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 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.     

Cooperative binding of concanavalin A to thymocytes at 4 degrees C and micro-redistribution of concanavalin A receptors.

The mode of binding of 125I-labelled concanavalin A and succinyl-concanavalin A to rat thymocytes at 4 degrees C was investigated. Simultaneously, the free binding sites of the cell-bound lectin molecules were quantified by horseradish peroxidase binding. Concanavalin A showed cooperative binding while succinyl-concanavalin A did not. The number of molecules of concanavalin A bound to the cell surface when it was saturated was twice the number of molecules of succinyl-concanavalin A. We interpret these results as showing that the binding of native concanavalin A to thymocytes at 4 degrees C brings about a cooperative modification of the membrane which leads to appearance of new receptors. Divalent succinyl-concanavalin A has no such effect. Horseradish peroxidase binding to cell-bound lectin was shown to be related to the immobilization of membrane receptors; the more they are immobilized, the more receptor-associated lectin can bind horseradish peroxidase. This allowed us to establish that post-binding events, which we called micro-redistribution, occurred at 4 degrees C when either concanavalin A or succinyl-concanavalin A binds to cells. A cooperative restriction of the micromobility of cell receptors is produced by increasing concentrations of concanavalin A. Succinyl-concanavalin A does not restrict cell receptor mobility at any concentration tested. The results are discussed in terms of cell stimulation and cell agglutination.     

Trypanosoma brucei brucei, T. brucei gambiense, and T. brucei rhodesiense: common glycoproteins and glycoprotein oligosaccharide heterogeneity identified by lectin affinity blotting and endoglycosidase H treatment

Whole cell extracts of 10 clones of bloodstream forms of African trypanosomes representing two strains of Trypanosoma brucei gambiense, one strain of T. b. rhodesiense and one strain of T. b. brucei were fractionated on sodium dodecyl sulfate-polyacrylamide gels, electrophoretically transferred to nitrocellulose paper, and probed with horseradish peroxidase conjugated lectins to detect glycoproteins. Variant specific glycoproteins of all 10 clones bound peroxidase labeled concanavalin A, but peroxidase labeled wheat germ agglutinin bound to the variant specific glycoproteins of only 3 of the 10 clones examined. In addition, 22 other glycoproteins expressed in common by all clones bound peroxidase labeled concanavalin A; 19 common glycoproteins bound peroxidase labeled wheat germ agglutinin. Lectin binding to transferred glycoproteins was specifically inhibited by appropriate monosaccharides, alpha-methyl mannoside for concanavalin A and N-acetyl glucosamine for wheat germ agglutinin. Prior incubation of blots in endo-beta-N-acetylglucosaminidase H eliminated binding of peroxidase-labeled concanavalin A to most of the 22 common glycoproteins. Two glycoproteins, designated Gp 81 and Gp 110, were the major Endoglycosidase H resistant components. Endoglycosidase H treatment also reduced binding of peroxidase labeled concanavalin A to the variant specific glycoproteins of 7 clones. The variant specific glycoproteins from the 3 clones that bound peroxidase labeled concanavalin A following enzyme treatment were those that bound peroxidase labeled wheat germ agglutinin. These results show that African trypanosomes express a greater number of glycoproteins than has been reported previously and that only a limited number of these glycoproteins bear Endoglycosidase H resistant oligosaccharides.     

Nature of the lectin-induced activation of plasma membrane Mg2+ATPase.

