Impaired CD28-mediated co-stimulation in anergic T cells

We have investigated a CD28 co-stimulation in anergic T cellsin staphylococcal enterotoxin Binoculated mice by stimulatingthe cells with a plate-coated anti-TCR antibody in the presenceor absence of an anti-CD28 antibody. CD28 co-stimulation increasedthe levels of IL-2 and IL-4 mRNAs in nalve CD4⁺V_ß8⁺T cells. However, it did not increase the levels of IL-4 mRNAat all and only partially increased those of IL-2 mRNA in anergicT cells. It was demonstrated that CD28 co-stimulation was impairedso that it no longer stabilized cytoklne mRNAs in anergic cells.The levels of IL-4 mRNA in response to TCR stimulation werehigher in anergic T cells than those in nalve T cells in spiteof the defective CD28 co-stimulation in the former cells. Anergyinduction and generation of a T_h2-type immune response in vivoare discussed     

CD28 and T cell co-stimulation

Over the last decade the concept of T cell co-stimulation has emerged to take a central role in the process of T cell activation. However, the exact definition of co-stimulation is still unclear. In this review, we re-examine the concept of co-stimulation. We suggest that while co-stimulation is important, there is little evidence to link co-stimulation with T cell anergy. We then suggest a framework for studying co-stimulation. Focusing on recent advances in our understanding of CD28, we discuss four areas of T cell activation where co-stimulation may play a role.     

CD28 co-stimulation stabilizes the expression of the CD40 ligand on T cells

The ligand for CD40 (CD40L) is a protein which is expressed on CD4 T cells following their activation: CD40-CD40L interactions are absolutely required for the induction of T cell-dependent antibody responses, yet little is known about the mechanisms whereby CD40L+ primary T cells activate naive B cells, since the protein is only transiently expressed and is rapidly down-regulated following T cell-B cell contact. We show here, using a variety of assays, that co- stimulation of primary murine T cells via CD3 and CD28 stabilizes the expression of the CD40L protein. Firstly, T cells stimulated in this manner express higher levels of CD40L when activated in the presence of B cells, compared to CD3-activated T cells. Secondly, the CD40L expressed on CD28-co-stimulated T cells is more resistant to B cell- induced down-regulation. Finally, CD3/CD28-preactivated, rested T cells re-express higher levels of CD40L more rapidly following re-stimulation via CD3 than T cells preactivated via CD3 alone. CD3/CD28-preactivated T cells, but not CD3-activated cells, are competent to induce DNA synthesis in naive B cells, and this requires re-stimulation via CD3 and prolonged ligation of CD40. These data therefore reinforce the concept that naive T cells need to be activated initially by cognate interaction with B7-bearing antigen-presenting cells (such as dendritic cells), before becoming competent helper effector cells capable of driving B cells into proliferation via a CD40-dependent pathway.      

Positive and negative regulation of IL-12 receptor expression of naive CD4(+) T cells by CD28/CD152 co-stimulation

IL-12 is a critical cytokine for polarizing naive CD4(+) T cells toward Th1 subset. Therefore, it is important to elucidate the mechanism of IL-12R expression of naive CD4(+) T cells. In this report, we present evidence to show that expression of both IL-12Rbeta1 and beta2 mRNA is regulated by signals mediated through CD28 and CD152. Naive CD4(+) T cells stimulated with anti-CD3 alone neither expressed IL-12Rbeta2 mRNA nor bound detectable level of rIL-12, although they expressed a very low level of IL-12Rbeta1 mRNA when stimulated with a high dose of anti-CD3. Expression of IL-12Rbeta1 and beta2 mRNA was induced by the co-ligation of CD3 and CD28, and it was down-regulated by the ligation of CD152. CD28 ligation induced not only IL-12Rbeta1 and beta2 mRNA expression, but also enhanced IFN-gammaR to mediate up-regulation of IL-12R by IFN-gamma.     

Role of CD28 co-stimulation in generation and maintenance of virus-specific T cells

