Distribution of concanavalin A binding sites on the surface of dissociated rat submandibular gland acinar cells.

The submandibular glands of 4-week-old rats were dissociated by a procedure involving digestions with collagenase and hyaluronidase, chelation of divalent cations and mechanical force. A suspension of single cells was obtained in low yield by centrifugation in a Ficoll-containing medium. Immediately after dissociation and after a culture period of 16-18 hr the dissociated cells were tested for agglutinability by concanavalin A (Con A). Using ferritin (tfer)-conjugated Con A the lectin binding by the isolated acinar cells was also studied. The dissociated cells were agglutinated by low concentrations of Con A and bound Fer-Con A molecules on their entire surface without any indication of polarization of the cell membrane. There was a considerable cell to cell variation in the amount of Fer-Con A binding which was, in general, sparse and patchy. The contact surfaces between agglutinated cells revealed a dense binding of Fer-Con A molecules irrespective of the types of cells participating in the agglutination reaction. Cells cultured for 16-18 hr were no longer agglutinated by Con A. As compared to the freshly dissociated cells the cultured acinar cells revealed a more uniform and denser binding of Fer-Con A molecules. Furthermore, there were more lectin molecules bound to the cell surface corresponding to the basal part of the cell, where the nucleus and most of the rough surface endoplasmic reticulum were located, than to the apical cell surface. It is suggested that the higher density of lectin-binding sites on the cell surface in the vicinity of the cisternae of the rough endoplasmic reticulum indicates insertion sites of newly synthesized membrane glycoproteins.     

Concanavalin A-induced impairment of fibroblast spreading on laminin but not on fibronectin

The effect of concanavalin A (Con A) on the adhesion of 8-day-old chick embryo fibroblasts (CEFs) to fibronectin (FN) and laminin (LM) was studied. Con A was shown to inhibit the spreading of CEF on a LM substrate. In contrast, no inhibition of CEF spreading on the FN substrate could be detected when the quantity of FN coated varied from 0.5 to 4 pmoles. The effect induced by Con A was specific, since it was abolished by 100 mM alpha-methylmannopyranoside. The inhibition of CEF spreading was only observed when the lectin was added during the 20 min following cell plating. In addition, the effect of Con A on CEF spreading on the LM substrate was shown to be dependent upon its presence at the cell surface, since under conditions which accelerate the uptake of the lectin, the effect on cell spreading is no longer detectable. Furthermore, the number of CEFs attached to LM was not modified by the lectin. The molecular weight of the isolated Con A binding sites revealed glycoproteins ranging from 30,000 to 72,000. On the other hand, these Con A binding sites did not interact with LM-Sepharose. Only a protein with a molecular weight of 68,000 which did not express affinity for Con A bound tightly to the LM-Sepharose. These data suggested that cell surface Con A binding sites do not interfere with the initial step of CEF adhesion to LM but play a key role during their spreading on this glycoprotein.     

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 non-cooperative 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 microre-distribution 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.     

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.     

Microtubule regulation of cell surface receptor topography during granulosa cell differentiation

Abstract. A possible role for cytoplasmic microtubules in modulating lectin binding site topography has been examined during the hormone-directed differentiation of rat ovarian granulosa cells in vitro. Indirect immunofluorescence staining with anti-tubulin antibodies indicates that undifferentiated cultured granulosa cells contain a network of microtubules which radiate from the cell center to the cell periphery. Cultures induced to differentiate by a three day treatment with 1 μg/ml prolactin exhibit a marginal distribution of microtubules and a centrally-located primary cilium. Prolactin enhances the incidence of granulosa cells containing a primary colium from 9% in undifferentiated cultures to 53% in hormone-treated cultures. The pattern of lectin binding site redistribution induced by Concanavalin A (Con A) is also modified by prolactin treatment. In contrast to undifferentiated cells, which randomly endocytose fluorescein Con A, granulosa cells exposed to prolactin respond to fluorescein Con A by forming central surface caps to a greater extent (75%) than undifferentiated controls (25%). Double label fluorescence microscopy and transmission electron microscopy on Con A labeled cells show that caps form at central cell surface sites which contain the primary cilium. Disruption of cytoplasmic microtubules by colchicine, in undifferentiated granulosa cells, results in the formation of cell surface caps upon Con A addition. These data suggest that cytoplasmic microtubules modulate the topography of lectin bindings sites which is subject to hormonal control during the in vitro differentiation of ovarian granulosa cells.     