The Mg2+ATPase activity of liver plasma membranes decreases markedly with increasing temperature above 30 degrees. This negative temperature dependency is counteracted by the binding of wheat germ agglutinin, concanavalin A, or Ricinus communis agglutinin (at concentrations greater than or equal 0.5 mg/ml) to membranes prior to assay of the enzyme. With one of these lectins bound, the enzyme has a single energy of activation between 20 degrees and 45 degrees. The binding of dimeric succinyl concanavalin A, soybean agglutinin, fucose-binding lectin from Lotus tetragonolobus, or the leucoagglutinin from Phaseolus vulgaris does not alter the temperature dependency of the enzyme. The latter two lectins, however, do prevent the concanavalin A-induced activation of the enzyme at 37 degrees. At saturating substrate concentrations, the enzyme is not inhibited by any of the lectins tested over a wide range of concentrations. Cytochalasin B and colchicine separately or in combination have little influence on the lectin-induced enhancement of enzyme activity. Chlorpromazine and vinblastine sulfate each partially prevent the activation and in combination do so completely. Treatment of the membranes with the detergent Lubrol-PX or phospholipase A prevents activation of the enzyme by concanavalin A. The results are consistent with a restriction by the lectin of an environment which is normally too disordered for maximal enzyme activity above 30 degrees.     

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.     

Biosynthesis of L-[15N]aspartic acid and L-[15N]alanine by immobilized bacteria

Glycoproteins in nitrocellulose transfers of electrophoretically separated mixtures of cellular and viral proteins are rapidly and sensitively located by sequential incubation with the lectin concanavalin A and the enzymatically active glycoprotein horseradish peroxidase. The bound enzyme is located by incubation with a substrate which is converted to a highly insoluble colored product. The specificity of the method is demonstrated by the abolition of concanavalin A binding in the presence of α-methyl mannoside. The method is capable of detecting as little as 60 ng of a purified model glycoprotein after electrophoresis. It has been applied to the analysis of the glycoproteins of purified Lassa virus and of the virus-specific glycoproteins in Japanese encephalitis virus-infected cells.     

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 use of streptavidin-biotinylglycans as a tool for characterization of oligosaccharide-binding specificity of lectin.

A new rapid and sensitive method for characterizing lectin specificity using streptavidin-biotinylglycans as a tool is presented. This assay is analogous to enzyme immunoassay and takes advantage of the strong, irreversible adsorption of streptavidin to the wells of the chambers of titer plates. A series of streptavidin-biotinylglycans was first coated on a microtiter plate, and then one of six lectins, concanavalin A, wheat germ agglutinin, Phaseolus vulgaris (red kidney bean) erythro-agglutinin, Lens culinaris (lentil) agglutinin, Datura stramoniun agglutinin, or Sambucus nigra (elderberry bark) agglutinin coupled to horseradish peroxidase, was added. After incubation and thorough washing, only the lectin bound to a complementary glycan remained and could be detected and quantified by the peroxidase reaction. It was established that the lectins retained their oligosaccharide-binding specificities after coupling to the peroxidase, that the binding was inhibited by addition of the corresponding sugar inhibitors, and that the color intensity produced by the enzyme reaction is proportional to the amount of lectin-peroxidase bound to biotinylglycan complexed with streptavidin immobilized on the plate. As an example, it was found that the peroxidase-D. stramoniun agglutinin conjugate strongly bound biotinylglycans, GlcNAc3-Man5-R, GalGlcNAc3Man5-R, and GlcNAc3-4Man3-R (R = GlcNAc2-[6-(biotinamido)hexanoyl]-Asn). As little as 10 pmol/ml of lectin was detected. With the growing availability of biotinylglycans, the method should represent a reliable and simple procedure for screening lectin-oligosaccharide recognition qualitatively and quantitatively.     

Peroxidase binding to cell-bound Concanavalin A

The relationship between the amount of Concanavalin A bound to a cell surface and the amount of peroxidase which binds to the lectin was investigated. It was found that only a few lectin molecules are revealed by the enzyme and that this number is dependent on the cell type.     

