Studies of lectins XXXVI. Properties of some lectins prepared by affinity chromatography on O-glycosyl polyacrylamide gels

A number of lectins has been purified by affinity chromatography on O-glycosyl polyacrylamide gels. The lectins isolated (and the particular sugar ligands used in the affinity carriers) are as follows: Anguilla anguilla, serum (α-L-fucosyl-), Vicia cracca, seeds; Phaseolus lunatus, seeds; Glycine soja, seeds; Dolichos biflorus, seeds; Maclura pomifera, seeds; Sarothamnus scoparius, seeds; Helix pomatia, ablumin glands; Clitocybe nebularis, fruiting bodies (all $\text{N-}\text{acetyl}\text{-α-}\text{d}\text{-galactosaminyl-}$); Ricinus communis, seeds (β-lactosyl-); Onomis spinosa, root; Fomes fomentarius, fruiting bodies; Marasmius oreades, fruiting bodies (all $\text{α-}\text{d}\text{-galactosyl-}$), Canavalia ensiformis, seeds, (i.e., concanavalin A) ($\text{α-}\text{d}\text{-glucosyl-}$).Physicochemical properties of Glycine soja, Dolichos bifloras, Phaseolus lunatus, Helix pomatia and Ricinus communis lectins correponded well to properties of the preparations studied earlier by other workers. For the other purified lectins the essential physicochemical data (sedimentation coefficient, molecular weight, subunit composition, electrophoretic patterns, amino acid composition, carbohydrate content, isoelectric point) were established and their precipitating, hemagglutinating and mitogenic activities determined.     

Studies on lectins. XLIV. The pH dependence of lectin interactions with sugars as determined by affinity electrophoresis.

The pH dependence of association constants of the lectin-sugar complexes was determined by means of affinity electrophoresis. All the lectins studied (from the seeds of Dolichos biflorus, Glycine soja, Lens esculenta and Vicia cracca and of the fruiting body of Marasmius oreades) were characterized by a similar course of pH dependence of the association constants, with the maximum values at pH 7--9. For concanavalin A and the L-fucose binding Ulex europaeus lectin only the association constants at three selected pH values were determined. Concanavalin A does not interact with immobilized alpha-D-mannosyl residues at pH 2.3. The association constants vs. pH curves measured for lectins isolated from two different lentil varieties slightly differ in accordance with the differences observed in the interaction of these lectins with the Sephadex gel.     

Studies on lectins XLIV. The pH dependence of lectin interactions with sugars as determined by affinity electrophoresis

The pH dependence of association constants of the lectin-sugar complexes was determined by means of affinity electrophoresis. All the lectins studied (from the seeds of Dolichos biflorus, Glycine soja, Lens esculenta and Vicia cracca and of the fruiting body of Marasmius oreades) were characterized by a similar course of pH dependence of the association constants, with the maximum values at pH 7–9. For concanavalin A and the l-fucose binding Ulex europaeus lectin only the association constants at three selected pH values were determined. Concanavalin A does not interact with immobilized α-d-mannosyl residues at pH 2.3. The association constants vs. pH curves measured for lectins isolated from two different varieties slightly differ in accordance with the differences observed in the interaction of these lectins with the Sephadex gel.     

Studies on lectins. XLIX. The use of glycosyl derivatives of Dextran T-500 for affinity electrophoresis of lectins

