Binding and cytochemical detection of cell-bound concanavalin A

We have investigated the relationship between the total amount of cell-bound concanavalin A (con A), as determined in binding experiments with ³H-conA, and the amount of cell-bound conA detected with horseradish peroxidase on normal murine fibroblasts (3T3). By comparing prefixed and non-prefixed cell membranes a discrepancy was found between the amount of cell-bound conA and the amount of cytochemically detected conA. This discrepancy was interpreted to substantiate the theory that conA binding sites can move within the membrane. Incubation of non-prefixed cells with conA induced redistribution of binding sites on the cell membrane. The redistribution resulted in changes in detectability of conA by horseradish peroxidase. The use and limitations of horseradish peroxidase in the study of cell transformation and of changes in agglutinability by conA are discussed.     

Small amount of concanavalin A modifies radiation-induced alteration in cell-surface charge depending on its binding condition

Cell electrophoretic mobility of cultured melanoma cells or rat erythrocytes decreased with time after X-irradiation. Addition of tetravalent concanavalin A or divalent succinyl-concanavalin A before (not after) irradiation, completely blocked the mobility reduction in greater concentrations than 5 μg/l.At 5 μg/1 only 3.7 · 10³ concanavalin A molecules bound to receptors per cell, while 4.18 · 10⁷ molecules/cell bound at saturating concentrations. Preincubation with concanavalin A at 37°C was effective even when the cells were treated with α-methylmannoside immediately after irradiation. At low temperature, however, concanavalin A was not effective despite a sufficient amount of bound ¹²⁵I-labelled concanavalin A. Treatment with α-methylmannoside following the binding of concanavalin A at 37°C before irradiation inhibited the concanavalin A effect depending on temperature. The residual amount of bound lectin could not account for the temperature dependence. The amount of sialic acid (the main charged substance) was not altered by X-irradiation with or without the lectin. Divalent succinyl-concanavalin A was also effective in blocking the radiation effect on electrophoretic mobility. These results seem to suggest that binding of a very small amount of concanavalin A without causing cell agglutination or clustering of its receptors, induces some alteration in the conformation of receptor glycoprotein, which blocks the internalization of acidic sugar residues by subsequent irradiation.     

The concanavalin a receptor from human erythrocytes in lipid bilayer membranes. Interaction with concanavalin A and succinyl-concanavalin A

The concanavalin A receptor from human erythrocyte membranes has been isolated by affinity chromatography using the mild, readily-dialyzable detergent dodecyltrimethylammonium bromide. The purified protein has been reincorporated into large unilamellar phospholipid vesicles using a detergent dialysis technique. The mean diameter of these vesicles increases as the lipid: protein ratio decreases. Binding of succinyl-concanavalin A to these vesicles was quantitated using ¹²⁵I-labelled lectin in a filtration assay. The concanavalin A receptor in lipid bilayer vesicles provides specific high affinity binding sites for succinyl-concanavalin A with an association constant of 2.13·10⁶ M^?1. Scatchard plots indicate positive cooperativity of binding at very low lectin concentrations, a characteristic also seen in concanavalin A binding to intact human erythrocytes. The presence of bovine serum albumin has little effect on lectin binding and is not required for expression of cooperativity. Concanavalin A effectively competes with succinyl-concanavalin A for binding to the vesicles with an association constant of 4.83·10⁶ M^?1. Receptor-bearing vesicles are readily agglutinated by concanavalin A but not by its succinylated derivative. The kinetics of vesicle agglutination are biphasic, with an initial rapid phase followed by a pseudo-first order process. We suggest that studies on reassembled receptor proteins in lipid bilayers can provide valuable insight into receptor involvement in transmembrane signalling events and the factors involved in cell membrane behaviour and cell agglutination.     

Dynamic state of concanavalin A receptor interactions on fibroblast surfaces.