Lectin-induced inhibition of plasma membrane 5′-nucleotidase: Sensitivity of purified enzyme

To determine whether the lectin-induced inhibition of plasma membrane 5′-nucleotidase resulted from direct interaction of the lectin with the enzyme or indirectly from a membranous change due to lectin binding to other membrane glycoproteins, the enzyme was purified and its sensitivity tested in the absence of other membrane components. A 5000 fold purification was achieved by solubilization in Lubrol PX followed by gel filtration (Sephadex G-100), anion exchange (DEAE-Biogel A) and selective adsorption (hydroxylapatite) chromatography. The purified enzyme was even more sensitive to inhibition by high concentrations of concanavalin A, wheat germ agglutinin or Rincinus communis agglutinin than was the membrane-bound enzyme indicating that inhibition is due to direct binding of the lectins to the glycoprotein enzyme itself. Divalent succinyl Con A inhibited neither form of the enzyme suggesting the need for crosslinking for inhibition by the native lectin. The purified enzyme could not be activated by low concentrations of lectins which stimulated the membrane bound enzyme.     

Binding of I-Concanavalin a and agglutination of embryonic neural retina cells : Age-dependent and experimental changes

Embryonic chick neural retina cells dissociated from retina tissue by treatment with EGTA (a calcium chelator) show an age-dependent decline in ability to agglutinate with concanavalin A (ConA). This developmental change in cell surface properties is not due to loss of ConA-binding sites, since mature retina cells can be rendered agglutinable by mild trypsinization. It is also not due to masking of ConA receptors, or to a decrease in their amount, since retina cells from late embryos (19 days) bind four times as much ¹²⁵I-ConA as cells from early embryos (8 days). Our findings lead us to suggest that, as the retina differentiates the lateral mobility of ConA receptors in the cell membrane decreases resulting in a reduction of cell agglutinability; trypsinization of late embryo retina cells increases the mobility of the receptors and thereby facilitates their clustering by the lectin into a configuration conducive to cell agglutination.The ability of late embryo (19 day) retina cells dispersed with EGTA to agglutinate with ConA could be increased by still other treatments: by pre-incubation of the cell suspension in Tyrode's balanced salt solution (1 h, 37 °C); and by brief pre-exposure to glutaraldehyde. These two treatments did not enhance cell agglutination with wheat germ agglutinin (WGA). Glutaraldehyde treatment of trypsinized cells made them agglutinable with ConA also at 4 °C; cells treated otherwise agglutinated only at higher temperature. Surface-saturation of monodispersed retina cells with ConA at 37 °C—but not at 4 °C—prevented their agglutination with this lectin, but not with WGA; this inhibition was reversible by methyl a-D-glucopyranoside (αMG).     

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.     

Use of azo dye ligand chromatography for the partial purification of a novel extracellular peroxidase from Streptomyces viridosporus T7A

Crude peroxidase preparations from the lignocellulose-degrading actinomycete, Streptomyces viridosporus T7A, were shown to decolorize several azo dye isomers and showed a correlation of dye structure to degradability similar to that shown by fungal Mn-peroxidase, an enzyme not previously described in actinomycetes. Addition of the heme-peroxidase inhibitor KCN did not significantly change the ability of the T7A enzyme(s) to decompose the dyes. These results suggest that T7A may produce a Mn- or other peroxidase with similar substrate specificity to Mn-peroxidase. Affinity chromatography using immobilized azo dye isomers was used for purifying peroxidases from T7A. A significantly purified peroxidase preparation was obtained irrespective of the azo dye used. In comparison, concanavalin A lectin affinity chromatography showed very poor binding and resolution for T7A peroxidases. Azo dye affinity purification gave preparations sufficiently purified to allow amino acid microsequencing for two of the bound proteins. N-terminal amino acid sequences were found to share significant homology with a fungal Mn-peroxidase and actinomycete cellulases. Received: 20 May 1997 / Received revision: 17 December 1997 / Accepted: 2 January 1998     

Binding of plasma fibronectin to the surfaces of BHK cells in suspension at 4 °C

Plasma fibronectin is shown by several different criteria to bind to suspended BHK cells if the binding incubations are carried out at 4 °C. In indirect immunofluorescence experiments, fibronectin bound to suspended BHK cells at 4 °C in a punctate distribution over the entire cell surfaces. Little binding, however, was detected on cells incubated with fibronectin at 37 °C. The fibronectin bound to the cells at 4 °C was functionally active, since these cells subsequently were able to spread on tissue culture dishes in protein-free medium, unlike cells preincubated with fibronectin at 37 °C or in the absence of fibronectin. Also, the cell surface receptors for soluble fibronectin and fibronectin-coated beads appeared to be similar, since cells preincubated with fibronectin at 4 °C subsequently bound fewer fibronectin-coated beads than control cells. In biochemical studies with radiolabeled fibronectin, binding of fibronectin to the cells was shown to increase with incubation time up to 4 h. In competition experiments with unlabeled fibronectin, 30% of the binding of radiolabeled fibronectin could be inhibited.     