Microtubule regulation of cell surface receptor topography during granulosa cell differentiation

A possible role for cytoplasmic microtubules in modulating lectin binding site topography has been examined during the hormone-directed differentiation of rat ovarian granulosa cells in vitro. Indirect immunofluorescence staining with anti-tubulin antibodies indicates that undifferentiated cultured granulosa cells contain a network of microtubules which radiate from the cell center to the cell periphery. Cultures induced to differentiate by a three day treatment with 1 microgram/ml prolactin exhibit a marginal distribution of microtubules and a centrally-located primary cilium. Prolactin enhances the incidence of granulosa cells containing a primary cilium from 9% in undifferentiated cultures to 53% in hormone-treated cultures. The pattern of lectin binding site redistribution induced by Concanavalin A (Con A) is also modified by prolactin treatment. In contrast to undifferentiated cells, which randomly endocytose fluorescein Con A, granulosa cells exposed to prolactin respond to fluorescein Con A by forming central surface caps to a greater extent (75%) than undifferentiated controls (25%). Double label fluorescence microscopy and transmission electron microscopy on Con A labeled cells show that caps form at central cell surface sites which contain the primary cilium. Disruption of cytoplasmic microtubules by colchicine, in undifferentiated granulosa cells, results in the formation of cell surface caps upon Con A addition. These data suggest that cytoplasmic microtubules modulate the topography of lectin bindings sites which is subject to hormonal control during the in vitro differentiation of ovarian granulosa cells.     

Differences in the redistribution of concanavalin A and wheat germ agglutinin binding sites on mouse neuroblastoma cells

Concanavalin A (Con A), wheat germ agglutinin (WGA), and Ricinus communis agglutinin (RCA) bound with either ¹²⁵I, fluorescent dyes, or fluorescent polymeric microspheres were used to quantitate and visualize the distribution of lectin binding sites on mouse neuroblastoma cells. As viewed by fluorescent light and scanning electron microscopy, over 10⁷ binding sites for Con A, WGA, and RCA appeared to be distributed randomly over the surface of differentiated and undifferentiated cells. An energy-dependent redistribution of labeled sites into a central spot occurred when the cells were labeled with a saturating dose of fluorescent lectin and maintained at 37°C for 60 min. Reversible labeling using appropriate saccharide inhibitors indicated that the labeled sites had undergone endocytosis by the cell. A difference in the mode of redistribution of WGA or RCA and Con A binding sites was observed in double labeling experiments. When less than 10% of the WGA or RCA lectin binding sites were labeled, only these labeled sites appeared to be removed from the cell surface. In contrast, when less than 10% of the Con A sites were labeled, both labeled and unlabeled Con A binding sites were removed from the cell surface. Cytochalasin B uncoupled the coordinate redistribution of labeled and unlabeled Con A sites, suggesting the involvement of microfilaments. Finally, double labeling experiments employing fluorescein-tagged Con A and rhodamine-tagged WGA indicate that most Con A and WGA binding sites reside on different membrane components and redistribute independenty of each other.     

Electron microscope study of the binding of Con A-gold to superficial and inner ectoderm layers ofXenopus laevis and its relation to the neural-inducing activity of this lectin

Summary Isolated competent amphibian ectoderm differentiates into neural (archencephalic) structures when treated with the plant lectin concanavalin A (Con A). While the inner ectoderm layer ofXenopus laevis forms brain structures after incubation with Con A, the outer ectoderm layer differentiates into ciliated epidermis only. This difference can be correlated with the pattern of Con A bound to the plasma membrane. With gold-labelled Con A it could be shown by transmission electron microscopy (TEM) that the outer ectoderm binds substantially less lectin than the inner layer. Furthermore we observed characteristic differences at the apical and basal surfaces of the cells of the same layer, i.e. on the apical cell surface of the superficial layer almost no Con A-gold could be found. In contrast, we observed a lot of gold particles on the basal cell side of the superficial layer. However, the number on both surfaces (apical and basal side of the cell) of the inner ectoderm layer was essentially higher, which could explain its biological reaction to the Con A stimulus and the differentiation into neural structures. The data presented in this paper indicate that early and late gastrula ectoderm bind similar amounts of Con A and support the view that the decrease in competence is not correlated with a loss of receptors for inducing factors. Furthermore, we describe the binding and the internalization of Con A via receptor-mediated endocytosis and the further fate of the Con A-gold-receptor complex inside the target cell.     