Cultured normal and transformed fibroblasts were treated "in situ" by the concanavalin A-peroxidase labelling technique. It is known that peroxidase recognizes only a fraction of the bound lectin depending on the cell type. Kinetics studies revealed that 80 to 95 percent of the peroxidase and only 10 percent of the lectin are released from the cell surface when the labelled cells were reincubated at 37 degrees C. It is shown that it is mostly the concanavalin traced by peroxidase that is released and also that the lectin and the enzyme are shed as a complex or concomitantly. Consequently, the shedding pattern of the enzyme is used to demonstrate heterogeneity in the lectin binding sites; there are two main components labelled by concanavalin and peroxidase, one which has a short period (from 6 to 16 min) and another one with a much longer one (1.3 to 3 h). It is shown that when cells are incubated at 37 degrees C after a lectin treatment, secondary binding forces occur between the lectin and cell surface components which render the lectin unavailable for inhibiting sugars. Under the same conditions, some peroxidase can still be bound and a slight agglutination can still occur.     

Interactions of concanavalin A with chick embryo fibroblasts transformed by Rous sarcoma virus. Study with an RSV mutant thermosensitive for transformation.

The interactions between concanavalin A and chick embryo fibroblasts, normal and infected with Rous sarcoma virus (RSV-BH) or its thermosensitive mutant RSV-BH-Ta, have been studied. Normal chick embryo cells and RSV-BH transformed cells showed at 4 and 25 degrees C a similar number of concanavalin A receptors per cell. Analysis of the binding data by the Scatchard relation showed that apparent changes in binding as a function of temperature are due to the thermodynamic properties of the process and not to endocytosis. The lectin receptors on the cell surface of normal and RSV-BH infected cells showed homogeneity in their binding properties. Chick cells infected with RSV-BH-Ta showed a lectin binding behavior that was dependent on the temperature at which the cells were grown. At the permissive temperature for transformation (37 degrees C), the binding process was similar to that observed for normal and RSV-BH infected cells. At the nonpermissive temperature (41 degrees C), the cells showed at least two sets of concanavalin A receptors. The new set of receptors on the cell surface had a lower lectin affinity than those observed in the same cells at 37 degrees C. Chick cells infected with RSV-BH showed an enhanced agglutinability by concanavalin A, as compared with normal cells. Cells infected with RSV-BH-Ta showed a reversal of the correlation between increased concanavalin A agglutinability and the transformed state. At the permissive temperature for transformation, the cells were not agglutinable, whereas at the nonpermissive temperature they presented agglutinability indexes as high as those observed with RSV-BH infected cells. This enhanced agglutinability observed with cells maintained at the nonpermissive temperature for transformation may be related to the new set of low affinity receptors present at 41 degrees C.     

Modulation by zinc chloride of concanavalin A binding to rat thymocytes and early inhibition of lectin-induced blastogenesis.

Zinc chloride was shown to modulate the number and mobility of concanavalin A receptors of rat thymocytes at 4 °C. Zinc was able to induce the exposition at the cell surface of the same number of receptors that can be exposed by high doses of concanavalin A. It only weakly restricted their mobility. Moreover, zinc chloride was shown to inhibit rat thymocyte stimulation by succinyl-concanavalin A. This inhibition occurred most effectively if zinc was present during the first few hours after mitogen addition to cell cultures, as assessed by [³H]uridine incorporation in RNA and [³H]thymidine incorporation in DNA. The time at which DNA synthesis took place was not modified by zinc. Blast transformation in the presence of zinc was characterized by fewer blast cells which otherwise appeared identical to blast cells in control cultures. The possible action on membrane-cytoskeleton interactions is discussed.     