The effect of amphotericin B on lectin-induced aggregation of cell surface receptors

The mobility of concanavalin A (ConA) and ricin receptors from NS20 neuroblastoma and C₆ glioma cells was studied using an electrophoretic technique. Cells attached to a solid support were exposed to an electrical field (12V cm⁻¹) at room temperature. The distribution of lectin receptors on the cell surface was revealed by fluorescent conjugates of lectins and microscopic observation of the fixed cells. This technique allowed the estimation of the mobilities of lectin receptors either in free or liganded form, depending on the time at which the cells are labeled with lectins (either after or before electrophoresis). In line with previous observations [1] it is shown that in their free form ConA and ricin receptors are mobile all over the cell surface. Ligand binding induced an apparent receptor immobilization. Immobilization of ricin receptors from C₆ glioma cells could be induced either by the multivalent or the monovalent form of the lectin indicating that cross-linking of receptors by the ligand did not play a predominant role in the process of receptor immobilization. Amphotericin B but not ionophores like valinomycin or gramicidin blocked ligand-induced receptor immobilization. It is concluded from this observation that the effect of amphotericin B is not related to its ionophoretic properties but more likely to its capacity to interact with membrane cholesterol. When cells were incubated at 37 °C extensive patching of lectin receptors could be observed. This process was also inhibited by amphotericin B. A model is proposed to account for a role of cholesterol in ligand-induced receptor immobilization and patching.     

Flow-injection binding assays: a way to increase the speed in binding analyses

A flow-injection analysis system was equipped with a small column containing immobilized concanavalin A. Pulses containing glucosides or glycoproteins were passed over the column, the lectin bound the carbohydrates. By using horseradish peroxidase as a labeled carbohydrate and letting it compete with other glucosides or mannosides a competitive binding assay for the latter was set up. When the enzyme activity had been evaluated, the column was rinsed and reconditioned, allowing a new assay to be run. To speed up the assay, substrates for the enzyme marker, peroxidase, were present in the perfusing buffer. A computerized evaluation of the absorbance peak allowed the time of the assay cycle to be reduced to 70 s. The sensitivity of this binding assay was fully comparable with those reported for other systems using the same reactants.     

Study on membrane recycling in the rat visceral yolk-sac endoderm using concanavalin-A conjugates

Summary The internalization and intracellular movements of apical-cell-membrane material were investigated in the endodermal cells of cultured visceral yolk-sacs of rats (whole-embryo culture; explanted at 10.5 days of gestation and cultured for 24h) using horseradish peroxidase- and ferritin-labelled concanavalin A (Con-A HRP, Con-A Fer). When visceral yolk-sac endoderm was exposed to Con-A HRP or Con-A Fer for 5 min at 4°C, the apical cell membranes containing a well-developed fuzzy coat were heavily labelled, whereas apical vacuoles, lysosomes and apical canaliculi were not. Incubation of Con-A-labelled endoderm for 5 60 min at 20° and 37°C in Con-A-free serum resulted in a temperature-dependent internalization of membranebound lectin into coated vesicles, apical vacuoles and lysosomes, and the apical cell membranes were cleared of the heavy labelling. With increasing incubation time, the number of labelled vacuolar structures and the intensity of their labelling decreased gradually, whereas the number of labelled apical canaliculi increased. Thus, after 30 and 60 min at 37°C, most of the apical canaliculi contained high concentrations of the markers. It was possible to observe labelled apical canaliculi that were in continuity with labelled apical vacuoles and lysosomes as well as with the apical cell membrane. These findings in rat endodermal cells indicate that constitutents of the apical cell membrane are internalized in apical vacuoles and lysosomes, and are then brought back to the apical cell membrane by the apical canaliculi, which concentrate and store this membrane material.Supported by the Deutsche Forschungsgemeinschaft (SFB 105)     

