Mutual Regulation Between B7-1 (CD80) Expressed on T Cells and IL-4

We have used T cells from B7-1-deficient TCR transgenic DO11.10 mice to demonstrate a functional role for B7-1 on T cells. B7-1-deficient DO11.10 T cells produce more IL-4 than wild-type DO11.10 T cells, suggesting that B7-1 expressed by T cells regulates the differentiation of IL-4-producing cells. In addition, we found that IL-4 inhibits B7-1 expression by wild-type DO11.10 T cells. Our results suggest that there is a reciprocal relationship between B7-1 expressed on T cells and IL-4 production, which results in a modulatory feedback loop. When high levels of IL-4 are produced by T cells, B7-1 expression by T cells is inhibited, which allows amplification of IL-4 production by these T cells. When low levels of IL-4 are produced by T cells, B7-1 expression by these T cells is increased, and a further reduction in IL-4 production follows. However, in addition to being influenced by IL-4, B7-1 expression by T cells is affected by peptide concentration and by B7 costimulation from APCs. The studies presented here demonstrate that B7-1 on T cells as well as on APCs regulates IL-4 production. However, whereas B7-1 expression on APCs can promote IL-4 production, IL-4 production is inhibited by B7-1 on T cells.

Human Effector Memory T Cells Express CD86: A Functional Role in Naive T Cell Priming

The glycoprotein CD86 expressed on APCs provides a costimulatory signal necessary for an efficient activation of naive T cells. In contrast, there is controversy about the condition of expression and the function of CD86 on T cells. In this study, we have analyzed the phenotype and the biological activity of CD86+ T cells generated from human PBMC. Results show that CD86 expression on T cells is induced by long term stimulation via CD3 and IL-2R and is down-regulated as the cells become quiescent. The CD86-expressing cells are memory effector T cells: 1) they express CD45RO and high levels of the activation markers CD25, CD54, and HLA-Dr; 2) they selectively express CD30, CD40-ligand, and CD70; and 3) in response to stimulation, most of them produce IFN-γ before dying by apoptosis. We then analyzed whether CD86 expressed on T cells is functional. Results show that paraformaldehyde-fixed CD86+ T cells enhance the proliferation and production of IFN-γ by anti-CD3 mAb-stimulated naive T cells and induce proliferation of resting allogenic T cells. All these effects are prevented by neutralizing anti-CD86 mAbs. In contrast, we report no autocrine effect of CD86 in CD86+ T cell activation. In conclusion, these data show that human memory effector T cells express a functional form of CD86 that can costimulate naive T cell responses.

Qualitative and Quantitative Effects of CD28/B7-Mediated Costimulation on Naive T Cells In Vitro

The CD28/B7 system provides costimulatory signals necessary for optimal T cell activation. We have examined the effects of blocking B7.1 and/or B7.2 in an in vitro system using TCR transgenic T cells specific for myelin basic protein. Activation of naive T cells was found to be B7.2 dependent and not dependent on the presence of B7.1 molecules. However, increasing the strength of signal through the TCR using peptide analogues with higher affinity for MHC compensated for blockade of B7.2 molecules, suggesting that signal 1 alone can be sufficient for the activation of naive T cells. The role of B7 molecules in the differentiation of T cells was further investigated by restimulating T cells with fresh APC and peptide in B7-sufficient conditions. A down-regulation of IL-2 and IFN-γ production by T cells primed in the presence of anti-B7.2 mAb was partially overcome when high affinity peptide analogues were used to restimulate T cells. In contrast, a significant down-regulation of the differentiation of cells producing Th-2 cytokines was observed in the presence of anti-B7 Abs. Differentiation of IL-4-secreting cells was influenced by both B7.1 and B7.2, while IL-5 secretion was totally dependent on B7.2. These results suggest that B7-mediated costimulation is essential for the development of Th-2-associated cytokines, the absence of which cannot be overcome by increasing the strength of the signal through the TCR.

Kinetics of Expression of Costimulatory Molecules and Their Ligands in Murine Relapsing Experimental Autoimmune Encephalomyelitis In Vivo

We studied the kinetics of expression of costimulatory molecules and cytokines in the central nervous system (CNS) in murine relapsing experimental autoimmune encephalomyelitis (EAE). During the natural course of EAE, B7-2 expression in the CNS correlated with clinical signs, while B7-1 was exclusively expressed during remissions. Interestingly, B7-1 was expressed on infiltrating mononuclear cells as well as neuronal cells in the CNS. In the periphery, B7-1 expression on APCs peaked with clinical disease but decreased on T cells. CD28 and CTLA4 molecules, the two known ligands for B7-1 and B7-2, had distinct expression patterns in the CNS; CD28 was highly expressed and correlated with B7-2 expression on APCs (macrophages/microglia as well as astrocytes) and with the clinical signs of EAE. CTLA4, on the other hand, was expressed by substantially fewer cells during the effector phase of disease and peaked during remission, which is consistent with the emerging role of this molecule in the termination of immune responses. The expression of CD40 and CD40L in the CNS was increased during clinical attacks. The expression of IL-12, IFN-γ, and TNF-α correlated with disease activity and severity, while TGF-β was the only factor that was up-regulated during the recovery phase. Interestingly, TGF-β was also expressed by neurons during remission. This is the first study demonstrating the kinetics of the in vivo expression of costimulatory molecules, their ligands, and cytokines in an autoimmune disease model characterized by remissions and relapses. Our data suggest that the targeting of costimulatory molecules to block an immune response must take into account the expression patterns in the target organ.

Expansion of Autoreactive T Cells in Multiple Sclerosis Is Independent of Exogenous B7 Costimulation

Multiple sclerosis (MS) is an inflammatory disease of the myelinated central nervous system that is postulated to be induced by myelin-reactive CD4 T cells. T cell activation requires an antigen-specific signal through the TCR and a costimulatory signal, which can be mediated by B7–1 or B7–2 engagement of CD28. To directly examine the activation state of myelin-reactive T cells in MS, the costimulation requirements necessary to activate myelin basic protein (MBP) or tetanus toxoid (TT)-reactive CD4 T cells were compared between normal controls and MS patients. Peripheral blood T cells were stimulated with Chinese hamster ovary (CHO) cells transfected either with DRB1*1501/DRA0101 chains (t-DR2) alone, or in combination with, B7–1 or B7–2. In the absence of costimulation, T cells from normal subjects stimulated with the recall antigen TT p830–843 were induced to expand and proliferate, but stimulation with MBP p85–99 did not have this effect. In marked contrast, T cells from patients with MS stimulated with MBP p85–99 in the absence of B7–1 or B7–2 signals expanded and proliferated. Thus, MBP-reactive CD4 T cells in patients with MS are costimulation independent and have been previously activated in vivo. These experiments provide further direct evidence for a role of activated MBP-specific CD4 T cells in the pathogenesis of MS.