Lectin-mediated stimulation of DNA synthesis in cultures of embryonic neural retina cells

Plant lectins and other agents which are mitogenic for lymphocytes and fibroblasts were tested for their effects on DNA synthesis in primary monolayer cultures of neural retina cells from 10-day chick embryos. Concanavalin A (ConA), phytohemagglutinin (PHA), wheat germ agglutinin (WGA), and anti-retina cell antiserum significantly stimulated [³H]TdR incorporation; the maximum increase was reached 15 h after exposure of the cultures to these agents. Cells stimulated by ConA to synthesize DNA subsequently divided. The divalent succinyl derivative of ConA had a considerably lesser effect than the native tetramer, suggesting that cross-linking of cell surface components may be an important aspect of the changes that lead to the stimulation of DNA synthesis in these cells.Using [¹²⁵I]ConA, the average number of ConA-binding sites per 10-day retina cell was estimated to be 1.7 × 10⁶ (under the culture conditions employed); binding of the lectin to 25–50% of these sites was sufficient to elicit the maximal stimulation of DNA synthesis. Continuous association of the lectin with the cell surface for up to 8 h was essential for the maximal effect, since removal of the lectin from the cell surface (with α-methyl mannose) prior to this time reduced or prevented the stimulation of DNA synthesis.The stimulation by ConA of DNA synthesis in these cultures was dependent on the cell density and was reduced or absent at lower than optimal densities. Examination of this effect suggested that the frequency of intercellular contacts or specific cell associations play a role in the responsiveness of these cells to stimulation of DNA synthesis by ConA.     

Distribution and mobility of concanavalin a receptors on isolated guinea pig epidermal cells at various stages of differentiation

Trypsinized guinea pig epidermal cells were separated by velocity sedimentation at unit gravity. Based on the relationship between cell size and both morphological and functional aspects of differentiation, the cells were classified as lower (a diameter <12.5 μM), middle (a diameter between 12.5 and 15 μM), and upper (a diameter >15 μM) epidermal cells. Fresh cells exposed to rhodaminated concanavalin A (Con A) were sedimented and reacted with fluoresceinated anti-Con A serum to distinguish cell surface Con A from intracellular lectin. Labeling at 4°C resulted in a uniform surface distribution of Con A irrespective of cell size. After a 1-hr incubation of Con A-labeled cells in lectin-free medium at 37°C, lower epidermal cells and approximately half of middle epidermal cells internalized Con A/receptor complexes by endocytosis while lectin remained diffusely on the remainder of middle epidermal cells and upper epidermal cells. By electron microscopy, ferritin-Con A was clustered on surface areas and invaginations of the plasma membrane before being endocytosed. We concluded that the differentiation of epidermal cells was accompanied by progressive decrease in endocytosis and, most probably, mobility of Con A receptors.     

Concanavalin A-induced discharge of glycocalyx of raphidophycean flagellates, Chattonella marina and Heterosigma akashiwo

Chattonella marina and Heterosigma akashiwo, known as red tide phytoplankton, are naturally wall-less and have quite fragile cell structures. In this study, we found that an equilibrium dialysis technique allowed the study of lectin binding to these flagellates. The results suggested that concanavalin A (Con A) binds to these flagellate cells through the specific carbohydrate moieties on the cell surface. Interestingly, the binding of an excess of Con A on the cell surface caused morphological changes concomitant with discharge of glycocalyx, a polysaccharide-containing common structure on the external cell surface of these flagellates. Fluorescent microscopic observation using FITC-labeled Con A (F-Con A) confirmed that F-Con A molecules are localized on the discharged glycocalyx.     