Lectin binding to the porcine and human ileal receptor of intrinsic factor-cobalamin

The purified porcine recpptor for the intrinsic factor-cobalamin complex bound to concanavalin A, lentil lectin and wheat germ lectin covalently coupled to Sepharose and was eluted with the corresponding soluble sugars. In contrast, human intrinsic factor bound efficiently to concanavalin A, to some extent to lentil lectin, but only slightly to wheat germ agglutinin. The binding of IF-Cbl to the receptor was inhibited when the receptor was pre-incubated with soluble wheat germ aglutinin, with an inhibition constant estimated to be 1.9 mol/l. After transfer of the purified receptor from SDS-PAGE to Immobilon, ligand blotting of the purified receptor with iodinated lectin showed that concanavalin A and lentil lectin bound to three (75, 56 and 43 kDa) components but that wheat germ agglutinin bound only to the 75 kDa component. These results showed that the subunit of the receptor could bind to wheat germ agglutinin, resulting in an inhibition of its binding with intrinsic factor. Both binding sites of intrinsic factor and of wheat germ agglutinin could be located near to each other.     

Characterization of cell surface carbohydrates on asexual spores of the water moldSaprolegnia ferax

Summary In asexual reproduction of the water mold,Saprolegnia ferax, four distinct and sequentially produced spores are involved in dispersal, two of which are motile and two of which are nonmotile. Composition of cell surface glycoproteins may be important in dispersal strategies for each of these stages. Binding patterns of fluorescently labelled lectins were investigated to identify differences in glycoproteins of asexually produced dispersal stages. The pattern of lectin binding to zoospores was diverse. FITC-Con A bound to surfaces of zoospores and membranes of the water expulsion vacuole system, indicating the prescence of mannosyl and glucosyl residues. In zoospores incubated for more than 30 min in FITC-WGA and FITC-GS II. which bind N-acetyl glucosamine, fluorescence was sometimes localized in peripheral, intracellular patches. In shorter incubations, secondary zoospores bound these lectins along the groove region where K-bodies were located. Surfaces of cystospores typically bound FITC-WGA, but not FITC-GS II. FITC-GS II, however, bound to empty cystospore walls, probably because reactive sugars were available at the inner surface of the wall. Germ tubes emerging from cystospores bound labelled WGA and GS II, but not Con A. The same lectin binding pattern was found along discharge papilla of primary cystospores, indicating that modifications in cystospore walls associated with direct germination and zoospore discharge were similar. Thus, glycoproteins involved in early establishment of the hyphal system differ from those forming the cell surface of cystospores. Differences in the binding pattern of lectins to zoospores and cystospores highlight differences between cell surface carbohydrates of motile and nonmotile asexual stages.Abbreviations BPA lectin fromBauhinia purpurea - C₁ primary cystospore - C₂ secondary cystospore - Con A concanavalin A, lectin fromCanavalia ensiformis - DBA lectin fromDolichos biflorus - DIC Nomarski differential interference contrast optics - DS dilute salts - FITC fluorescein isothiocyanate - FUC fucose - Gal galactose - GalNAc N-acetyl galactosamine - Glc glucose - GlcNAc N-acetyl glucosamine - GS I Griffonia simplicifolia lectin I - GS II G. simplicifolia lectin II - Man mannose - MPA lectin fromMaclura pomifera - PC phase contrast optics - PNA lectin fromArachis hypogaea - SBA soybean agglutinin, lectin fromGlycine max - UEA-1 lectin fromUlex europaeus - WGA wheat germ agglutinin fromTriticum vulgare - WV water expulsion vacuole