Membrane receptors for Vicia graminea anti-N lectin and its binding to native and neuraminidase-treated human erythrocytes

Abstract

Membrane receptors for Vicia graminea (Vg) lectin on human red cells were analyzed using deoxycholate lysates obtained from 125I-erythrocyte membranes incubated with a purified lectin immobilized on Sepharose 4B. The glycoproteins (GP) specifically bound to the gel were eluted and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography. Using native erythrocytes the results obtained demonstrate that N red cells have exposed Vg receptors located on GPα (synonym glycophorin A) and GPδ (synonym glycophorin B) whereas on M erythrocytes the Vg receptors are restricted to GPδ. The presence of Vg receptors was also found on the hybrid glycoprotein (made of the N-ter of GPδ and C-ter of GPα) carried by St(a+) erythrocytes. A similar amount of radioactivity was bound to Vg-Sepharose incubated with neuraminidase-treated N or M membranes. The material eluted was tentatively identified as asialo GPα and asialo GPδ, suggesting that numerous receptors have been uncovered mainly on asialo GPα species from M erythrocytes. No glycoprotein component could be identified from the material eluted from Vg Sepharose incubated with native or neuraminidase-treated membrane from a Tn(+) individual. Scatchard plot analysis obtained from binding experiments at equilibrium with M, N, and St(a+) cells revealed the existence of at least two classes of receptors both on native and neuraminidase-treated erythrocytes. Desialylation of the M, N, and St(a+) erythrocytes resulted in an increase in the number of low- and high-affinity binding sites but had no significant effect on the association constants. However, high-affinity binding constants were about six times higher with N (7.07 × 10 7 and 6.61 × 10 7 m −1 for native and neuraminidase-treated N cells, respectively) as compared to M erythrocytes (1.13 × 10 7 and 1.17 × 10 7 m −1 for native and neuraminidase-treated M cells, respectively) whereas the low-affinity binding constants were similar for all types of cells (in the range of 0.1 to 0.3 × 10 7 m −1). The number of Vg binding sites increases from 0.085 × 10 5 to 0.8 × 10 5 (high affinity) and from 2.10 × 10 5 to 6.25 × 10 5 (low affinity) per native and neuraminidase-treated N cell, respectively. On native and neuraminidase-treated M cells the number of Vg receptors increases from 0.011 × 10 5 to 0.51 × 10 5 (high affinity) and 0.13 × 10 5 (low affinity), respectively. The large increase in the number of Vg receptors on neuraminidase-treated M cells is correlated with a large increase in agglutinability. Under similar treatment St(a+) cells behave like N erythrocytes whereas only 0.16 × 10 5 Vg receptors of low affinity could be detected on neuraminidase-treated Tn erythrocytes. The results demonstrate that sialic acid is not required for binding and favor the view that the binding site of V. graminea lectin accommodates with two types of erythrocyte membrane receptors, one including both a contribution of polypeptide and oligosaccharide chains and a second which involves a simple interaction with sugar sequence Galβ1–3GalNAc available only when sialic acids are removed. The latter disaccharide is recognized by the Arachis hypogea lectin which therefore inhibits further binding of the V. graminea to neuraminidase-treated erythrocytes.