p-Aminophenyl glycosides and glycosylamines were coupled to periodate oxidized Dextran T-500 either directly or through an epsilon-aminocaproic acid spacer. The new glycosylated derivatives of dextran specifically precipitate lectins having the appropriate carbohydrate specificity, and thus were used in the preparation of affinity gels for affinity electrophoresis of lectins. The apparent strength of interaction of several lectins with carbohydrate residues immobilized in this way was less than with carbohydrates immobilized in O-glycosyl polyacrylamide copolymers. The presence of epsilon-aminocaproic spacer had no effect on the strength of interaction. The advantages of this type of macromolecular derivative of the ligand for affinity electrophoresis and some differences between the glycosylated dextrans and O-glycosyl polyacrylamide copolymers are discussed. Dextrans containing bound p-aminophenyl alpha-D-mannopyranoside and p-aminophenyl alpha-D-glucopyranoside were used to study the binding properties of concanavalin A and the lectin from Lathyrus sativus seeds. For the investigation of interaction of lectins from Ricinus communis and Glycine soja seeds, dextran derivatives containing bound p-aminophenyl alpha- and beta-D-galactopyranosides and alpha- and beta-D-galactopyranosylamines were used.     

Localization of carbohydrate components in rat colon with fluoresceinated lectins

Cryostat sections of rat descending colon were studied by fluorescence microscopy after exposure to conjugates of fluorescein isothicoyanate with lectins from Glycine max (soybean), Triticum vulgaris (wheat germ), Ricinus communis (castor bean), Ulex europaeus, (gorse), Dolichos biflorus (horse gram) and Canavalia ensiformis (concanavalin A) (Jack bean). No two lectins showed identical patterns of fluorescence. FITC-conjugates of soybean and D. biflorus lectins reacted strongly with the mucus present in the crypt lumens and with the surface (as well as cytoplasm) of the epithelial cells suggesting that these sites are rich in terminal, non-reducing, N-acetylgalactosamine residues. Wheat germ, R. communis, U. europaeus and concanavalin A-FITC conjugates did not stain mucus but showed fluorescence in the cytoplasm of absorptive cells as well as in the lamina propria and submucosa. The FITC-R. communis conjugate also reacted with structures in the apical portion of epithelial cells that may correspond to the Golgi apparatus.     

Detection of anomalies in cell-surface carbohydrates on thrombasthenic platelets using 125I-labeled lectins

The composition of carbohydrates on the surface of platelets from a patient with Glanzmann's thrombasthenia and from seven normal donors were determined and compared. To this end, binding studies were performed using nine different purified 125I-labeled lectins; Concanavalin A, P-Phytohaemagglutinin, Wheat Germ Agglutinin, Dolichos biflorus, Pisum sativum, Ricinus communis II Agglutinin, Tetragonolobus purpureus, Lens culinaris and Soybean Agglutinin. These studies show that thrombasthenic platelets bear significantly decreased numbers of receptors for Concanavalin A and Lens culinaris, both with a specificity for D-mannose, and Ricinus communis II, with specificity for D-galactose. There were no detectable differences in the numbers of other lectin receptors. These results provide further evidence of molecular defects in thrombasthenic platelets. Moreover, the use of 125I-labeled lectins, as shown here, provides a fast and reliable technique for identifying abnormalities in the carbohydrate composition on the surface of platelets in various thrombopathies.     

The isolation of lectins on acid-treated agarose.

The ability of several D-galactose and N-acetyl-D-galactosamine-binding lectins to bind to Sepharose was investigated. Lectins from soybean, Wistaria floribunda, Bauhinia purpurea alba, and Sophora japonica could be isolated by affinity chromatography on acid-treated Sepharose 6B. These lectins would not bind to untreated Sepharose 2B, 4B, and 6B. The binding of B. purpurea alba and S. japonica was temperature-dependent. The S. japonica lectin would bind only at high pH. Ricinus communis toxin also showed a temperature-dependence of binding; acid-treated Sepharose 6B was a better affinity support for the toxin than was untreated Sepharose 4B Lectins from lima bean, Dolichos biflorus, and kidney-bean phytohemagglutinin did not bind to Sepharose under any of the conditions studied.     

