CDB20:0002660 CD80 — CD28
Experimentally validated in Human; Orthology-inferred in Mouse, Rat, Frog, Chicken, Macaque, Pig, Dog, Cow, Chimp, Horse, Marmoset, Sheep
Title
Journal:; Year Published:
Abstract
Human Soluble CD80 is generated by alternative splicing, and recombinant soluble CD80 binds to CD28 and CD152 influencing T-cell activation.
Scandinavian journal of immunology, 2007; PubMed, Homo sapiens CD80 — Homo sapiens CD28
ABSTRACT: CD80 is a costimulatory factor mainly expressed on the surface of activated monocytes, B cells and dendritic cells. In this study, we demonstrate that 24% of healthy individuals have soluble forms of CD80, sCD80, in their serum. The concentration of sCD80 ranged from 0 to 1 mg/l. At the mRNA level, we detected a spliced form s1CD80 (771 bp), in unstimulated monocytes and B cells, while another form named s2CD80 (489 bp) was expressed in activated T cells as well as in freshly isolated and activated monocytes. s1CD80 lacks the transmembrane domain, and the IgC-like domain plus the transmembrane domain are spliced out of s2CD80. We also present data demonstrating that recombinant s1CD80 binds to recombinant CD152-Ig and CD28-Ig. It can also bind to T cells, preferentially to activated T cells. Recombinant sCD80 had immunomodulatory effects shown by its inhibition of the mixed lymphocyte reaction and inhibition of T-cell proliferation. sCD80 in human serum adds a new member to the family of soluble receptors, implying a network of soluble costimulatory factors with functional relevance. The inhibitory effect of the recombinant protein on T-cell activation makes it a possible candidate for treatment of diseases associated with hyperactivated T cells.
Both extracellular immunoglobin-like domains of CD80 contain residues critical for binding T cell surface receptors CTLA-4 and CD28.
The Journal of biological chemistry, 1995; PubMed, Homo sapiens CD80 — Homo sapiens CD28
ABSTRACT: The B7-related molecules CD80 and CD86 are expressed on antigen-presenting cells, bind the homologous T cell receptors CD28 and CTLA-4, and trigger costimulatory signals important for optimal T cell activation. All four molecules are immunoglobulin superfamily members, each comprising an extracellular Ig variable-like (IgV) domain, with CD80 and CD86 containing an additional Ig constant-like (IgC) domain. Despite limited sequence identity, CD80 and CD86 share similar overall receptor binding properties and effector functions. We have identified, by site-directed mutagenesis of soluble forms of CD80 and CD86, residues in both the IgV and IgC domains that are important for CTLA4Ig and CD28Ig binding. Mutagenesis in the IgV domain of CD80 identified 11 amino acids that support receptor binding. Many of these residues are conserved in the B7 family, are hydrophobic, and approximately map to the GFCC'C" beta-sheet face of an IgV fold. Mutagenesis of corresponding residues in CD86 established that some, but not all, of these residues also played a role in CD86 receptor binding. In general, mutations had a similar effect on CTLA4Ig and CD28Ig binding, thereby indicating that both receptors bind to overlapping sites on CD80 and CD86. Further, mutagenesis of several conserved residues in the ABED beta-sheet face of the IgC domain of CD80 completely ablated receptor binding. Point mutagenesis had a more pronounced effect than complete truncation of the IgC domain. Thus, full CTLA4Ig and CD28Ig binding to B7 molecules is dependent upon residues in the GFC'C" face of the IgV domain and the ABED face of the IgC domain.