Interaction of concanavalin A and a divalent derivative with lymphocytes and reconstituted lymphocyte membrane glycoproteins

Both concanavalin A (con A) and its divalent derivative, succinyl-concanavalin A (S-con A) are mitogenic for porcine lymph node lymphocytes. We have compared the binding of these two lectins to intact porcine lymphocytes and phospholipid vesicles containing reconstituted lymphocyte membrane glycoproteins. Both con A and S-con A showed high- and low-affinity binding to intact cells, as indicated by LIGAND analysis of Scatchard plots of binding data. Despite the apparently identical saccharide specificities of the two lectins, high-affinity binding sites for S-con A were only one-third as numerous as high-affinity sites for the parent lectin. Large numbers of low-affinity binding sites existed for con A, while many fewer were present for S-con A. It is suggested that these sites result from hydrophobic association. Con A bound to lymphocytes in a positively cooperative fashion, while S-con A showed noncooperative behavior. Lectin binding to large unilamellar phospholipid vesicles containing reconstituted lymphocyte membrane glycoproteins was measured using a rapid filtration assay, and was linear with the glycoprotein content of the vesicles. Almost all of the outward-facing glycoprotein was functional in terms of lectin binding. Reconstituted glycoproteins showed only a single class of high-affinity binding sites for both con A and S-con A, with association constants similar to those measured for intact cells. Con A, but not S-con A, showed positively cooperative binding to reconstituted vesicles. Cooperativity was observed in both gel phase and liquid crystalline phase lipid, and was thus not dependent on long-range lateral rearrangement of glycoprotein receptors. Results suggested that con A induces a microredistribution of receptors on the lymphocyte membrane surface, leading to the exposure of glycoproteins that were previously inaccessible to the lectin. S-Con A does not cause glycoprotein redistribution, and a large fraction of the receptors remain cryptic.     

Processing of concanavalin A-receptor complexes by rat osteoclasts in vitro

The osteoclast is a large multinucleate cell that is widely accepted as the primary effector cell responsible for normal bone resorption. In a previous study, we demonstrated that concanavalin A (con A) has a dose-dependent biphasic effect on the bone-resorbing capacity of osteoclasts, using a 45Ca bone-organ culture system; bone resorption was stimulated at low concentrations and inhibited at high concentrations. The mitogenic property of con A in lymphocyte cultures is well documented; therefore con A has been used extensively to study the manner in which lymphocytes and other mononuclear cells process the cell-bound lectin. In this study, we have investigated the processing of con A-receptor complexes by osteoclasts in culture, using con A-FITC to evaluate the redistribution of cell-bound con A via epifluorescence microscopy and using con A-ferritin to determine whether the lectin receptor complexes are internalized. The osteoclasts were obtained from the long bones of newborn rats and allowed to attach to glass coverslips at 37 degrees C. Following attachment, the nonadherent cells were removed by rinsing. The adherent osteoclasts were preincubated in 50 micrograms/ml con A-FITC or con A-ferritin at 4 degrees C for 10 min, washed to remove unbound con A, and incubated at 37 degrees C for 15 or 30 min in the absence of con A. Positive controls were fixed immediately after preincubation at 4 degrees C; negative controls were preincubated in con A-FITC and alpha-methyl mannoside, the haptenic inhibitor of con A binding. The results demonstrate that redistribution and endocytosis of con A-receptor complexes occurs within 30 min. These findings confirm the hypothesis that cell-bound con A can alter the structure and activity of osteoclast membrane components in a manner similar to that observed in mononuclear cell cultures. The internalization of con A may be important in altering osteoclastic activity by mediating intracellular mechanisms involved in the bone-resorbing process.     

Relationship of prolactin receptors to concanavalin A binding.