Schistosomula of Schistosoma mansoni clear concanavalin A from their surface by sloughing

The lectin concanavalin A (Con A) was used as a model probe to study the behavior of molecules bound to the surface of recently transformed schistosomula of Schistosoma mansoni. Con A binding was saturable (150- 180 pg/organism) and specifically competed by alpha-methyl mannoside. Both FITC-Con A and 125-I-Con A were lost from the surface of schistosomula with a halftime of 8-10 h in culture in defined medium. A comparable decrease in the binding of Con A to schistosomula cultured and then labeled with the lectin indicated that the labeling procedure itself was not inducing the observed change. Internalization of Con A was not seen by either fluorescence microscopy or electron microscope radioautography. In addition, 70-80% of the radioactivity lost from the parasite was recoverable by TCA precipitation from the culture medium as intact Con A (27,000 mol wt on SDS PAGE). Thus, the mechanism of clearance of bound Con A from the surface of cultured schistosomula is apparently by sloughing of Con A molecules intact into the culture media and not by endocytosis and degradation. Con A binding sites, visualized with hemocyanin by scanning electron microscopy, appeared homogeneously distributed over the surface of schistosomula when organisms were labeled at 4 degree C or after fixation with glutaraldehyde. However, Con A and hemocyanin formed aggregates on the surface of schistosomula when labeling was performed at 37 degrees C, which suggests that lectin binding sites have lateral mobility within the plane of the membrane. These aggregates are likely independent of metabolism by the parasite because aggregation also occurs on the surface of organisms killed with azide.     

Specificity and valency of concanavalin A in neuron-substratum adhesion and redistribution of cell surface receptors

Neurons seeded in culture as spherical cells flatten partially to form lamellipodia by which they adhere to the substratum. Lamellipodium formation is stimulated specifically by concanavalin A (Con A) and other mannose-binding lectins in several types of neuronal cells, but not in similarly treated fibroblasts. Conditions that block much of the adsorption of Con A to the substratum have no effect on stimulation of lamellipodium formation by Con A. This suggests that Con A acts in solution on neurons and does not directly bind them to their substrata. Succinylated-Con A (bivalent) binds to the same receptors as native Con A (tetravalent) but does not elicit lamellipodium extension unless crosslinked with anti-Con A IgG. Treatment of neurons with Con A produces local changes in the composition of the cell surface resulting from redistribution of lectin receptor complexes. This redistribution is not as great with SCon A and, like lamellipodium formation, is sensitive to the valency of Con A. A variety of treatments (4 degrees C, trifluoperazine, nordihydroguaiaretic acid, 4-bromphenacyl bromide, and cytochalasin D), inhibit both Con A-receptor redistribution and lamellipodium extension by neurons. Other treatments (colchicine and cycloheximide) prevented neither lamellipodium formation nor redistribution.     

Inability of newt epidermal cells to migrate over concanavalin A-coated substrates

Pieces of coverslip glass coated with various proteins were implanted under one edge of a fresh skin wound on adult newt hind limbs so that the implant served as wound bed for migrating epidermal cells as they attempted to form a wound epithelium. Despite the fact that concanavalin A (Con A) receptors could be demonstrated on newt epidermal cells with fluorescein isothiocyanate (FITC)-conjugated lectin, Con A-coated implants supported practically no migration, an even poorer response than the modest amount of migration that occurred on uncoated glass. Coomassie blue staining verified that the lectin formed a complete film over the glass, and peroxidase binding assays showed that even after several hours in the wound, the Con A binding sites for mannose were still available. Migration on fibrinogen-coated glass (a good migration substrate) was not affected by placing the implants next to Con A-coated implants. Thus, the failure to migrate on Con A cannot be explained by soluble Con A effects from lectin leaching off the implants. These data suggest that linkages between cell surface mannose and the substrate are not part of the strategy by which newt epidermal cells migrate.     

Determination of mitogenic properties and lymphocyte target sites of Dolichos lablab lectin (DLA): comparative study with concanavalin A and galactose oxidase cell surface receptors

A mannoside-directed lectin has been isolated and purified from the seeds of Dolichos lablab L. by affinity chromatography. We have established that this glycoprotein, which displays high erythroagglutinating activity without blood group specificity, highly activates murine T lymphocytes, and we have described for the first time its mitogenic properties. Although its main properties are close to those of concanavalin A (Con A), the well-known mannoside-directed mitogen devoid of sugar moiety, several differences were found in some of the early events triggered by the two lectins during lymphocyte mitogenic stimulation: higher level of interleukin-2 (IL-2) synthesis, optimal dose for IL-2 synthesis at suboptimal mitogenic concentration, lack of ecto-5' nucleotidase inhibition, and lack of mitogenic inhibition at high lectin concentration. Because the two lectins did not act on the cell surface in exactly the same way, we have compared their receptors involved in mitogenesis on the plasma membrane of murine lymphocytes. We had previously established that the polyclonal activation of these cells probably occurred through high-molecular-weight receptors (200-230 kDa). Since the mitogenic stimulation of lymphocyte by galactose oxidase (GO), like that of Con A, was inhibited by DLA, we analyzed the cell surface receptors that were common to these three polyclonal mitogens. After labeling the neuraminidase/GO-treated cell surface glycoproteins with NaB3H4, we immunoprecipitated the Con A and DLA receptors which are the target of GO mitogenic action. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of the precipitates demonstrated that there exist on the lymphocyte cell surface receptors common to the polyclonal mitogens DLA, Con A, and GO. Because Con A and DLA sterically inhibit GO mitogenic stimulation, the common glycoproteins which represent the necessary sites of oxidative mitogenic action are probably those which are involved in DLA and Con A-triggered mitogenesis, despite the different properties of the two lectins. These differences could be explained by the lower molecular weight receptors of the two lectins which are not identical.     