Efficient induction of T cell responses is normally assumed to require both TCR-mediated signaling and engagement of co-stimulatory molecules, in particular CD28. However, the importance of CD28 co-stimulation in induction and maintenance of antiviral T cell responses is not clearly established. For this reason antiviral CD4(+) and CD8(+) T cell responses in CD28-deficient mice were studied using two different viruses [vesicular stomatitis virus and lymphocytic choriomeningitis virus (LCMV)]. Intracellular cytokine staining and/or MHC-peptide tetramers were used to enumerate antigen-specific T cells. In addition, we used DNA constructs encoding viral epitopes to probe the importance of the epitope itself. Our results reveal that while the context of antigen presentation (live virus versus DNA construct) is a critical factor in determining the requirement for CD28 co-stimulation, epitope and virus dose play little if any role. Direct visualization of antigen-specific cells also confirms the notion that CD28 is more critical for the generation of antiviral T(h)1 cells than for T(c)1 cells generated in response to the same virus (LCMV). Most importantly, the present study reveals that CD28 generally is essential for the host to respond optimally over a broad set of conditions, and our results may imply that the relatively CD28 independent activation of LCMV-specific CD8(+) T cells may represent an extreme situation related to the non-cytolytic nature of this virus allowing the delivery of a uniquely strong and prolonged signal 1.     

Schiff base-mediated co-stimulation primes the T-cell-receptor-dependent calcium signalling pathway in CD4 T cells

In addition to macromolecular interactions that provide co-stimulation during antigen-presenting cell (APC) and CD4+ T-cell conjugation, covalent chemical events between specialized ligands have been implicated in T-cell co-stimulation. These take the form of transient Schiff base formation between carbonyls and amines expressed on APC and T-cell surfaces. Small Schiff base-forming molecules, such as tucaresol, can substitute for the physiological donor of carbonyl groups and provide co-stimulation to T cells, thereby functioning as orally active immunopotentiatory drugs. The Schiff base co-stimulatory pathway in T cells has been partially characterized in terms of changes in Na+ and K+ transport, and activation of the mitogen activated protein kinase (MAPK) ERK2. In the present study, the effects of Schiff base co-stimulation by tucaresol on the T-cell receptor (TCR)-dependent pathway leading to Ca2+ release were investigated. Schiff base co-stimulation by tucaresol was found to prime for enhanced TCR-dependent phospholipase C-gamma phosphorylation, inositol 1,4,5-triphosphate production, and Ca2+ mobilization that correlated with functional enhancement of interleukin-2 production in primary T cells. The effects on Ca2+ occurred comparably in Jurkat and primary CD4+ T cells responding to anti-CD3 monoclonal antibody. Enhancement of the Ca2+ response required a 10-min priming period and was prevented by prior covalent ligation of cell-surface free amino groups by sulpho-N-hydroxy succinimido-biotin; clofilium-mediated inhibition of tucaresol-induced changes in intracellular K+; and selective inhibition of the MAPK pathway. The data are consistent with a priming mechanism in which late co-stimulation-triggered events exert a positive influence on early TCR-triggered events. In additional studies of murine T cells expressing trans-gene TCRs, tucaresol was likewise shown to prime for enhanced Ca2+ mobilization in response to physiological TCR-engagement by MHC-peptide complexes.     

Requirement for CD28 co-stimulation is lower in SHP-1-deficient T cells.

This study provides biochemical and functional evidence pertaining to the role of the intracellular protein tyrosine phosphatase, SHP-1, in influencing thresholds for TCR activation. Although the loss of SHP-1 in thymocytes from motheaten mice had minimal effects on the initial rise of cytosolic Ca(2+) concentration following TCR triggering, the post-stimulation equilibrium levels of Ca(2+) were consistently elevated. In keeping with a SHP-1 effect on PLCgamma function, IP3 generation was increased in SHP-1 deficient thymocytes. Importantly, we demonstrate that loss of SHP-1 results in a relaxation of the normally stringent co-stimulatory requirements for IL-2 production. SHP-1 deficient single-positive CD4(+) thymocytes revealed a significantly enhanced capacity to produce IL-2 in response to anti-CD3 stimulation alone. In contrast, the simultaneous triggering of CD3 and CD28 was required for equivalent IL-2 production in control single-positive CD4(+) thymocytes. Furthermore, SHP-1 deficient thymocytes generated an increased and prolonged proliferative response to anti-CD3 stimulation alone. In addition, the simultaneous triggering of CD28 and CD3 resulted in equivalent proliferative responses in SHP-1-deficient and control thymocytes, suggesting that a strong co-stimulatory signal is able to override the effect of SHP-1 loss on TCR hyperresponsiveness. Collectively, these results suggest that SHP-1, rather than acting directly on TCR signaling, may indirectly raise thresholds for TCR triggering by modulating co-stimulatory signals.     

