Costimulation via CD55 on human CD4+ T cells mediated by CD97.

Decay-accelerating factor (CD55) is a complement regulatory protein, which is expressed by most cells to protect them from complement-mediated attack. CD55 also binds CD97, an EGF-TM7 receptor constitutively expressed on granulocytes and monocytes and rapidly up-regulated on T and B cells upon activation. Early results suggested that CD55 could further enhance T cell proliferation induced by phorbol ester treatment. The present study demonstrates that coengagement of CD55, using either cross-linking mAbs or its natural ligand CD97, and CD3 results in enhanced proliferation of human peripheral blood CD4(+) T cells, expression of the activation markers CD69 and CD25, and secretion of IL-10 and GM-CSF. Recently, an increase in T cell responsiveness in CD55(-/-) mice was shown to be mediated by a lack of complement regulation. In this study, we show that direct stimulation of CD55 on CD4(+) T cells with CD97 can modulate T cell activation but does not interfere with CD55-mediated complement regulation. Our results support a multifaceted role for CD55 in human T cell activation, constituting a further link between innate and adaptive immunity.

Identification and functional characterization of a highly polymorphic region in the human TRAIL promoter in multiple sclerosis.

TNF-related apoptosis-inducing ligand (TRAIL) is not only involved in cell death but also in other immunoregulatory mechanisms. So far, the regulation of the TRAIL pathway in physiologic and pathologic conditions remains unclear. Due to the implication in brain damage and the elevated expression in peripheral immune cells of patients with multiple sclerosis (MS), an autoimmune disease of the central nervous system, TRAIL might play a central role in the pathology of this disease. Here, we have identified a highly polymorphic region in the TRAIL promoter. Using single-strand conformation polymorphism analysis, we found four single nucleotide polymorphisms (SNPs) within 111 base pairs. One of these SNPs is located in a binding site for the transcription factor AP-1. However, the RNA and protein expression of TRAIL revealed no obvious differences in relation to the genotypes. Furthermore, investigating samples from both MS patients and healthy controls we could not detect any association of these newly described polymorphisms to the clinical disease pattern. Thus, the TRAIL promoter contains a highly polymorphic area which has, however, no impact on molecule expression, and is neither directly related to increased risk of developing MS nor associated with a certain course of this heterogeneous disease in our population.

Absence of preproenkephalin increases the threshold for T cell activation.

Certain forms of the neuroendocrine hormone preproenkephalin (PPNK) are produced by T cells, B cells and macrophages. This hormone has been shown to be important in regulating a variety of immune responses; however, the basic mechanisms of this regulation are unknown. Here we examine the ability of CD8 and CD4 PPNK-deficient T lymphocytes to proliferate to antigenic and mitogenic stimuli. We found that lymphocyte activation and proliferation to suboptimal concentrations of both anti-CD3 and antigen was reduced in the absence of PPNK. Proliferation could be rescued by increasing antigen or by co-incubation of PPNK-deficient cells with wild-type cells. These data confirm the importance of neuroendocrine hormones such as PPNK in T cell activation and proliferation and provides a potential mechanism for the regulation of T cell responses by PPNK or its peptide derivatives.

Biochemical and immunological characteristics of 4-1BB (CD137) receptor and ligand and potential applications in cancer therapy.

4-1BB (CD 137) is a member of the tumor necrosis factor receptor (TNFR) superfamily that is expressed primarily on activated T cells. Crosslinking of the 4-1BB receptor activates an intracellular signal cascade that leads to the activation of NF-kappaB and costimulation of T cell growth. Recent evidence indicates that 4-1BB may preferentially costimulate CD8+ T cell growth and induce cytolytic activity. The cytolytic activity induced by 4-1BB crosslinking is able to eradicate large, well-established, poorly immunogenic tumors and augments allogenic T cell responses in vivo. The 4-1BB/4-1BB ligand costimulatory pathway can provide an alternative T cell costimulatory pathway in the absence of CD28, but may physiologically function as a synergistic or complementary pathway to the CD28 costimulatory pathway. Only some of the basic immunological functions of 4-1BB/4-IBB ligand have been elucidated and much study is required to determine its exact role in T cell activation.

Long-term inositol phosphate release, but not tyrosine kinase activity, correlates with IL-2 secretion and NF-AT induction in anti-CD3-activated peripheral human T lymphocytes.

The cascade of events within the first few minutes of T cell stimulation has been well characterized. Although many second messengers have been shown to be necessary and sufficient for T cell activation in a number of model systems, the rate-limiting step in peripheral T cells has not been demonstrated. To model effective versus ineffective CD3-mediated stimulation in peripheral T cells, we used two anti-CD3 mAbs that differ in their ability to stimulate purified T cells: OKT3, which causes early second messenger generation but is unable to activate T cells without a second signal, and 64.1, which stimulates T cell proliferation on its own. We found that tyrosine kinase activity was similar for both mAbs over a period of hours. However, the inositol phosphate response was stronger for 64.1 than for OKT3. To tie these events to gene activation, we measured NF-kappa B and NF-AT activity in the nucleus after anti-CD3 stimulation. Both stimuli induced the appearance of the NF-kappa B components (c-Rel, p65 (RelA), and p50 (NF-kappa B1)) and NF-kappa B DNA binding activity in the nucleus. However, only 64.1 induced NF-AT in the nucleus, correlating with its ability to activate T cells. Thus, NF-AT induction and IL-2 secretion were correlated with the levels of inositol phosphate release but not with gross levels of tyrosine kinase activity induced late following the response. On the other hand, NF-kappa B induction and IL-2 receptor expression occurred even with the smaller second messenger response generated by OKT3.