Concanavalin A, which binds to specific carbohydrate determinants on the cell surface, was used to investigate the binding of prolactin to its receptors in liver membranes from female rats. The binding of 125I-labeled ovine prolactin to receptors was sharply inhibited by concanavalin A. This effect was reversed by the competitive sugar alpha-methyl-D-mannopyranoside and thus required the presence of specifically bound lectin. Concentrations of concanavalin A of up to 50 mu/ml caused a progressive decrease in the apparent affinity of the prolactin receptor for hormone. When higher concentrations were used, the number of available binding sites decreased. Concanavalin A-resistant receptors, about 30% of the total, had the same dissociation constant (Kd) as the controls. The binding of 125I-labeled concanavalin A in the same membrane preparations showed the presence of two distinct types of concanavalin A binding. At low concentrations, the lectin bound with high affinity (Kd approximately equal to 6.6 . 10(-8) M. At high lectin concentrations, low affinity (Kd approximately equal to 6.7 . 10(-5) M) binding predominated. Since high affinity concanavalin A binding was saturated at 50 microgram/ml, this class of binding most likely alters the affinity of the prolactin receptor for hormone; low affinity concanavalin A binding may mask prolactin receptors, making them inaccessible to the hormone. Binding sites for concanavalin A and prolactin appear to be independent but closely related since (i) concanavalin A did not displace bound prolactin from its receptor, and (ii) detergent-solubilized 125I-labeled prolactin-receptor complexes bound to concanavalin A-Sepharose and were eluted by alpha-methyl-D-mannopyranoside.     

Molecular heterogeneity of the concanavalin A tetramer: effects on binding to human red blood cells

We have found that the distribution of the three main monomer species found in tetrameric concanavalin A was approximately 73% type A monomer (27,000 MW); 4% type B monomer (14,000 MW); and 23% type C monomer (12,000 MW). When this tetrameric concanavalin A was bound to human erythrocytes and the monomer distribution of the bound concanavalin A was examined, we found that it resembled that of the concanavalin A used in the binding reaction. However, when competing sugars were used, either to inhibit the binding of concanavalin A or to remove previously-bound lectin, examination of cell-bound monomer distribution revealed that there was a significant increase in type C monomers and a simultaneous decrease in type A monomers. The shifts in monomer distribution varied depending on experimental conditions and the particular competing inhibitor employed. These findings were taken to indicate that not all concanavalin A cell surface interactions are identical and that quantitative methods are available for studying this phenomenon.     

Relationship of prolactin receptors to concanavalin A binding

Concanavalin A, which binds to specific carbohydrate determinants on the cell surface, was used to investigate the binding of prolactin to its receptors in liver membranes from female rats. The binding of ¹²⁵I-labeled ovine prolactin to receptors was sharply inhibited by concanavalin A. This effect was reversed by the competitive sugar α-methyl-D-mannopyranoside and thus required the presence of specifically bound lectin. Concentrations of concanavalin A of up to 50 μg/ml caused a progressive decrease in the apparent affinity of the prolactin receptor for hormone. When higher concentrations were used, the number of available binding sites decreased. Concanavalin A-resistant receptors, about 30% of the total, had the same dissociation constant (K_d) as the controls. The binding of ¹²⁵I-labeled concanavalin A in the same membrane preparations showed the presence of two distinct types of concanavalin A binding. At low concentrations, the lectin bound with high affinity (K_d ≈ 6.6 · 10^?8 M). At high lectin concentrations, low affinity (K_d ≈ 6.7 · 10^?5 M) binding predominated. Since high affinity concanavalin A binding was saturated at 50 μg/ml, this class of binding most likely alters the affinity of the prolactin receptor for hormone; low affinity concanavalin A binding may mask prolactin receptors, making them inaccessible to the hormone.Binding sites for concanavalin A and prolactin appear to be independent but closely related since (i) concanavalin A did not displace bound prolactin from its receptor, and (ii) detergent-solubilized ¹²⁵I-labeled prolactin-receptor complexes bound to concanavalin A-Sepharose and were eluted by α-methyl-D-mannopyranoside.     

Dynamic state of concanavalin a receptor interactions on fibroblast surfaces

Cultured normal and transformed fibroblasts were treated “in situ” by the concanavalin A-peroxidase labelling technique. It is known that peroxidase recognizes only a fraction of the bound lect in depending on the cell type. Kinetics studies revealed that 80 to 95% of the peroxidase and only 10% of the lectin are released from the cell surface when the labelled cells were reincubated at 37 °C. It is shown that it is mostly the concanavalin traced by peroxidase that is released and also that the lectin and the enzyme are shed as a complex or concomitantly. Consequently, the shedding pattern of the enzyme is used to demonstrate heterogeneity in the lectin binding sites: there are two main components labelled by concanavalin and peroxidase, one which has a short period (from 6 to 16 min) and another one with a much longer one (1.3 to 3 h).It is shown that when cells are incubated at 37 °C after a lectin treatment, secondary binding forces occur between the lectin and cell surface components which render the lectin unavailable for inhibiting sugars. Under the same conditions, some peroxidase can still be bound and a slight agglutination can still occur.     