ICOS and CD28 reversely regulate IL-10 on re-activation of human effector T cells with mature dendritic cells

With newly generated ICOS-ligand (ICOS-L)-specific monoclonal antibodies we determined that human Langerhans cells in situ express similar levels of ICOS-L, CD80, and CD86, compared to immature dendritic cells (DC) derived from monocytes in vitro. Maturation of DC strongly up-regulated CD80 and CD86 but did not significantly change ICOS-L levels. On coculture of "naive"CD4(+) T cells with mature DC in the presence of superantigen, ICOS was highly up-regulated on T cells, but played only a secondary role in the CD28-dominated release of TNF-alpha and IFN-gamma, and did not participate in the induction of IL-2. Cocultures of "effector" CD4(+) T cells with mature DC revealed CD28 as the driving force for the secretion of IL-2, IFN-gamma, IL-6, and IL-13, with no apparent contribution of ICOS. In contrast, the release of IL-10 was differentially regulated. Interaction of ICOS with ICOS-L strongly promoted IL-10 secretion, whereas the CD28/B7 pathway acted as a potent attenuator of IL-10 release. Our data thus indicate a selective regulation of IL-10 secretion by ICOS on re-activation of effector T cells with professional antigen-presenting cells (bearing CD80 and CD86) in lymphoid tissue.     

Differential production of IL-10 by T cells and monocytes of HIV-infected individuals: association of IL-10 production with CD28-mediated immune responsiveness

Immune unresponsiveness in HIV-1 infection can result from impaired signals delivered by the costimulatory CD28-B7 pathway and the altered production of immunoregulatory cytokines, in particular IL-10, whose production is altered in HIV-1 infection. In this study we investigate IL-10 regulation in T cells and monocytes from HIV⁺ individuals, and its association with CD28-mediated T cell proliferation. IL-10 production as analysed in T cell- and monocyte-depleted peripheral blood mononuclear cells (PBMC), and by intracellular staining at the single-cell level, reveals a defect in IL-10 production by CD4⁺ and CD8⁺ T cells, whereas monocytes constitute the major IL-10-producing cell type. To investigate the impact of IL-10 on immune responsiveness, CD28-mediated proliferative responses in HIV⁺ individuals were correlated with PHA-induced IL-10 production. CD4⁺ T cells expressed CD28, yet exhibited markedly reduced CD28-mediated cell proliferation. This CD28-mediated CD4⁺ T cell proliferation was found to be inversely associated with the levels of PHA-induced IL-10 production and could be restored, at least in part, by anti-IL-10 antibodies. These results suggest that IL-10 production is differentially regulated in T cells and monocytes of HIV⁺ individuals, and that IL-10 may have a role in inducing immune unresponsiveness by modulating the CD28-B7 pathway.     

IL-1 acts on antigen-presenting cells to enhance the in vivo proliferation of antigen-stimulated naive CD4 T cells via a CD28-dependent mechanism that does not involve increased expression of CD28 ligands

The basis of the adjuvant effect of IL-1 on the clonal expansion of Ag-specific CD4 T cells was measured in vivo using the TCR transgenic T cell adoptive transfer method. Injection of Ag plus IL-1 caused naive CD4 T cells to proliferate to a greater extent than did injection of Ag alone. The T cells had to express CD28 to experience the beneficial effect of IL-1 whereas the host had to express the type I IL-1R, raising the possibility that IL-1's adjuvant properties were related to induction of CD28 ligands on APC. Surprisingly, however, expression of CD28 ligands on DC and B cells was not affected by IL-1. Therefore, the adjuvant properties of IL-1 depend on a basal level of CD28 signaling but cannot be explained by enhanced CD28 signaling due to CD28 ligand induction.     

Antibodies recognizing CD24 LAP epitope on human T cells enhance CD28 and IL-2 T cell proliferation

Membrane expression of the CD24 molecule on activated T lymphocytes is not elucidated fully. We previously described the intracellular and cell-surface expression of the CD24 sialic acid-dependent epitope(s) on phytohemagglutinin-activated peripheral blood mononuclear cells. However, the CD24 core protein was not detected previously on human T cells. This study reinvestigated the expression and role of CD24 in T cell subsets. We analyzed binding of anti-CD24 monoclonal antibodies (mAbs) to sialic and leucine-alanine-proline (LAP) epitopes in resting and activated, normal T lymphocytes. CD24 LAP and CD24 sialic epitopes were detected on activated CD4- and CD8-positive cells. Although expression of CD24 sialic epitopes remained stably expressed in interleukin (IL)-2-dependent cultures, T cell expression of the LAP epitope was transient. Anti-LAP antibodies strongly enhanced the response of T cells to a combination of anti-CD3/CD28 mAbs and enhanced proliferative response induced by recombinant IL-2. We found similarities in the tissue distribution and function of the human CD24 LAP molecule and the murine, heat-stable antigen, which suggests that CD24 might function as a signaling molecule on human T cells.     

