The E2 antigen, a 32 kd glycoprotein involved in T-cell adhesion processes, is the MIC2 gene product.

E2 is a 32 kd human T-cell surface glycoprotein involved in spontaneous rosette formation with erythrocytes. A 1.11 kb cDNA was isolated from a lambda gt11 expression library by screening with monoclonal antibodies directed against E2. The primary structure of E2, deduced from the nucleotide sequence of its gene, comprises 185 amino acids and is devoid of N-linked glycosylation sites. The E2 protein is rich in proline residues and displays an organization typical of an integral membrane protein. Northern blotting showed a good correlation between mRNA abundance, E2 surface density and the level of T cell differentiation. In fact, nucleotide sequencing revealed that E2 is the MIC2 gene product, previously identified with the 12E7 Mab. Xg(a-) female individuals have no E2 molecule on the surface of their red cells, in contrast with Xg(a+) individuals, but have the molecule in their cytoplasm, in the form of the 28 kd precursor. These findings show that the E2 antigen, a cell surface molecule involved in T cell adhesion processes, is the product of the MIC2 gene, the only pseudoautosomal gene to be described in man.

The biochemical characterization of E2, a T cell surface molecule involved in rosettes.

We have previously identified a molecule on the T cell surface, which, in addition to CD2 is involved in the rosette phenomenon. This is a 32-kDa single polypeptide chain which we have termed E2. The studies reported here show striking patterns on the glycosylation status of E2. It is a heavily sialylated and glycosylated molecule, the sugar moieties accounting for almost half of its relative molecular mass (Mr). It carries no N-linked sugar residues, only O-linked oligosaccharides. Despite heavy glycosylation, the molecule appears to behave homogeneously on gel electrophoresis, both in terms of Mr and pI. Neuraminidase treatment of E2 lowered its Mr to 28 kDa; this was further decreased to 18 kDa after removal of O-linked sugar residues by treatment with O-glycanase. An identical reduction in size was observed after treatment with trifluoromethane sulfonic acid, showing that the molecule carries no detectable N-linked sugar residues. Moreover, endoglycosidase F and endoglycosidase H treatment of either the immunoprecipitates from 125I surface-labeled thymocytes, or of a purified preparation of E2, did not reduce the Mr of E2, nor did tunicamycin treatment of T cells. Two-dimensional gel electrophoresis revealed two discrete spots of acidic pI (4.4 and 4.6) that were still seen after neuraminidase treatment, though they had moderately shifted. Pulse-chase experiments revealed a single 28-kDa precursor form that could have been the unsialylated molecule. Finally, sequencing 14 amino acid residues of the N-terminal side revealed no homology with known proteins. Since the sugar moieties of adhesion protein could play an important role, the results obtained in this study will prove valuable to our understanding of the role exerted by the E2 molecule.

A 19-kDa human erythrocyte molecule H19 is involved in rosettes, present on nucleated cells, and required for T cell activation. Comparison of the roles of H19 and LFA-3 molecules in T cell activation.

We have previously described a molecule on the SRBC surface which, in addition to the sheep equivalent of LFA-3, is involved in the process of rosette formation. It is made of a single, 14- to 19-kDa, polypeptide chain, and we termed this molecule S14. We have now identified, on the human E a molecule with a similar Mr albeit somewhat higher (19 kDa). The mAb against H19 efficiently block autologous or homologous rosettes by binding to human E. In addition, purified H19 molecules block rosettes made with human E and SRBC in a dose-dependent manner. The H19 molecule, like LFA-3, is not limited to the E surface, but is also present on many nucleated cells, including T cells and monocytes. Moreover H19, like LFA-3, is required for T cell activation: when we stimulated whole PBMC anti-H19 blocked [H3]TdR incorporation triggered via CD3, but not via CD2, in contrast to anti-LFA-3 that inhibited activation via both pathways. When a mixture of highly purified T-PBL and autologous paraformaldehyde fixed accessory cells (AC) was cultivated, anti-H19 or anti-LFA-3 mAb bound to AC blocked T cell proliferation. When high amounts of rIL-1 (100 U/ml) were added to purified T-PBL, no AC were required to sustain their proliferation upon stimulation via CD2, contrary to stimulation via CD3. When lower amounts of rIL-1 (10 U/ml) were used, fixed AC were still necessary to sustain proliferation via CD2. In this latter situation, anti-H19 mAb bound to AC could no longer inhibit T cell proliferation, whereas the anti-LFA-3 mAb was still inhibitory. When T-PBL were stimulated via CD2 in the presence of 100 U/ml of rIL-1, anti-LFA-3 did not induce any inhibition. Thus the inhibitory effect of anti-H19 and anti-LFA-3 mAb can both be accounted for by an effect on the AC molecules only, and not on the T cell molecules. F(ab')2 fragments of anti-H19 mAb produced the same pattern of inhibition as the whole Ig molecule, excluding an effect via the FcR. Moreover, purified preparations of the H19 molecules also produced inhibition.(ABSTRACT TRUNCATED AT 400 WORDS)

A T cell surface molecule different from CD2 is involved in spontaneous rosette formation with erythrocytes.

Increasing evidence indicates that rosettes which spontaneously from between human T cells and E might be of physiologic relevance. We show here that another T cell-surface molecule than CD2 is involved in rosette formation. Four mAb have been obtained reacting with human T cells that block rosettes with E from many species, including autologous cells. They react with a molecule, we termed E2, which is actively synthetized by T and monocytic cells. Immunoprecipitation revealed a major 32-kDa band. Immunoblots revealed a major 32-kDa band and a minor 20-kDa band. This molecule was detected on all T cells tested--and present at high densities on corticothymocytes, but at low densities on medullary thymocytes. It was also found on monocytes but not on B cells. However B-CLL cells did carry this molecule. E2 molecules were also detected on nonhematologic cells. Together with the recent evidence that 3 molecules from the erythrocyte surface are also involved for rosettes, intricate molecular interactions would account for adhesion of T cells to autologous E and possibly autologous nucleated cells.