response to Staphylococcal enterotoxin A.

In the generation of a traditional immune response against invading pathogens, innate cells guide T cells by programming their differentiation. However, here we demonstrate that αß T cells have an essential role in priming innate immunity in the lung after Staphylococcus aureus enterotoxin A (SEA) inhalation. We found that SEA induces waves of cellular activation, cytokine production, and migration into the lung tissue and airways. However, this innate response was completely inhibited in the absence of αß T cells. Specifically, we found that interleukin (IL)-17A was required for the recruitment of neutrophils and monocytes into the lung. The cellular source of IL-17A was γδ T cells, which increased their IL-17A production following SEA but only in an αß T-cell-dependent manner. Thus, rapid T-cell activation orchestrates innate immunity and may be a new point of therapeutic intervention for acute lung injury.

Feeding by the tick, Ixodes scapularis, causes CD4(+) T cells responding to cognate antigen to develop the capacity to express IL-4.

Effects of tick feeding on an early antigen-specific T cell response were studied by monitoring a clonotypic population of adoptively transferred T cell receptor (TCR) transgenic CD4 cells responding to a tick-associated antigen. When recipient mice were infested with pathogen-free Ixodes scapularis nymphs several days prior to T cell transfer and intradermal injection of soluble cognate antigen at the feeding site, the clonotypic CD4 cells gained the ability to express the Th2 effector cytokine IL-4. Notably, this effect was not only observed in BALB/c mice predisposed towards developing Th2 responses but also in B10.D2 mice predisposed towards Th1 responsiveness. Furthermore, tick feeding was able to superimpose IL-4 expression potential onto a strong Th1 response (indicated by robust IFN-gamma expression potential) elicited by immunization with a vaccinia virus expressing the cognate antigen. The magnitude to which tick feeding was able to programme IL-4 expression potential in CD4 cells was partially reduced in mice that had been previously exposed to pathogen-free tick nymphs 6 weeks earlier, as well as when the nymphs were infected with Borrelia burgdorferi. Intradermal injection of salivary gland extract programmed IL-4 expression potential similar to that of tick infestation, suggesting that IL-4 programming activity is contained within tick saliva.

OX40 ligation enhances cell cycle turnover of Ag-activated CD4 T cells in vivo.

OX40 costimulates T cells, increases activated T cell longevity, and promotes memory acquisition. T cells activated in vivo with agonist anti-OX40 and ovalbumin have a unique pattern of survival and cell division compared to control cells, but are able to respond to recall Ag equally well. BrdU incorporation shows that early cellular division rates of the anti-OX40-treated and the control groups are similar. Nevertheless, more BrdU(+) Ag-specific T cells accumulate in lymphoid tissue upon anti-OX40 administration. Thus, OX40 ligation does not necessarily lead to increased cell cycle entry, but promotes the accumulation of dividing cells. However, CFSE staining shows that OX40 ligation allows cells to progress through more cellular division cycles, while control cells stall or die. Moreover, OX40 ligation leads to a proportional decrease in apoptotic Ag-specific T cells. Thus, OX40 ligation boosts immunity by promoting an increase in the number cell cycles completed, thereby increasing the life span of Ag-activated CD4 T cells.

Differential clonal expansion of CD4 and CD8 T cells in response to 4-1BB ligation: contribution of 4-1BB during inflammatory responses.

Cell surface proteins of the tumor necrosis factor (TNF) family of receptors have been intimately involved in inducing T cell death. A feature of these family members that is less well studied is their ability to rescue T cells from apoptosis. One such member is 4-1BB; an activation induced surface receptor on CD4 and CD8 T cells. This study demonstrates that the costimulatory effects of 4-1BB, which was found to enhance clonal expansion, required cross-linking of the receptor. The survival of the activated CD8 T cells following expansion was not associated with an increase in Bcl-2 expression. Provided that 4-1BB signaling was present, the amplification of activated CD8 T cell growth in vivo was independent of CD28 ligation. In vivo clonal expansion of activated CD4 T cells, however, was not as responsive to 4-1BB cross-linking. Moreover, 4-1BB-induced expansion was comparable to that mediated by LPS which can incite multiple costimulatory signals. Furthermore, LPS-mediated growth and survival of superantigen (SAg) stimulated T cells appeared to be partially dependent on interactions between 4-1BB and 4-1BB ligand (4-1BBL).