CD4+ Th2 cells are directly regulated by IL-10 during allergic airway inflammation

Interleukin-10 (IL-10) is an important regulatory cytokine required to control allergy and asthma. IL-10-mediated regulation of T cell-mediated responses was previously thought to occur indirectly via antigen-presenting cells. However, IL-10 can act directly on regulatory T cells and T helper type 17 (Th17) cells. In the context of allergy, it is therefore unclear whether IL-10 can directly regulate T helper type 2 (Th2) cells and whether this is an important regulatory axis during allergic responses. We sought to determine whether IL-10 signaling in CD4⁺ Th2 cells was an important mechanism of immune regulation during airway allergy. We demonstrate that IL-10 directly limits Th2 cell differentiation and survival in vitro and in vivo. Ablation of IL-10 signaling in Th2 cells led to enhanced Th2 cell survival and exacerbated pulmonary inflammation in a murine model of house dust mite allergy. Mechanistically, IL-10R signaling regulated the expression of several genes in Th2 cells, including granzyme B. Indeed, IL-10 increased granzyme B expression in Th2 cells and led to increased Th2 cell death, identifying an IL-10-regulated granzyme B axis in Th2 cells controlling Th2 cell survival. This study provides clear evidence that IL-10 exerts direct effects on Th2 cells, regulating the survival of Th2 cells and severity of Th2-mediated allergic airway inflammation.     

Requirement of CD28-CD86 co-stimulation in the interaction between antigen-primed T helper type 2 and B cells

The interaction between CD28 and its ligands, CD80 and CD86, is crucial for an optimal activation of antigen-specific T cells. However, the requirement of CD80 or CD86 co-stimulation in Th2 cell differentiation and activation is controversial. Freshly isolated murine CD4+ and CD8+ T cells were incubated with P815 transfectants expressing a similar level of either CD80 or CD86 in the presence of anti-CD3 mAb. Both CD80 and CD86 co-stimulated the proliferation of CD4+ and CD8+ T cells at comparable time-kinetics and magnitude, but CD86 alone was able to co- stimulate IL-4 and especially IL-10 production in CD4+ T cells. In typical Th2-dependent immune responses elicited by Nippostrongylus brasillensis infection, the anti-CD86 mAb treatment but not the anti- CD80 mAb treatment efficiently inhibited antigen-specific IgE and IgG1 production, which was accompanied with the reduced IL-4 production. Our results suggest that CD86 co-stimulation plays a dominant role not only in the primary activation of Th2 cells but also in the secondary interaction between antigen-primed Th2 cells and B cells.      

Reversal of the inhibitory effects of HIV-gp120 on CD4+ T cells by stimulation through the CD28 pathway

The effects of exposure to HIV-gp120 on proliferation and cytokine production by T cell lines were investigated. T cell lines were generated by stimulation of peripheral blood mononuclear cells from several healthy donors with cross-linked anti-CD3 antibodies and IL-2. These T cell lines exhibited the characteristics of Th1 cells, producing IL-2 and interferon-gamma (IFN-γ), but not IL-4, on stimulation with anti-CD3 antibodies. In the presence of gp120, stimulation with anti-CD3 antibodies was inhibited in terms of both proliferative responses and the secretion of IL-2 and IFN-γ. Similar effects were observed when a T cell line was stimulated in the presence of a synthetic peptide representing the CD4-binding region of gp120. Neither gp120 nor the CD4-binding region peptide had any effect on IL-4 production by the T cell lines. Stimulation through the CD28 pathway partially restored both the proliferative effect and cytokine production by T cell lines in response to anti-CD3 antibodies in the presence of gp120. Anti-CD28 antibodies also partially restored cytokine production when purified CD4⁺ T cells from a T cell line were stimulated with anti-CD3 antibodies in the presence of gp120. Anti-gp120 antibodies partially or completely reversed the inhibitory effects of gp120 on T cell proliferation. These results indicate that stimulation through the CD28 pathway may restore defective CD4⁺ T cell responses in HIV-infected individuals.     