Trypanosoma rhodesiense Bloodstream Trypomastigote and Culture Procyclic Cell Surface Carbohydrates1, 2, 3

Bloodstream trypomastigote and culture procyclic (insect midgut) forms of a cloned T. rhodesiense variant (WRATat 1) were tested for agglutination with the lectins concanavalin A (Con A), phytohemagglutinin P (PP), soybean agglutinin (SBA), fucose binding protein (FBP), wheat germ agglutinin (WGA), and castor bean lectin (RCA). Fluorescence-microscopic localization of lectin binding to both formalin-fixed trypomastigotes and red cells was determined with fluorescein isothiocyanate (FITC)-conjugated Con A, SBA, FBP, WGA, RCA, PNA (peanut agglutinin), DBA (Dolichos bifloris), and UEA (Ulex europaeus) lectins. Electron microscopic localization of lectin binding sites on bloodstream trypomastigotes was accomplished by the Con A-horseradish peroxidase-diaminobenzidine (HRP-DAB) technique, and by a Con A-biotin/avidin-ferritin method. Trypomastigotes, isolated by centrifugation or filtration through DEAE-cellulose or thawed after cryopreservation, were agglutinated by the lectins Con A and PP with agglutination strength scored as Con A < PP. No agglutination was observed in control preparations or with the lectins WGA, FBA or SBA. Red cells were agglutinated by all the lectins tested. Formalin-fixed bloodstream trypomastigotes bound FITC-Con A and FITC-RCA but not FITC-WGA, -SBA, -PNA, -UEA or -DBA lectins. All FITC-labeled lectins bound to red cells. Con A receptors, visualized by Con A-HRP-DAB and Con A-biotin/avidin-ferritin techniques, were distributed uniformly on T. rhodesiense bloodstream forms. No lectin receptors were visualized on control preparations. Culture procyclics lacked a cell surface coat and were agglutinated by Con A and WGA but not RCA, SBA, PP and FBP. Procyclics were not agglutinated by lectins in the presence of competing sugar at 0.25 M. The expression of lectin binding cell surface saccharides of T. rhodesiense WRATat 1 is related to the parasite stage. Sugars resembling α-D-mannose are on the surface of bloodstream trypomastigotes and culture procyclics; n-acetyl-D-galactosamine and D-galactose residues are on bloodstream forms; and n-acetyl-D-glucosamine-like sugars are on procyclic stages.     

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.     

Lectin-Induced Enhancement of Voltage-Dependent Calcium Flux and Calcium Channel Antagonist Binding

Concanavalin A (Con A), a tetravalent lectin with preferential affinity for mannosyl and glucosyl residues of membrane glycoconjugates, increased K+ depolarization-evoked uptake of 45Ca2+ in the PC12 neural cell line. Enhancement of uptake by Con A was concentration dependent, with maximal (24%) stimulation at 100 micrograms/ml of Con A, and was preferentially inhibited by mannoside and glucoside. Succinyl-Con A, a divalent analog with reduced biological potency, increased uptake by only 7%. The effect of Con A on 45Ca2+ uptake was dependent on membrane depolarization, was abolished by ionic Ca2+ channel blockers and organic Ca2+ channel antagonists, and was accompanied by an equivalent increase in Ca2+ channel 3H-labeled antagonist binding, observations suggesting that the voltage-dependent Ca2+ channel was the site of Ca2+ entry. The mechanism for enhancement of 45Ca2+ uptake by Con A appeared to be separate from that used by the Ca2+ channel agonist BAY K 8644 and independent of that involved in Ca2+ channel regulation by phorbol esters. These findings suggest that voltage-dependent Ca2+ channels may link cell surface carbohydrate interactions with intracellular effector processes.     