CTL hyporesponsiveness induced by 2,3,7, 8-tetrachlorodibenzo-p-dioxin: role of cytokines and apoptosis.

Studies have shown that blocking B7-mediated costimulation induces T cell tolerance via anergy or apoptosis. Provision of exogenous IL-2 can reverse or prevent the induction of tolerance. We have previously shown that TCDD-induced suppression of the CTL response to allogeneic P815 tumor cells is accompanied by decreased expression of CD86 (B7-2) as well as suppressed IL-2 and IFNgamma production. In the present studies, the role of IL-2 and IFNgamma and the analysis of inappropriate deletion of CD8(+) cells was examined. Administration of IL-2 on days 7-9 relative to the injection of P815 tumor cells dose-dependently increased the CTL activity and the generation of CD8(+) CTL effector cells in TCDD-treated mice. This increased CTL response was not due to recruitment of naive CTL precursors (CTLp), suggesting that a small pool of activated CTLp in TCDD-treated mice could respond to the IL-2. A much larger pool of activated CTLp in control mice was also expanded by IL-2 treatment. In contrast, treatment with IFNgamma during the same time period did not alter CTL activity in control or TCDD-treated mice. To address the possibility that insufficient IL-2 early in the response was responsible for the reduced pool of activated CTLp in TCDD-treated mice, IL-2 was administered on days 1-3 after P815 injection. However, not only did early treatment with IL-2 fail to restore the response in TCDD-treated mice, it suppressed the CTL response of non-TCDD-treated mice. To test whether exposure to TCDD induced apoptosis of activated CD8(+) T cells, phosphatidylserine (PS) expression was measured on various days after P815 tumor challenge. Surprisingly, the percentage of apoptotic CD8(+) T cells was significantly lower in TCDD-treated mice compared to controls throughout the allograft response. Similarly, exposure to TCDD failed to enhance peripheral deletion of Vbeta3(+)CD8(+) T cells after injection of the superantigen Staphylococcal enterotoxin A (SEA). Taken together, the data indicate that TCDD induces an early defect in CTLp activation that is not due to insufficient IL-2 or deletion of CD8(+) cells and may implicate a novel mechanism by which ligands of the Ah receptor disrupt CTL precursor activation.

Uncovering the differences between T cell tolerance and immunity.

In the last two decades, T cell function has been analyzed in vitro from many different angles, with a great deal of attention dedicated to the basic requirements of activation. During this time, a compendium of information has been collected and has proven to be invaluable. Paradoxically, very little is known about T cell activation and function in vivo. In the last decade, a number of models have been developed which allow the tracking of Ag-activated T cells in vivo and these studies have been instrumental in advancing the field of T cell biology. In particular, a new and emerging paradigm of T cell immunity is evolving.

Danger and OX40 receptor signaling synergize to enhance memory T cell survival by inhibiting peripheral deletion.

This report defines a cell surface receptor (OX40) expressed on effector CD4 T cells, which when engaged in conjunction with a danger signal, rescues Ag-stimulated effector cells from activation-induced cell death in vivo. Specifically, three signals were necessary to promote optimal generation of long-lived CD4 T cell memory in vivo: Ag, a danger signal (LPS), and OX40 engagement. Mice treated with Ag or superantigen (SAg) alone produced very few SAg-specific T cells. OX40 ligation or LPS stimulation, enhanced SAg-driven clonal expansion and the survival of responding T cells. However, when SAg was administered with a danger signal at the time of OX40 ligation, a synergistic effect was observed which led to a 60-fold increase in the number of long-lived, Ag-specific CD4 memory T cells. These data lay the foundation for the provision of increased numbers of memory T cells which should enhance the efficacy of vaccine strategies for infectious diseases, or cancer, while also providing a potential target (OX40) to limit the number of auto-Ag-specific memory T cells in autoimmune disease.