Concanavalin A can trap insulin and increase insulin internalization into cells cultured in monolayer

When rat hepatoma cells (R-Y121B) were incubated with insulin at 37 degrees C, concanavalin A increased insulin internalization into cells. When R-Y121B cells were first incubated with labeled insulin at 4 degrees C then with concanavalin A at various concentrations at 37 degrees C, the total cellular radioactivity was much higher at high lectin concentrations than at low lectin concentrations. This increase was not only due to an increase in insulin internalization into cells but also to an increase in insulin binding to cell surfaces. Concanavalin A can trap insulin on the insulin receptors - a "trapping" effect. It has been concluded that insulin and concanavalin A binding sites are very close to each other on the insulin receptors.     

Interactions of concanavalin A with chick embryo fibroblasts transformed by rous sarcoma virus Study with an RSV mutant thermosensitive for transformation

The interactions between concanvalin A and chick embryo fibroblasts, normal and infected with Rous sarcoma virus (RSV-BH) or its thermosensitive mutant RSV-BH-Ta, have been studied. Normal chick embryo cells and RSV-BH transformed cells showed at 4 and 25 °C a similar number of concanavalin A receptors per cell. Analysis of the binding data by the Scatchard relation showed that apparent changes in binding as a function of temperature are due to the thermodynamic properties of the process and and not to endocytosis. The lectin receptors on the cell surface of normal and RSV-BH infected cells showed homogeneity in their binding properties. Chick cells infected with RSV-BH-Ta showed a lectin binding behavior that was dependent on the temperature at which the cells were grown. At the permissive temperature for transformation (37 °C), the binding process was similar to that observed for normal and RSV-BH infected cells. At the nonpermissive temperature (41 °C), the cells showed at least two sets of concanavalin A receptors. The new set of receptors on the cell surface had a lower lectin affinity than those observed in the same cells at 37 °C.Chick cells infected with RSV-BH showed an enhanced agglutinability by concanavalin A, as compared with normal cells. Cells infected with RSV-BH-Ta showed a reversal of the correlation between increased concanavalin A agglutinability and the transformed state. At the permissive temperature for transformation, the cells were not agglutinable, whereas at the nonpermissive temperature they presented agglutinability indexes as high as those observed with RSV-BH infected cells. This enhanced agglutinability observed with cells maintained at the nonpermissive temperature for transformation may be related to the new set of low affinity receptors present at 41 °C.     

Inhibition of lymphocyte 5'-nucleotidase by lectins: effects of lectin specificity and cross-linking ability

5'-Nucleotidase, an integral glycoprotein enzyme of the lymphocyte plasma membrane, is inhibited cooperatively by the lectin concanavalin A. Because divalent succinyl-concanavalin A is a poor enzyme inhibitor, both binding and lectin-induced cross-linking of 5'-nucleotidase may be necessary for inhibition. Succinyl-concanavalin A does not compete with concanavalin A for binding to the enzyme; however, maleyl-concanavalin A, another poor inhibitor, competes effectively with the parent lectin. Thus, maleyl-concanavalin A binds to the same site as concanavalin A but causes little inhibition, whereas succinyl-concanavalin A does not bind to this site. The monovalent lectin from Ricinus communis (RCA-60) is a more effective enzyme inhibitor than the related divalent lectin (RCA-120), and inactivation of the second low-affinity sugar binding site on RCA-60 does not abolish inhibition, suggesting that multivalent cross-linking is not required for 5'-nucleotidase inhibition. Peanut and wheat germ agglutinins do not inhibit the enzyme, whereas lectins from lentil, pea, soybean, Griffonia simplicifolia, and Phaseolus vulgaris inhibit 5'-nucleotidase with various degrees of effectiveness. The only lectin showing strong positive cooperativity in its interaction with 5'-nucleotidase is concanavalin A.     