Antigen-specific targeting of CD28-mediated T cell co-stimulation using chimeric single-chain antibody variable fragment-CD28 receptors

T cells require two distinct signals for optimal activation. One is an antigen-specific signal and is provided by engagement of the T cell receptor (TCR). The second is an antigen-independent signal mediated by engagement of the T cell surface molecule CD28 with members of the B7 family. To endow CD28 molecules with antibody-type recognition, we have constructed chimeric single-chain antibody variable fragment (scFv)-CD28 molecules; following transfection of the genes encoding such constructs into the Jurkat human T cell line we show that they are stably expressed as functional cell surface receptors. These chimeric molecules have no apparent negative effects on the expression and signaling ability of the wild-type CD28 and TCR/CD3 molecules. When combined with signaling via the TCR/CD3 complex, these antigen-specific scFv-CD28 chimeric molecules provide signals similar to those elicited by the cross-linking of the unmodified CD28 molecules. Furthermore, the generation of double transfectants simultaneously expressing scFv-CD28 and scFv-CD3ζ chimeras demonstrates that antigen-specific co-stimulatory signals can also synergize with signals mediated through chimeric CD3ζ chains to secrete maximal levels of interleukin-2. Overall, our results suggest that optimal, predefined antigen-specific activation of T cells directed by the specificity of the scFv should be possible.     

CD40L stimulation of rat dendritic cells specifically favors the IL-12/IL-10 ratio resulting in a strong T cell stimulatory capacity

Dendritic cells (DC) play an important role in immune responses and have been studied extensively in human and mouse models. CD40 triggering of DC has a pivotal role in their maturation process, obtaining the unique capacity to induce strong CD4 and CD8 T cell activation. Although rat models are frequently used for the understanding of the underlying mechanism of human diseases, relatively little is known about rat DC. To investigate the effect of CD40 triggering on rat DC, we cloned the rat CD40L gene and generated murine fibroblasts with stable expression (L-rCD40L). DC stimulated by L-rCD40L cells exhibited a strong T cell stimulatory capacity, associated with higher amounts of IFN-gamma as compared to LPS-stimulated DC. Analysis of cytokine production showed that LPS induced both IL-12 and IL-10 production, whereas CD40L induced high amounts of IL-12, but little IL-10 production by rat DC. This implies that the difference found in T cell stimulatory capacity by the stimulated DC is due to the cytokine profile of the DC at the time of T cell activation.     

Effects of co-stimulation by CD58 on human T cell cytokine production: a selective cytokine pattern with induction of high IL-10 production

CD58 is the ligand for the CD2 molecule on human T cells and has been shown to provide a co-stimulatory signal for T cell activation. However, its physiological role is still unclear. We studied the effects of co-stimulation by CD58 on the production of T(h)1-type (IL-2- and IFN-gamma) or T(h)2 type (IL-4, IL-5 and IL-10) cytokines in an in vitro culture system of purified human T cells with CD58-transfected P815 cells and with anti-CD3 as the primary stimulus. Co-stimulation of T cells by CD58 potently induced IL-10 and IFN-gamma production (at the protein and at the mRNA level), and transforming growth factor-ss production (at the mRNA level), comparable to what can be found in CD80 co-stimulated T cell cultures. In contrast, we found low to absent IL-2, IL-4, IL-5, IL-13 and tumor necrosis factor-alpha production after CD58 co-stimulation, and this was not due to suppressive effects of endogenously produced IL-10. CD80 co-stimulation strongly induced all these cytokines. Intracellular staining for cytokine expression revealed the existence of a T cell subpopulation induced by CD58 co-stimulation to produce both IFN-gamma and IL-10. We furthermore found that the selective cytokine profile induced by CD58 co-stimulation is further accentuated by rIL-12 and by rIFN-alpha. Using cyclosporin A as an inhibitor of the calcineurin enzyme, we could show that production of all cytokines in this system is calcium dependent. CD58 co-stimulation thus induces a cytokine pattern corresponding to that described for T regulatory (T(r)) 1 cells and to the pattern reported to be induced by the newly identified B7 family member, B7-H1.     

Changes in the strength of co-stimulation through the B7/CD28 pathway alter functional T cell responses to altered peptide ligands

T cells require a TCR and a co-stimulatory signal for activation. We have examined the effect of the strength of TCR and co-stimulatory signals on proliferation and production of cytokines by differentiated T cell clones. The TCR signal was varied using antigen dose and altered peptide ligands. The co-stimulatory signal was varied by using as antigen-presenting cells, Chinese hamster ovary cell transfectants that express different levels of the B7-1 molecule with similar levels of MHC class II. Our results show that the level of co-stimulation has a profound effect on the response to an antigen, and that a strong co-stimulatory signal can convert a weak agonist into a full agonist and an agonist into a superagonist. Antigenicity is not absolute but a function of the strengths of the TCR and co-stimulatory signals. Increasing the strength of co-stimulation can lower antigen concentration required for maximal proliferative responses by T cell clones by 5 log. These results show that the level of expression of co-stimulatory molecules will profoundly regulate T cell clonal expansion and effector functions.