T-cell antigen receptor assembly and cell surface expression is not affected by treatment with T-cell antigen receptor-alpha chain transmembrane Peptide.

A synthetic peptide termed core peptide (CP), which corresponds to a specific sequence of the TCR-alpha chain transmembrane domain, is known to inhibit IL-2 production in antigen stimulated T-cells. The molecular mechanism of the TCR inhibition is not known. This study examined the effects of CP on TCR subunit assembly and TCR cell surface expression in vitro. Co-transfection experiments between TCR-alpha and CD3-delta using COS-7 cells, and the interaction between TCR-alpha and the CD3 proteins in a T-cell line (2B4) were analysed after incubation with CP or its conjugates. Results indicate that CP co-precipitates with CD3-delta and CD3-epsilon in vitro, without any effect on TCR-alpha/CD3-delta dimerisation or TCR multisubunit assembly and cell surface expression.

T-cell antigen receptor peptides inhibit signal transduction within the membrane bilayer.

Previous studies have shown that a synthetic peptide (core peptide, CP) corresponding to a 9-amino-acid region in the transmembrane domain of the alpha subunit of the T-cell antigen receptor (TCR) can suppress T-cell function in vitro and in vivo. The aim of these experiments was to determine the cellular site and molecular mechanism of CP inhibition in T cells. The cytochrome c-sensitive TCR-expressing hybridoma (2B4) was stimulated with pigeon cytochrome c antigen, anti-CD3 crosslinking, or PMA and ionomycin, in the presence or absence of CP, and the resulting IL-2 produced was measured in a bioassay using an IL-2-dependent cell line (CTLL-2). In the presence of CP, IL-2 production was inhibited following antigen-induced stimulation. By contrast, when stimulated with cross-linking antibodies to the CD3 complex or with PMA and ionomycin, both of which activate T cells downstream of the TCR antigen recognition site, CP had no effect on IL-2 production. These experiments suggest that CP interferes with TCR function by inhibiting T-cell activation at the transmembrane/receptor level. In addition, we show that CP inhibits early TCR signal transduction events such as TCR zeta chain phosphorylation following stimulation with either antigen or anti-CD3-crosslinking antibodies, although this is unlikely to be the mechanism leading to the reduced IL-2 production.