CDB20:0002657 CD59 — CD2
Experimentally validated in Human; Orthology-inferred in Rat, Zebrafish, Chicken, Macaque, Pig, Dog, Cow, Chimp, Horse, Marmoset, Sheep
Title
Journal:; Year Published:
Abstract
Overlapping but nonidentical binding sites on CD2 for CD58 and a second ligand CD59.
Science, 1992; PubMed, Homo sapiens CD59 — Homo sapiens CD2
ABSTRACT: The interaction of the T cell glycoprotein CD2 with one ligand, CD58, contributes to T cell function. We have identified CD59, a glycoprotein with complement-inhibitory function, as a second physiological ligand for CD2. Antibodies to CD59 inhibit CD2-dependent T cell activation in murine T cell hybridomas expressing human CD2. In an in vitro binding assay with purified CD58 and CD59, CD2+ cells bind not only immobilized CD58 but also CD59. With two complementary approaches, it was demonstrated that the binding sites on CD2 for CD58 and CD59 are overlapping but nonidentical. These observations suggest that direct interactions between CD2 and both CD58 and CD59 contribute to T cell activation and adhesion.
CD59 molecule: a second ligand for CD2 in T cell adhesion.
European journal of immunology, 1992; PubMed, Homo sapiens CD59 — Homo sapiens CD2
ABSTRACT: The T cell surface molecule CD2 forms, with its counter-receptor CD58 (LFA-3), a powerful adhesion/activation pathway. There is some evidence that CD2 might bind more than a single ligand. Chinese hamster ovary cells (CHO) expressing human CD59 after cDNA transfection (CD59+CHO) form rosettes with human T cells; these rosettes are inhibited in a dose-dependent fashion by the CD59 monoclonal antibody (mAb) H19 and by the CD2 mAb O275 known to block natural rosettes, but not by the CD2R mAb D66, a poor rosette blocker. CD2+CHO transfectants form rosettes with human erythrocytes; these rosettes are inhibited by the CD59 mAb H19 in addition to CD2 mAb O275 and CD58 mAb; murine thymoma cells expressing human CD2 form rosettes with CD59+CHO cells that again are blocked by CD59 H19 and by CD2 O275 mAb. In a marked contrast with H19, two others CD59 mAb, YTH 53.1 and MEM 43, which react with a different epitope on CD59, led to a 50%-70% increase of the number of cells forming rosettes. In addition to rosette experiments, the binding of 125I-labeled CD59 molecules to CD2+CHO cells was specifically inhibited by unlabeled CD59 molecule and CD2 mAb. Furthermore, the binding of CD59 molecules to resting T cells induced expression of CD2R epitopes. These results directly show that CD2 binds CD59 and that subtle molecular changes occur upon binding.