Surface membrane redistribution and stabilization of concanavalin A-specific receptors following Yaba tumor poxvirus infection

Monkey kidney cells productively infected with Yaba tumor poxvirus clearly exhibit plasma membrane alterations when treated with both fluorescein-labeled and unlabeled concanavalin A. The convanavalin A-mediated cytoagglutination reaction for Yaba-infected Jinet and CV-1 cells increased linearly from 12 to 16 h post-infection, reaching a maximum by 24-28 h. Treatment of either Yaba-infected CVC-1 or Jinet cells with methyl-D-glucopyranoside before or after addition of concanavalin A completely blocked or reversed the cytoaglutination response. Trypsin treatment of uninfected CV-1 or Jinet cells enhanced concanavalin A-mediated cytoagglutination properties. Conversely, trypsin treatment of Yaba-infected Jinet cells resulted in a reduced cytoagglutination response. Increasing temperature and lectin concentration enhance concanavalin A-mediated cytoagglutination for uninfected, trypsin-treated and Yaba-infected CV-1 cells. Cytosine arabinoside has little or no effect on the Yaba-induced cell cytoagglutination reaction while cycloheximide blocks the cytoagglutinatin response if added prior to 12 h post-infection. Fluorescein-labeled concanavalin A binding studies have revealed that at 4 degrees C, Yaba-infected CV-1 cells display a predominantly 'patchy' pattern of topological fluorescence, while trypsin-treated and uninfected CV-1 cells at 4 degrees C display a uniform pattern of fluorescence binding. Patchy fluorescence, indicative of concanavalin A-suspeptible, receptor-site clustering on the surface membrane, was reduced 50% if Yaba-infected CV-1 cells were treated with glutaraldehyde (2.5%) before addition of fluorescein-labeled concanavalin A at 4 degrees C. Similar pre-fixatin of trypsin-treated CV-1 cells resulted in uniform, fluorescent labelling patterns at all assay temperatures.     

Qualitative and quantitative interactions of lectins with untreated and neuraminidase-treated normal, wild-type, and temperature-sensitive polyoma-transformed fibroblasts.

The lectin receptors of confluently grown hamster BHK, wild type polyoma virus transformed PyBHK, and temperature-sensitive polyoma transformed ts3-PyBHK fibroblasts were investigated using cell agglutination, quantitative (125I)lectin binding, and ferritin-lectin labeling. PyBHK and permissively grown ts3-PyBHK cells agglutinated more strongly with Ricinus communis I agglutinin (RCA-I)compared to BHK and nonpermissively grown ts3-PyBHK, although saturation binding of (125I)RCA-I to these cells at 4 degrees resulted in a twofold difference in lectin-binding sites on BHK and nonpermissively grown ts3-PyBHK cells (1.0-1.3 x 10 7 sites/cell) compared to PyBHK and permissively grown ts3-PyBHK (0.4-0.6 x 10 7 sites/cell). These cells bound equivalent amounts of (125I)concanavalin A (0.8-1 x 10 7 sites/cell) and (125I)wheat germ agglutinin (1-2.2 x 10 7 sites/cell). Under these binding conditions little endocytosis occurred, as judged by the subsequent release of greater than 90% cell-bound (125I)RCA-I by the RCA-I inhibitor lactose and localization of ferritin-RCA-I exclusively to the extracellular plasma membrane surface. However, if the binding is performed at 22 degrees, only 50% of the bound lectin can be removed by lactose, and ferritin-RCA-I is localized inside the cell within endocytotic vesicles. The relative mobility of RCA-I receptors was examined on ts3-PyBHK cells by the ability of ferritin-RCA-I to induce clustering of its receptors at 22 degrees. RCA-I receptors on permissively grown ts3-PyBHK cells appeared to be more mobile than on nonpermissively grown cells. BHK and PyBHK cells were treated with neuraminidase, and the resulting enzyme-treated cells were assayed for lectin agglutinability and quantitative binding of RCA-I, concanavalin A, and wheat germ agglutinin. Neuraminidase treatment resulted in decreased concanavalin A and wheat germ agglutinability and a slight increase in RCA-I agglutinability. The enzyme-treated BHK and PyBHK cells bound less (125I)wheat germ agglutinin (2.8 x 10 6 and 2.2 x 10 6 sites/cell, respectively) and 2.5 and 6.2 times more (125I)RCA-I (2.5-3 x 10 7) and 3.5-4 x 10 7 sites/per cell, respectively). There was no change in the number of concanavalin A binding sites after neuraminidase treatment. The increase in RCA-I binding sites approximated the decrease in wheat germ agglutinin binding sites indicating that the predominant penultimate oligosaccharide residue to sialic acid on these cells is D-Gal.     

