Roland A. Newman

The transferrin receptor

Abstract The isolation and analysis of the transferrin receptor has been greatly aided by the use of monoclonal antibodies. The receptor is a disulphide-linked homo-dimer which spans the membrane and binds two molecules of transferrin. Controlling genes for this receptor in humans have been mapped to chromosome 3 using cell hybrids. The expression of transferrin receptors is related to the obligatory and ubiquitous iron requirements associated with cell proliferation or the special iron demand of haemoglobin synthesizing cells and trophoblasts. However, transferrin receptors may also be involved in cell interactions regulating cell growth.

Human MHC class II molecules as differentiation markers

DA6.231 and DA6.164 are mouse monoclonal antibodies that immunoprecipitate HLA-DR-like p34,29 glycoprotein dimers from surface- and metabolically-labeled cells. On lymphoblastoid cell lines the distribution of the 231 epitope is completely nonpolymorphic, while the 164 epitope is present on all cells except on those that are DR7 homozygous. Binding-inhibition studies show that the 231 and 164 epitopes are spatially close to each other when present on the same molecule. The mutual inhibition pattern and the absence of the 164 epitope from the 231+ cells of a few leukemia patients suggest, however, that 231 and 164 epitopes are not invariably present together. Most DR-positive cells possess 231− 164+ and 231+ 164− class 11 molecules in approximately a 2:1 ratio. This has been confirmed by immune depletion studies. Thus DA6.231 appears to define a supralocus epitope. The 164 epitope may be a marker for a subset of class 11 molecules exhibiting differential expression on various cell types immortalized by malignant transformation.

Alkali-labile oligosaccharides from glycoproteins of different erythrocyte and milk fat globule membranes

Phenol extraction of horse, sheep, cow, pig and human erythrocyte membranes and human milk fat globule membranes gave glycoprotein fractions, all of which were shown by gas chromatography to contain the reduced disaccharide beta-D-galactosyl (1-3)-N-acetyl-D-galactosaminital after treatment with alkaline borohydride. Cow and pig erythrocyte membrane glycoproteins were found however to contain much lower amounts than the erythrocyte membrane glycoproteins of the other species tested. After gel filtration, a tetrasaccharide was isolated from horse and sheep glycoproteins containing the disaccharide plus two molecules of sialic acid. Periodate oxidation together with paper chromatography of alkaline degraded fragments showed these two molecules of sialic acid to be linked to positions C3 and C6 of the galactosyl and N-acetylgalactosamine residues respectively. Evidence was obtained for a similar structure from pig and cow erythrocyte glycoproteins and human milk fat globule membrane glycoproteins although the complete structure was not elucidated. In all native glycoprotein fractions, the unsubstituted disaccharide beta-D-galactosyl (1-3)-N-acetyl-D-galactosamine was found to be present to different extents. Haemagglutination inhibition tests against human anti-T serum, Arachis hypogoea and Vicia graminea by desialylated glycoproteins showed the presence of the T-antigen, confirming the chemical findings. Inhibition was found to be proportional to the chemically detected amounts of disaccharide in each fraction. Evidence for a second carbohydrate chain in horse, sheep and human erythrocyte glycoproteins with a sialic acid substituted N-acetylgalactosamine residue as the terminal sequence was obtained using the agglutinin from Helix pomatia.

Biochemical characterisation of leukaemia-associated antigen p24 defined by the monoclonal antibody ba-2

The leukaemia-associated cell surface antigen p24/BA-2 is a single polypeptide chain with a molecular weight of 24,000. Treatment with glycosidases or exposure of cells to tunicamycin failed to show any change in the molecular weight of the antigen when examined by SDS-polyacrylamide gel electrophoresis. In addition, it failed to bind to lectin affinity columns of concanavalin A, lentil lectin or ricinus communis lectin. This is consistent with the absence of N-asparagine linked oligosaccharide chains on the antigen. Pulse-chase labelling of protein p24 shows a post-translational modification resulting in a molecular weight increase of approx. 500-1000. Alkaline treatment resulted in a decrease in molecular weight of approximately the same amount, suggesting that p24 contain some O-glycosidically linked oligosaccharide. Protein p24 has a basic pI of 7.3 which is unchanged after neuraminidase treatment. Protein P24/Ba-2 cannot be labelled by either the lipophilic photoactivatable nitrene reagent, hexanoyldiiodo-N-(4-azido-2-nitrophenyl)tyramine, or with [32P]phosphate. This suggests that the molecule is non-integral in nature and that it does not form an intimate association with the lipid matrix. Identical molecular weights, when reduced and non-reduced antigens were compared, suggest that it contains no internal disulphide linkages and failure to detect any other band on gradient gel SDS-polyacrylamide gel electrophoresis from 5-15% suggests that is is not strongly associated with any other structure.

Alkali-labile oligosaccharides from bovine milk fat globule membrane clycoprotein

Abstract Phenol extraction of bovine milk fat globule membrane gave a glycoprotein fraction which, in sodium dodecyl sulphate electrophoresis, showed three major bands, all staining for both protein and carbohydrate. Alkaline borohydride treatment and desialylation of the glycoprotein fraction released the reduced disaccharide β- d -galactosyl(1 → 3)- N- acetyl- d -galactosamine (T-antigen), which was identified by gas chromatography using a standard. All of the disaccharide units in the native glycoprotein were shown to be substituted by sialic acid, and a tetrasaccharide containing the disaccharide plus two molecules of sialic acid was isolated following alkaline borohydride treatment of the glycoprotein and gel filtration. Periodate oxidation of native and desialylated glycoprotein, together with paper chromatography of alkali degraded oligosaccharide fragments, indicated that the major alkali-labile oligosaccharide of the glycoprotein fraction is a tetrasaccharide containing β- d -galactosyl(1 → 3) -N- acetyl- d -galactosamine substituted by sialic acid at position C3 of the galactosyl and position C6 of the N- acetyl- d -galactosamine residue. Evidence was also obtained for the presence of small amounts of unsubstituted alkali-labile N- acetyl- d -galactosamine linked directly to protein in the native glycoprotein. Serological evidence using agglutinins from Vicia graminea, Arachis hypogoea and human anti-T serum confirmed the presence in the native glycoprotein of a sialic acid substituted T-antigen. Similar evidence using agglutinins from Helix pomatia and Cepaea hortensis also confirmed the presence of terminal alkali-labile N- acetyl- d -galactosamine in the native glycoprotein.

Interaction of peanut agglutinin with human lymphocytes. Binding properties and topology of the receptor site.

The relationship between the mitogenic lectin PNA and other mitogenic and non-mitogenic lectins was investigated. PNA labelled with 125I was found to bind equally well to T and B lymphocytes, after neuraminidase treatment, with 3.88 times 10(6) and 3.73 times 10(6) binding sites respectively. Only the T cell fraction was stimulated, however, and only after neuraminidase treatment. Preincubation of neuraminidase-treated cells with non-mitogenic lectins and antiserum which appeared to bind to the same receptor as PNA, enhanced the latters stimulatory properties. Capping and co-capping techniques were used to examine the topology of lectin receptors on the lymphocyte surface. The receptor glycoprotein for the mitogenic PNA lectin was found to be distinct from that possessing the Con A and PHA receptors, as well as that possessing the receptor for the non-mitogenic lectin from Helix pomatia.