CD2 molecule

Abstract: We describe a new monoclonal murine antibody that reacts with a 50,000-mol wt polypeptide that appears to be present on all E-rosetting cells. We conclude that this antigen is either identical to or closely associated with the E receptor because of (a) the high degree of concordance between E-rosette formation and 9.6 antigen expression, (b) the inhibition of rosette formation by preincubation of cells with 9.6 antibody, and (c) the observed failure of cells lysostripped of 9.6 antigen to form E-rosettes. This last finding suggests cocapping of 9.6 antigen and the E receptor.

Abstract: Activation of resting T lymphocytes is initiated by the interaction of cell-surface receptors with their corresponding ligands. In addition to activation through the CD3 (T3)-Ti antigen-receptor complex1, recent experiments have demonstrated induction of T-cell proliferation through the CD2 (T11) molecule2–4, traditionally known as the erythrocyte(E)-receptor, through which T cells can bind red blood cells (RBC)5–7. This 'alternative pathway' of T-cell activation2 was observed in vitro in response to combinations of anti-CD2 monoclonal antibodies (mAbs) that bind to distinct epitopes of CD2, such as mAbs against T112 plus T113 (ref. 2). The physiological importance of this activation pathway can be assessed only by studying the effects of a naturally occurring ligand of CD2 on T-cell activation. We have recently described such a ligand, a glycoprotein of apparent relative molecular mass 42,000 (Mr 42K) that is expressed on all blood cells and some other tissues9,11. Here we demonstrate that binding of this cell surface molecule, termed T11 target structure or T11TS, to CD2 (T11) induces reactivity in resting T cells to a mitogenic stimulus given by a mAb to the T113 determinant or by submitogenic concentrations of anti-T112+3 mAbs. Thus, one of the signals required for T-cell activation through the alternative pathway is provided by the interaction of CD2 with a naturally occurring complementary cell-surface molecule.

Abstract: T cells may be activated either by the antigen-specific T cell receptor (TCR)-CD3 complex or the cell surface receptor CD2. A natural ligand for CD2 has been found to be lymphocyte function-associated antigen 3 (LFA-3), a widely distributed cell surface glycoprotein. To investigate the interaction of these two pathways, we have expressed the cDNA encoding the human CD2 molecule in a murine T cell hybridoma that produces IL-2 in response to HLA-DR antigens. Expression of the CD2 molecule markedly enhances IL-2 production in response to LFA-3+ antigen-bearing stimulator cells, and this stimulation is inhibited by anti-CD2 and anti-LFA-3 mAb. To further define the role of LFA-3 in antigen-dependent T cell activation, we have studied the ability of the purified ligands of CD2 and the TCR to stimulate the hybridoma. Neither liposomes containing purified HLA-DR antigens nor liposomes containing purified LFA-3 were able to stimulate the parent or the CD2+ hybridoma. However, liposomes containing both purified LFA-3 and HLA-DR, the physiological ligands for CD2 and the TCR, respectively, stimulate IL-2 production by the CD2+ but not the parent hybridoma, suggesting that complementary interactions between the TCR-CD3 complex and the CD2 pathway may regulate lymphocyte activation. To determine whether the CD2/LFA-3 interaction participates in cell-cell adhesion and provides an activation signal, we have constructed a cytoplasmic deletion mutant of CD2, CD2 delta B, in which the COOH-terminal 100 amino acids of CD2 have been replaced with a serine. Hybridomas expressing the CD2 delta B molecule were examined. Deletion of the cytoplasmic domain of CD2 did not alter binding of LFA-3 but eliminated the ability of CD2 to increase the response of the hybridoma to liposomes containing both HLA-DR and LFA-3, demonstrating that adhesion of LFA-3 to CD2 alone was insufficient for activation, and that the cytoplasmic domain was required for LFA-3 stimulation through the CD2 molecule. T cells may be activated by purified LFA-3 binding to CD2 and the TCR interacting with its ligand, and these signals appear to be synergistic for the T cell. These results suggest that the CD2/LFA-3 interaction not only plays a role in cell-cell adhesion but provides a stimulatory signal for T cell activation.

Abstract: T lymphocyte activation with monoclonal antibodies directed against the CD2 (T,p50) sheep red blood cell receptor antigen and against CD3 (T,p19,29) has been investigated. Co-stimulation of purified T lymphocytes with anti-CD3 (SP34) and anti-CD2 (9-1), which detects a unique epitope on the CD2 molecule, results in T cell activation and cell proliferation. Each antibody alone is unable to mediate this effect. Co-stimulation of purified T cells with two different anti-CD2 antibodies, 9-1 and 9.6, which detect two different epitopes on the CD2 molecule, are also mitogenic. In contrast, the combination of anti-CD3 (SP34) and anti-CD2 (9.6) cannot induce T cell activation. These data suggest that the CD2 epitope defined by the 9-1 antibody is functionally important for T cell activation via the CD3/Ti complex. Furthermore, it is demonstrated that anti-CD3 (SP34) induces epitopic modulation of the CD2 molecule, resulting in enhanced expression of the CD2, 9-1 epitope. This epitope modulation of the CD2 (9-1) epitope by anti-CD3 (SP34) occurs instantaneously at 4 degrees C and in the presence of NaN3. The functional interaction between CD3 and CD2 occurs in spite of any evidence of complex formation between these two molecules. These data suggest that the T cell differentiation antigens CD3 and CD2 are jointly involved in antigen-specific T cell activation. The data are consistent with a model for antigen-specific T cell activation involving both the CD3/Ti complex and subsequent activation of the CD2 complex T cell activation by co-stimulation with anti-CD3 (SP34) and anti-CD2 (9-1) is substantially enhanced by the addition of exogenous, purified interleukin 1 (IL 1). These data would suggest that the CD2 complex, as well as the putative IL 1 receptor, are involved in separate and complementary receptor-ligand interactions, resulting in the amplification of antigen-specific T cell responses.