Development of eosinophilic airway inflammation and airway hyperresponsiveness requires interleukin-5 but not immunoglobulin E or B lymphocytes.

We previously defined a role for B cells and allergen-specific immunoglobulins in the development of allergic sensitization, airway inflammation, and airway hyperresponsiveness (AHR), using a 10-d protocol in which allergen exposure occurred exclusively via the airways, without adjuvant. In the present protocol, normal and B-cell-deficient (microMt(-/-)) mice were sensitized intraperitoneally to ovalbumin (OVA) and challenged with OVA via the airways in order to examine the requirements for AHR with this protocol. T-cell activation (antigen-specific proliferative responses and Th2-type cytokine production) and eosinophil infiltration in the peribronchial regions of the airways, with signs of eosinophil activation and degranulation, occurred in both experimental groups. In contrast to the 10-d protocol, increased in vivo airway responsiveness to methacholine and in vitro tracheal smooth-muscle responses to electrical field stimulation were observed in both normal and B-cell-deficient mice, and these responses were inhibited by anti-interleukin (IL)-5 administration before airway challenge. These data show that IL-5, but not B cells or allergen-specific IgE, are required for eosinophil airway infiltration and the development of AHR following allergen/alum sensitization and repeated airway challenge with allergen. These results emphasize that the use of different sensitization and challenge protocols can influence the requirements for development of AHR.

Ascorbic acid is a potent inhibitor of various forms of T cell apoptosis.

This study was designed to examine the effect of ascorbic acid (vitamin C) on various death pathways of mouse T cells. Unlike humans, mice produce their own ascorbic acid and our study tested the effect of additional ascorbic acid on murine T cells. Our data show that three T cell death pathways (growth factor withdrawal-, spontaneous-, and steroid-induced death) were inhibited when T cells were incubated with ascorbic acid. The data show that both activated and resting T cells were responsive to ascorbic acid since both populations were resistant to death stimuli when treated with ascorbic acid. Additionally, effector T cells were more likely to enter S phase if treated with ascorbic acid. Our data implicate ascorbic acid as a potent inhibitor of various forms of T cell death and suggest that vitamin C may function as an immune booster through this mechanism.

Cutting edge: 4-1BB is a bona fide CD8 T cell survival signal.

After recognition of Ag/MHC and ligation of a costimulatory molecule, resting T cells will clonally expand and then delete to very low levels. Previously, it was shown that deletion can be prevented by coinjection of cytokines or proinflammatory agents such as adjuvants. Here, we demonstrate that ligation of 4-1BB blocks deletion of superantigen-activated T cells in the absence of adjuvant or additional cytokine treatment. Nearly 10 times as many staphylococcal enterotoxin A-specific T cells were detected in the spleens of mice injected 21 days previously with staphylococcal enterotoxin A and an agonist anti-4-1BB Ab compared with mice given staphylococcal enterotoxin A and a control IgG. Even though both CD4- and CD8-activated T cells expressed 4-1BB, a higher proportion of CD8 T cells were rescued compared CD4 T cells. These data suggest that although 4-1BB provides costimulation, it may also promote long-term T cell survival.

CD40 activation boosts T cell immunity in vivo by enhancing T cell clonal expansion and delaying peripheral T cell deletion.