Cross-species reactivity of the anti-idiotype anti-OKT3 cascade between mice and humans.

The administration of murine mAb specific for the CD3 epsilon subunit of the TCR complex (OKT3) has been demonstrated to engender in humans an anti-OKT3 idiotypic cascade. This study used murine-derived anti-OKT3 (Ab2) as a bioreagent to determine whether this Ab2 and polyclonal anti-(anti-OKT3) (Ab3) generated in some human kidney transplant patients are idiotypically connected. Two anti-OKT3 mAbs G-880 (IgG1) and M-12 (IgM) were derived by immunizing BALB/c mice with the OKT3-secreting hybridoma. The two mAbs exhibited specificity for OKT3 F(ab)'2 idiotypic determinants. Both mAbs were tested for their ability to inhibit OKT3 induced mitogenesis and to block FITC-OKT3 binding to cell surface CD3 epsilon chain. The M-12 mAb inhibited OKT3-induced mitogenesis and blocked (approximately 60%) the binding of OKT3 to peripheral blood (PBL) T-cell CD3 epsilon chain in flow cytometry. In contrast, the G-880 mAb did not inhibit mitogenesis and only weakly blocked OKT3 binding to CD3 epsilon chain (approximately 12%). Sera of kidney transplant recipients who received OKT3 antirejection therapy and who developed antiidiotypic anti-OKT3 antibodies could be divided into two subgroups exhibiting anti-OKT3 activity: (a) those who had similar specificity as M-12 and failed to enhance the M-12 inhibition of OKT3 binding to PBL T-cell CD3 epsilon chain when added as a third component (n = 3), and (b) those with anti-OKT3 antibodies with idiotype specificity dissimilar to M-12 and who were able to increase the (maximum 60%) inhibition obtained with M-12 in the OKT3 to T-cell CD3-binding assay (n = 4). From these observations, we conclude that M-12 had the characteristics of an Ab2 beta and G-880 that of an Ab2 alpha. Additionally, there was an idiotypic connectivity of mouse-derived M-12 anti-OKT3 (Ab2) and OKT3-engendered human polyclonal anti-(anti-OKT3) (Ab3), in that three of seven patients examined had human serum IgG antibodies that specifically recognized M-12 idiotypic determinants as demonstrated in ELISA.

Proliferation of peripheral blood mononuclear cells from rheumatoid arthritis patients to mycobacterial antigens.

Proliferation of rheumatoid and control peripheral blood mononuclear cells (PBMC) to an antigenic acetone-precipitable extract from mycobacterium tuberculosis (MTa) was investigated. Cells were also stimulated with the recall antigen tuberculin PPD (purified protein derivative) and the mitogen OKT3. Controls had a significantly higher response to both MTa and tuberculin PPD than RA patients. However, lymphocytes from patients who had had their disease for 3-10 years proliferated more vigorously to MTa than did PBMD from patients with longer disease duration. There was no difference in the proliferation to OKT3 between patients and controls. We were not able to confirm a previously found correlation between the HLA-DR4 phenotype and lymphocyte transformation to MTa.

Human T cell activation by OKT3 is inhibited by a monoclonal antibody to CD44.

The CD44 molecule, also known as Hermes lymphocyte homing receptor, human Pgp-1, and extracellular matrix receptor III, has been shown to play a role in T cell adhesion and activation. Specifically, anti-CD44 mAb block binding of lymphocytes to high endothelial venules, inhibit T cell-E rosetting, and augment T cell proliferation induced by the CD2 or CD3-TCR pathways. We have characterized an anti-CD44 mAb (212.3) which immunoprecipitates a 90-kDa protein and is specific for CD44 as shown by peptide mapping and antibody competition studies. Interestingly, our studies with 212.3 demonstrate that this CD44-specific mAb completely inhibits T cell proliferation stimulated by the anti-CD3 mAb, OKT3. Inhibition is not a result of reduced cell viability, but is associated with 1) inhibition of IL-2 production, 2) inhibition of IL-2R expression, and 3) inhibition of OKT3-mediated increases in intracellular Ca2+ levels. In addition, 212.3 does not inhibit proliferation by the T cell mitogens PHA or PWM nor does it inhibit proliferation in a mixed lymphocyte reaction. Similar to other anti-CD44 mAb, 212.3 also augments T cell proliferation induced by mAb directed against the T11(2) and T11(3) epitopes of CD2. Thus, these studies describe a novel CD44-specific mAb (212.3) that inhibits T cell activation by OKT3 by blocking early signal transduction. Furthermore, these studies suggest that "receptor cross-talk" between the CD3-TCR complex and CD44 may regulate T cell activation.