Comparative study of blood group-recognizing lectins toward ABO blood group antigens on neoglycoproteins, glycoproteins and complex-type oligosaccharides

Binding specificities of ABO blood group-recognizing lectins toward blood group antigens on neoglycoproteins, glycoproteins and complex-type oligosaccharides were studied by lectin-blotting analysis, enzyme linked immunosorbent assay and lectin-conjugated agarose column chromatography. Human serum albumin conjugated with A- and B-trisaccharides was clearly recognized by Helix pomatia (HPA), Phaseolus lunatus, Dolichos biflorus agglutinins, and Griffonia simplicifolia I agglutinin B(4), respectively. Almost the same results were obtained for human group A and B ovarian cyst and A-active hog gastric mucins, but Glycine max agglutinin only reacted to the group A hog mucin. When human plasma von Willebrand factor (vWF), having Asn-linked blood group antigens, was tested, HPA was highly sensitive to blood group A antigen on the vWF. Ulex europaeus agglutinin I (UEA-I) preferentially bound to the vWF from blood group O plasma. Within the GalNAc-recognizing lectins examined, a biantennary complex-type oligosaccharide having the blood group A structure retarded on an HPA-agarose column, and the affinity was diminished after digestion with alpha-N-acetylgalactosaminidase. This product bound to UEA-I agarose column. These results indicate that HPA and UEA-I are most sensitive for detection of glycoproteins possessing small amounts of blood group A and H antigens and also useful for fractionation of complex-type oligosaccharides with blood group A and H antigens, respectively.     

The glycoprotein-bound large carbohydrates from embryonal carcinoma cells carry receptors for several lectins recognizing N-acetylgalactosamine and galactose

When various lectins were mixed with radioactively labeled embryoglycan (polylactosamine-type glycoprotein-bound carbohydrates from early embryonic cells) isolated from F9 embryonal carcinoma cells and the resulting complex was precipitated with ammonium sulfate, the glycan was found to react with the following lectins: Helix pomatia agglutinin (HPA), soybean agglutinin (SBA), Sophora japonica agglutinin (SJA), and Ricinus communis agglutinin-1 (RCA-1). Furthermore, affinity chromatography on lectin-agarose revealed that receptors for Griffonia simplicifolia agglutinin-I (GS-I) were also carried by the glycan. Together with the previous finding that the glycan carries receptors for Dolichos biflorus agglutinin (DBA) and peanut agglutinin (PNA), the present result established that the glycan has receptors for a variety of lectins recognizing N-acetylgalactosamine and/or galactose in teratocarcinoma cells. Intact molecules carrying GS-1 receptors and SJA receptors were isolated from F9 cells and teratocarcinoma OTT6050 and were shown to be high-molecular weight glycoproteins similar to DBA receptors isolated from the same sources.     

Secretory glycoconjugates of a mucin-synthesizing human colonic adenocarcinoma cell line. Analysis using double labeling with lectins

Lectins were used to characterize mucin glycoproteins and other secretory glycoconjugates synthesized by a human colon adenocarcinoma-derived cell line which expresses a goblet cell phenotype. Despite being clonally derived, HT29-18N2 (N2) cells, like normal goblet cells in situ were heterogeneous in their glycosylation of mucin. Only wheat-germ agglutinin, which recognizes N-acetylglucosamine and sialic acid residues, and succinylated wheatgerm agglutinin, which binds N-acetylglucosamine, stained the contents of all secretory granules in all N2 goblet cells. The N-acetylgalactosamine binding lectins Dolichos biflorus and Glycine max stained 20% and 21% of N2 goblet cells respectively. Ricinus communis I, a galactose-binding lectin, stained 67% of N2 goblet cells although staining by another galactose-binding lectin, Bandeiraea simplicifolia I, was limited to 19%. Peanut agglutinin, a lectin whose Gal(beta 1-3)GalNAc binding site is not present on mucins produced in the normal colon but which is found on most mucins of cancerous colonic epithelia, stained 68% of the cells. Ulex europeus I, a fucose-binding lectin, did not stain any N2 goblet cells. Four lectins (Lens culinaris, Pisum sativum, Phaseolus vulgaris E, Phaseolus vulgaris L) which recognize sugars normally present only in N-linked oligosaccharides stained up to 38% of N2 goblet cells. The binding of these lectins indicates either both O-linked and N-linked oligosaccharide chains are present on the mucin protein backbone or the co-existence of non-mucin N-linked glycoproteins and O-linked mucins within the goblet cell secretory granule.     

