N-glycosylation is required for human CD2 immunoadhesion functions.

The T-lymphocyte glycoprotein receptor, CD2, mediates cell-cell adhesion by binding to the surface molecule CD58 (LFA-3) on many cell types including antigen presenting cells. Two domains comprise the CD2 extracellular segment, with all adhesion functions localized to the amino-terminal domain that contains a single N-glycosylation site at Asn65. We have defined an important role for the N-linked glycans attached to Asn65 of this domain in mediating CD2-CD58 interactions and also characterize its N-glycotype structure. Analysis of deglycosylated soluble recombinant CD2 as well as a mutant transmembrane CD2 molecule containing a single Asn65-Gln65 substitution demonstrates that neither deglycosylated CD2 nor the mutant CD2 transmembrane receptor binds CD58 or monoclonal antibodies directed at native CD2 adhesion domain epitopes. Electrospray ionization-mass spectrometry demonstrates that high mannose oligosaccharides ((Man)nGlcNAc2, n = 5-9) are the only N-glycotypes occupying Asn65 when soluble CD2 is expressed in Chinese hamster ovary cells. Based on a model of human CD2 secondary structure, we propose that N-glycosylation is required for stabilizing domain 1 in the human receptor. Thus, N-glycosylation is essential for human CD2 adhesion functions.

Interleukin 2 receptor-targeted cytotoxicity. Receptor binding requirements for entry of a diphtheria toxin-related interleukin 2 fusion protein into cells.

The receptor binding requirements for entry of the NAD+ ADP-ribosyltransferase component of DAB486-IL 2 into target cells were examined. Experiments utilizing cell lines bearing either high-affinity or individual subunits of the interleukin 2 receptor (IL 2R) as well as human peripheral blood mononuclear cells with natural killer activity demonstrate that the high-affinity receptor facilitates delivery of fragment A from DAB486-IL 2 to the cytosol approximately 1000 times more efficiently than either the intermediate-(p75) or low-affinity (p55) forms of the IL 2R. We show that elongation factor 2 (EF-2) in these cells is not quantitatively or qualitatively altered indicating that the relative resistance to intoxication displayed by IL 2R variant cell lines cannot be attributed to an altered intracellular target of the hybrid toxin. We also demonstrate that an alteration in the binding of DAB486-IL 2 to the p75 subunit of the IL 2R may account for the selective cytotoxicity of DAB486-IL 2 for cells bearing the heterodimeric high-affinity IL 2R.

Receptor-mediated uptake of a mannose-6-phosphate bearing glycoprotein by isolated chicken osteoclasts.

We have recently shown that degradation of bone collagen by osteoclasts occurs via proteolytic enzyme activity that depends on an acidic milieu. Since bone resorption occurs in an extracellular, acidic compartment located at the cell-matrix attachment site, the osteoclast must deliver the acid collagenolytic enzymes to the cell surface. These observations raise the possibility that the mannose-6-phosphate (M-6-P) receptor, known to sort acidic proteases in other cells, is involved in trafficking lysosomal enzymes to the plasmalemma of bone resorbing cells. To this end we studied receptor-mediated uptake, distribution and release, by isolated chicken osteoclasts, of 125I-hexosaminidase, a M-6-P bearing enzyme. We found that at 4 degrees C, the bone-resorbing polykaryons bind approximately 10,000 molecules of radioligand/cell with a Kd of 0.7 nM, which is endocytosed by osteoclasts at 37 degrees C by a calcium-independent process. Furthermore, 125I-hexosaminidase uptake is unaffected by mannosylated albumin, documenting specificity of the receptor-mediated event. Release of endocytosed enzyme from the cell is also much more rapid than its degradation, attesting to a pathway of uptake and secretion. By autoradiography, the M-6-P bearing ligand is concentrated at the site of osteoclast-bone attachment. Thus, osteoclasts also have the capacity to deliver M-6-P bearing degradative enzymes to their surface at the site of matrix degradation.