In this report we show that activation of APC with an agonist anti-CD40 mAb profoundly alters the behavior of CD4 T cells in vivo. Stimulation of mice with anti-CD40 2 days before, but not 1 day after, administration of superantigen (SAg) enhanced CD4 and CD8 T cell clonal expansion by approximately threefold. Further, CD40 activation also delayed peripheral T cell deletion after activation. Dying, activated T cells were quantitated by detecting extracellular phosphatidylserine with concomitant staining for SAg-reactive T cells using a TCR Vbeta-specific mAb. Upon close examination, it was shown that CD40 activation delayed the death of the activated T cells. Additionally, it was found that enhanced survival of CD4 T cells was equally dependent on APC expression of B7-1 and B7-2. This is in contrast to CD8 T cells, which did not depend as much on B7-1 as B7-2. Thus, CD40 activation indirectly promotes T cell growth and delays the death of SAg-stimulated CD4 T cells in vivo. These data suggest that one way CD40 activation promotes a more robust immune response is by indirectly increasing the production of effector T cells and by keeping them alive for longer periods of time.

OX-40: life beyond the effector T cell stage.

The OX-40 receptor (OX-40R) is a transmembrane protein found on the surface of activated CD4(+) T cells. When engaged by an agonist such as anti-OX-40 antibody or the OX-40 ligand (OX-40L) during antigen presentation to T cell lines, the OX-40R generates a costimulatory signal that is as potent as CD28 costimulation. Engagement of OX-40R enhances effector and memory-effector T cell function by up-regulating IL-2 production and increasing the life-span of effector T cells. We hypothesize that the signal generated by the OX-40R inhibits activation-induced T cell death (AICD) and thereby increases the number of cells differentiating from the effector to memory T cell stage. In experimental autoimmune encephalomyelitis (EAE) OX-40R+ T cells are found only within the inflammatory site [central nervous system (CNS)]. Sorting OX-40R+ T cells from the CNS of animals with EAE revealed that they are autoantigen-specific T cells. Therefore, OX-40R-specific therapies were devised to eliminate or inhibit autoreactive T cells, while sparing the remainder of the T cell repertoire. In contrast, in vivo costimulation through the OX-40R in animals with cancer generated enhanced tumor-specific immunity leading to improved tumor-free survival. Thus, manipulation of the OX-40R during inflammatory responses can alter effector CD4(+) T cell function by enhancing or limiting T cell activation and survival.

Early preferential stimulation of gamma delta T cells by TNF-alpha.

Although recent findings indicate that gamma delta T cells influence both early innate and Ag-specific adaptive host responses, it has remained unclear what triggers gamma delta T cell reactivity. Investigating very early T cell activation in mouse and human models of bacterial infection, we measured CD69 expression as an indicator of early cellular activation. Both murine alpha beta and gamma delta T cells responded polyclonally to systemic bacterial infections, and to LPS. However, gamma delta T cells responded more strongly to the bacteria and to LPS. In vitro LPS-stimulated human T cells showed a similar differential response pattern. We identified TNF-alpha as mediator of the early differential T cell activation, and of differential proliferative responses. The stronger response of gamma delta T cells to TNF-alpha was correlated with higher inducible expression levels of TNF-Rp75. Among unstimulated splenocytes, more gamma delta T cells than alpha beta T cells expressed CD44 at high levels. The data suggest that TNF-Rp75 determines the differential T cell reactivity, and that most gamma delta T cells in the normal spleen are present in a presensitized state. As TNF-alpha stimulates activated T cells, it may early preferentially connect gamma delta T cell functions with those of cells that produce this cytokine, including activated innate effector cells and Ag-stimulated T lymphocytes.

Cytokine-induced survival of activated T cells in vitro and in vivo.