Binding and uptake of concanavalin A into rat brain synaptosomes: evidence for synaptic vesicle recycling

The specific binding of radioiodinated concanavalin A (125I-con A) to rat brain synaptosomes was shown to be saturable. In the presence of excess on A binding was rapid and was completed within 5 min (t1/2 was 25 s) at 37 degrees C, and at saturation the amount bound did not change over time. Under the electron microscope, concanavalin A-ferritin (con A-ft) bound to synaptosomes in two regions: in the extra-junctional plasma membrane and within the synaptic cleft of Gray type 1 and 2 synapses. Synaptosomes incubated with con A-ft at 37 degrees C internalized bound lectin by endocytosis through coated pits. Endocytosis took place in the extra-junctional membrane, because it can occur before con A-ft has penetrated into the synaptic cleft, and continued for a considerable time (more than 30 min) after saturation of the receptor(s). Synaptic vesicles, which have at least two con A receptors on the internal aspect of their membranes, and cisternae, become labelled. When exocytosis was induced in synaptosomes by K+ depolarizations, synaptic vesicle con A receptors became incorporated into the plasma membrane and were labelled with 125I-con A causing a 2.5-fold increase in con A binding that was Ca2+ dependent. These experiments thus provide evidence for the transient incorporation of synaptic vesicle membrane glycoproteins into the plasma membrane during transmitter release.     

The inactivation by concanavalin A of the ecto-ATPase and ectoacetylcholinesterase of intact skeletal muscles

The (Ca2+ or Mg2+)-activated ectophosphohydrolase of intact frog muscle liberates, in situ, about 37 mumol inorganic phosphate/g muscle in 20 min at 20 degrees C with 10 mM ATP. Pretreatment with concanavalin A (ConA) at 4 degrees C for 18 h caused ectoenzyme inactivation which plateaued at 35-40% of the control rate. The inhibition was concentration dependent, being maximal at about 500 micrograms ConA/mL Ringer's solution. The lectin mediated its effect via the membrane glycoproteins since the inhibition was specifically prevented by alpha-methyl D-mannopyranoside. As the temperature increased from 10 to 40 degrees C, the ectoenzyme activity of untreated muscles increased linearly between 10 and 35 degrees C, with a "break point" and a clear change in slope at 35 degrees C. When treated with ConA the activity increased linearly from 10 to 40 degrees C, eliminating the transition temperature. The findings suggested that a phase transition toward fluidity in the lipid bilayer may have occurred at 35 degrees C and that this was abolished by the lectin binding. Hence we perturbed the surface membrane phospholipids of muscle pretreated with the lectin. Phospholipase C increased the activation by the lectin; phospholipase D had no effect, but phospholipase A2 completely prevented it. The lectin may require the more fluid fatty acyl chains of membrane lipids to achieve inhibition of this ecto-ATPase. Ectoacetylcholinesterase, in situ, and its inactivation by ConA were measured directly on whole, intact skeletal muscles.