Receptor mobility and the binding of cells to lectin-coated fibers

The ability of cells to bind to nylon fibers coated with lectin molecules interspaced with varying numbers of albumin molecules has been analyzed. The cells used were lymphoma cells, normal lymphocytes, myeloid leukemia cells, and normal and transformed fibroblasts, and the fibers were coated with different densities of concanavalin A or the lectins from soybean or wheat germ. Cells fixed with glutaraldehyde did not bind to lectin-coated fibers. The number of cells bound to fibers could be increased by increasing the density of lectin molecules on the fiber, the density of specific receptors on the cell, or the mobility of the receptors. It is suggested that binding of cells to fibers involves alignment and binding of specific cell surface receptors with lectin molecules immobilized on the fibers, and that this alignment requires short-range rapid lateral mobility (RLM) of the receptors. The titration of cell binding to fibers coated with different densities of lectin and albumin has been used to measure the relative RLM of unoccupied cell surface receptors for the lectin. The results indicate a relationship of RLM to lectin-induced cell-to-cell binding. The RLM or receptors for concanavalin A (Con A) was generally found to be higher than that of receptors for the lectins from wheat germ or soybean. Receptor RLM could be decreased by use of metabolic inhibitors or by lowering the temperature. Receptors for Con A had a lower RLM on normal fibroblasts than on SV40-transformed fibroblasts, and trypsinization of normal fibroblasts increased Con A receptor RLM. Normal lymphocytes, lymphoma cells, and lines of myeloid leukemia cells that can be induced to differentiate had a high receptor RLM, whereas lines of myeloid leukemia cells that could not be induced to differentiate had a low receptor RLM. These results suggest that the RLM of Con A receptors is related to the transformation of fibroblasts and the ability of myeloid leukemia cells to undergo differentiation     

Effect of Hypoxia on Endothelial Cell Surface Glycoprotein Expression: Modulation of Glycoprotein IIIa and Other Specific Surface Glycoproteins

Exposure to hypoxia alters many aspects of endothelial cell metabolism and function; however, changes in surface glycoconjugates under these conditions have not been extensively evaluated. In the current studies, we examined surface glycoproteins of cultured bovine aortic (BAEC) and pulmonary arterial (BPAEC) endothelial cells under standard culture conditions (21% oxygen) and following exposure to hypoxia (0% oxygen) for varying time periods (30 min to 18 h) using a system of biotinylation, lectin binding (concanavalin A, Con A; Griffonia simplicifolia , GSA; Arachis hypogaea, PNA; Ricinus communis, RCA; or Triticum vulgaris, WGA), subsequent strep-avidin binding, and staining. Using these methods, we identified differences in lectin binding between the two cell types cultured in 21% oxygen with all lectins except PNA. With exposure to 0% oxygen, there was no change in lectin binding to most surface glycoproteins. Several surface glycoproteins, including glycoprotein IIIa on both cell types, demonstrated a time-dependent decrease in lectin binding; in addition, there was an increase in lectin binding to a few specific surface glycoproteins on each cell type within 30-60 min of exposure to 0% oxygen. These changes in specific surface glycoproteins were confirmed in both cell types by ¹²⁵I labeling. Increased lectin binding was observed for Con A binding BAEC glycoproteins at molecular weight (MW) 116, 130, and 205 kDa, GSA binding BAEC glycoproteins at MW 120 and 205 kDa, and RCA binding BPAEC glycoproteins at MW 140 and 205 kDa. Increased binding of WGA or PNA was not observed during exposure to hypoxia. The specificity of lectin binding was further confirmed by competitive inhibition with the appropriate sugar. These studies demonstrate that there are baseline differences between BAEC and BPAEC cell surface glycoproteins and that exposure to hypoxia is associated with little change in lectin binding to most surface glycoproteins. There is, however, increased surface expression of a few glycoproteins that differ depending of the origin of the endothelial cell. Although the mechanism of this increase in lectin binding is not yet clear, subsequent studies suggested that it is due to increased availability of select carbohydrate moieties. The time course of these alterations suggests a possible role in the endothelial cell response to decreases in ambient oxygen tension.