The carbohydrate components of corn prolamins]

This work was aimed to study the patterns of zein glycosylation. Zein proteins included 1-3% of sugars. The affinity of different lectins, such as concanavalin A (Con A), Lens culinaris lectin (LCL) and lectins of Arachis hypogaea (PNA), of Triticum vulgaris (WGA), of Dolichos biflorus (DBA), of Glycin max (SBA), of Lotus tetragonolobus (LTA), of Laburnum anagiroides (LAL), of Ricinus communis (RCA), of Phaseolus vulgaris (PHA) was used to analyze the glycosylation sites. All selected lectins interacted with zein proteins. It may serve a basis for determination of mannose, galactose, fucose and aminosugars. Some lectins were bound only by prolamines of some inbred lines, while others were connected with all lines.     

Glycoconjugates in normal human kidney. A histochemical study using 13 biotinylated lectins

The avidin-biotin-peroxidase complex technique was used with 13 lectins to study the glycoconjugates of normal human renal tissue. The evaluated lectins included Triticum vulgaris (WGA), Concanavalin ensiformis (ConA), Phaseolus vulgaris leukoagglutinin and erythroagglutinin (PHA-L and PHA-E), Lens culinaris (LCA), Pisum sativum (PSA), Dolichos biflorus (DBA), Glycine max (SBA), Arachis hypogaea (PNA), Sophora japonica (SJA), Bandeiraea simplicifolia I (BSL-I), Ulex europaeus I (UEA-I) and Ricinus communis I (RCA-I). Characteristic and reproducible staining patterns were observed. WGA and ConA stained all tubules; PHA-L, PHA-E, LCA, PSA stained predominantly proximal tubules; DBA, SBA, PNA, SJA and BSL-I stained predominantly distal portions of nephrons. In glomeruli, WGA and PHA-L stained predominantly visceral epithelial cells; ConA stained predominantly basement membranes and UEA-I stained exclusively endothelial cells. UEA-I also stained endothelial cells of other blood vessels and medullary collecting ducts. Sialidase treatment before staining caused marked changes of the binding patterns of several lectins including a focal loss of glomerular and tubular staining by WGA; an acquired staining of endothelium by PNA and SBA; and of glomeruli by PNA, SBA, PHA-E, LCA, PSA and RCA-I. The known saccharide specificities and binding patterns of the lectins employed in this study allowed some conclusions about the nature and the distribution of the sugar residues in the oligosaccharide chains of renal glycoconjugates. The technique used in this report may be applicable to other studies such as evaluation of normal renal maturation, classification of renal cysts and pathogenesis of nephrotic syndrome. The observations herein reported may serve as a reference for these studies.     

A versatile immunoadsorbent capable of binding lectins of various specificities and its use for the separation of cell populations

A procedure for cell fractionation using lectin-affinity chromatography is described. It consists of a single affinity adsorbent, hog gastric mucin blood group A+H substance covalently coupled to Sephadex or Sepharose, to which lectins of various specificities can bind. The complex formed, lectin in equilibrium hog A+H substance-Sephadex, then serves as an affinity probe for isolating and fractionating cells. The lectins from Ulex europaeus, Lotus tetragonolobus, Helix pomatia, Dolichos biflorus, and Phaseolus lunatus were used with the same blood group substance as adsorbent. The affinity columns retained erythrocytes with blood group specificity for the adsorbed lectin and thus fractionate cells in mixtures. Cells as well as lectins are eluted by specific sugar inhibitors. Mixtures of two kinds of cells can be separated when the proportion of the adsorbed cells is not too low.     