Many antigen-specific T cells die after exposure to antigen in animals. These cells also die if they are isolated from animals shortly after activation and cultured. Various cytokines were tested for their ability to interfere with this in vitro death. Surprisingly, tumor necrosis factor alpha and other inflammatory cytokines did not prevent the in vitro death of activated T cells, even though these cytokines do prevent activated T cell death in animals. Therefore, the inflammatory cytokines probably act on T cells in vivo via an intermediary factor. Four cytokines, interleukin (IL)-2, IL-4, IL-7, and IL-15, did prevent activated T cell death in vitro, with IL-4 and IL-15 more effective than IL-2 or IL-7. These cytokines share a component of their receptors, the common gamma chain, gammac. Therefore, their collective ability to protect activated T cells from death may be mediated by signals involving gammac. To assess their activity in vivo, two of the cytokines, IL-2 and IL-4, were expressed in animals at local sites of superantigen responses. Both cytokines increased the numbers of T cells found at the local sites 14 days later. Interleukin 4 was more effective than IL-2, even though IL-2 stimulates T cell proliferation better than IL-4. This result suggested that IL-4 and related cytokines can promote T cell survival in vivo as well as in vitro. The ability of these cytokines to prevent the death of activated T cells may be important at certain stages of immune responses in animals.

IL-6 rescues resting mouse T cells from apoptosis.

It has previously been demonstrated that mature mouse T cells live for many weeks in vivo. In contrast, explanted lymph node or splenic T cells undergo spontaneous death within days, suggesting that survival factors supplied in vivo are not present in normal tissue culture medium. We discovered that IL-6 can rescue resting T cells from apoptosis in vitro. We show that recombinant mouse IL-6 as well as IL-6 in endothelial cell supernatants are sufficient to rescue T cells from death in the absence of additional cytokines. We show that CD4+ T cells express Bcl-2 immediately following isolation from the mouse, but after 24 h in culture Bcl-2 is undetectable. If during this time period the T cells are incubated with rIL-6, Bcl-2 expression is not down-regulated. It is, therefore, possible that IL-6 rescue from death is mediated by maintenance or induction of Bcl-2 expression. Addition of rIL-6 does not by itself induce blastogenesis or proliferation, and therefore, this cytokine appears to be a true survival factor rather than a mitogenic factor for resting T cells. Together, these results support a potential role for IL-6 as one of the factors important for prolonging resting T cell survival in vivo.

CD28 engagement and proinflammatory cytokines contribute to T cell expansion and long-term survival in vivo.

To mount a productive response to Ag, CD4+ T cells in mice must divide, differentiate, and survive at least until the Ag has been eliminated. It has been suggested that to accomplish this, T cells must receive two signals, one through their TCRs and a second through CD28. The second signal through CD28 has been thought to fulfill two roles, to stimulate T cell proliferation and to promote T cell survival. In this paper we confirm that CD28 engagement can contribute to vigorous T cell expansion in mice injected with superantigens. However, CD28 engagement does not protect T cells produced during a superantigen-specific proliferative response from undergoing subsequent deletion. Even if CD28 is bound, 4 days after superantigen exposure, the majority of T cells produced in response to superantigen exposure are eliminated in vivo. In contrast, this loss of superantigen-stimulated T cells can be prevented by the inflammatory stimuli created by injection of bacterial LPS. This protection does not require engagement of CD28 by its ligands, B7-1 and B7-2. These data suggest that productive T cell responses in mice involve a number of signals, including those initiated through TCR and CD28, which are primarily involved in the activation and expansion of T cells, and others delivered by proinflammatory cytokines that protect an activated T cell from subsequent deletion.

Allergic airway sensitization induces T cell activation but not airway hyperresponsiveness in B cell-deficient mice.

B cells play an important role in the allergic response by producing allergen-specific Igs as well as by serving as antigen-presenting cells. We studied the involvement of B cells in the development of responses in a murine model of allergic airway sensitization. Normal and B cell-deficient (muMt-/-) B10.BR mice were sensitized via the airways to ovalbumin; Ig production, cytokine elaboration from local lymph node cells, development of airway hyperresponsiveness, and histological changes in the airways were evaluated. Both strains of mice had increased production of T helper 2-like cytokines and developed an accumulation of eosinophils in the bronchial tissue after airway sensitization. However, only wild-type mice produced allergen-specific antibodies and exhibited altered airway function. B cell-deficient mice reconstituted with anti-ovalbumin IgE during the course of sensitization developed increases in airway responsiveness. These results indicated that neither B cells nor IgE were necessary for the induction of a T helper 2-type cytokine response or eosinophil infiltration of the airways after allergic sensitization but that IgE was required as a second signal for the development of airway hyperresponsiveness in this model of airway sensitization.

B cells are not essential for peripheral T-cell tolerance.

Some self-reactive T cells avoid thymic tolerance and become mature peripheral cells. Nevertheless, these cells do not usually attack their hosts because T cells can be inactivated or killed, even after they are mature, by various means. The details of these processes are not fully understood; however, a number of experiments have suggested that peripheral tolerance may be induced in mature mouse T cells by exposure to antigen on resting B cells, cells that can express antigen bound to major histocompatibility complex proteins but that lack critical costimulatory molecules such as B7-1 and B7-2. Conversely, previous experiments have indicated that mature T cells can be stimulated by exposure to antigen on cells such as dendritic cells, cells that are thought to express the essential costimulatory molecules. We tested this idea in vivo by using mice that lack B cells. Unexpectedly, T-cell tolerance and antigen-induced T-cell death occurred normally in mice free of B cells. On the other hand, antigen-specific T-cell expansion in the spleens of such mice was impaired. Finally, we have recently shown that T-cell death in mice can be prevented by exposure to antigen and an inflammatory agent such as bacterial lipopolysaccharide. This was also true in mice that lacked B cells. Overall, these data show that mature T cells can be tolerized and rescued from tolerance in the absence of B cells.

Lipopolysaccharide interferes with the induction of peripheral T cell death.

In mice injected with superantigens, T cells specific for that antigen proliferate and then die. It has been suggested that the target cells die because they encounter superantigen on the surfaces of nonprofessional presenting cells, such as B cells, which cannot deliver costimulatory signals to T cells. A number of reagents that induce costimulatory molecules on B cells were tested. Lipopolysaccharide very effectively prevented T cell death driven by superantigen. Perhaps surprisingly, the action of lipopolysaccharide was not mediated through the expected costimulatory molecule, B7. Rather, the effects of lipopolysaccharide involved the production of inflammatory cytokines, in particular TNF alpha. The rescued cells survived in vitro culture and were resistant to Fas-induced killing. These data demonstrate that LPS can block antigen-induced T cell death perhaps by interfering with Fas signaling.

Increased CD4+ T cell-dependent anti-erythrocyte antibody levels following the onset of parasite egg production in Schistosoma mansoni infected mice.

Anaemia has been reported to be a symptom of schistosomiasis mansoni. In other chronic infectious diseases, anti-red blood cell (RBC) antibodies have been suggested or shown to play a role in anaemia by participating in either complement or macrophage-dependent RBC elimination. To examine whether such a situation could be contributing to the anaemia of schistosomiasis, we examined RBC taken from infected mice for surface-bound antibodies. Our data show that prior to the onset of egg production infected mice have plasma haemoglobin levels that are indistinguishable from age matched controls (AMC). However, consistent with previous reports, following the initiation of egg laying, infected mice have significantly lower haemoglobin levels than AMC. Surface-bound IgM, IgG1 and IgG3 on RBC from infected mice increased markedly after egg laying began. Levels of RBC-associated IgG2b were similar on RBC from infected and normal mice. Antibody production against RBC was Th cell-dependent since it did not occur in mice depleted of CD4+ cells. Antibodies eluted from RBC of infected mice bound to isolated membranes of RBC from AMC and to a soluble extract of schistosome eggs. Furthermore, antibodies in serum from mice carrying patent infections bound to the membranes of RBC from normal mice. Taken together, these data suggest that schistosome eggs induce an antibody response which may cross react with a RBC surface antigen.