ESR and fluorescence studies on the adenine binding site of lectins using a spin-labeled analogue

The techniques of electron spin resonance (ESR) and fluorescence spectroscopy have been used to study the interaction of a spin-labeled analogue of adenine, N6-(2,2,6,6-tetramethyl-1-oxypiperidin-4-yl)adenine (I), with several plant lectins. While most adenine derivatives enhanced lectin-induced fluorescence of 1,8-anilinonaphthalenesulfonic acid by binding to a separate, adenine-specific site [Roberts, D.D., & Goldstein, I.J. (1982) J. Biol. Chem. 257, 11274-11277], the spin label I caused a decrease in this fluorescence with certain lectins. ESR showed the ligand to interact strongly with lectins from lima bean (Phaseolus lunatus), Dolichos biflorus, and Phaseolus vulgaris (PHA); however, no binding was observed with Griffonia simplicifolia isolectins A4 and B4, soybean agglutinin, or Amphicarpaea bracteata lectins. The spin label was highly immobilized by each of these proteins (2T magnitude of = 68 G). Apparent affinities of the spin label for the lectins decreased in the order lima bean lectin greater than PHA erythroagglutinin greater than PHA leukoagglutinin greater than D. biflorus. Spin-labeled adenine appeared to bind specifically to the adenine binding site of D. biflorus and PHA leukoagglutinin, as demonstrated by total abolition of the ESR spectrum of bound spin label by adenine. PHA erythroagglutinin and lima bean lectin bound the analogue with apparent dissociation constants of 5 X 10(-5) and 3.2 X 10(-5) M, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cell surface carbohydrate of Leishmania mexicana amazonensis: differences between infective and non-infective forms

The cell surface carbohydrates of Leishmania mexicana amazonensis (amastigotes and promastigotes, both infective and non-infective forms) were comparatively analyzed by agglutination assay employing 28 highly purified lectins, and by binding assay using 125I-labeled lectins. Among the D-GalNAc binding lectins, Bandeiraea simplicifolia-I, Dolichos biflorus, Phaseolus vulgaris and Glycine max were highly specific for the amastigotes, while that from Maclura aurantiaca selectively agglutinated promastigotes. The lectins from Wistaria floribunda, Phaseolus lunatus (D-GalNAc), Arachis hypogaea (D-Gal) and Triticum vulgaris (D-GlcNAc) were selective for the infective forms (both amastigotes and promastigotes), not reacting with the non-infective ones. Conversely, no parasite agglutination occurred with the L-fucose binding lectins Lotus tetragonolobus and Ulex europaeus-I. Binding studies with 125I-labeled lectins from Wistaria floribunda, Triticum vulgaris and Arachis hypogaea were performed to find whether unagglutinated non-infective promastigotes might have receptors for these lectins, in which case absence of agglutination could be due to a peculiar arrangement of the receptors. These assays essentially confirmed the selectivity, demonstrated in the agglutination assays of these lectins for the infective promastigotes.     

Studies on platelet surface carbohydrates in normal and uraemic platelets using 125I-labelled lectins

Binding studies with six different purified 125I-labelled lectins, concanavalin A (con A), wheat germ agglutinin (WGA), Ricinus communis agglutinin II (RCA II), Dolichos biflorus (DB), Tetranolobus purpureus (TP) and P-phyto-hemagglutinin (P-PHA), were used to investigate the surface topography of carbohydrates in platelets from uraemic and normal subjects. Compared with normal the uraemic platelets, bear significantly decreased (more than 2.5-fold) numbers of receptors for P-PHA (N-acetyl D-galactosamine specificity) and Con A (specificity glucose, mannose). The number of WGA, RCA, II, DB and TP receptors in uraemic platelets did not differ from the number in normal platelets. Binding studies with 125I-labelled lectins provide further evidence of molecular defects in uraemic platelets. Moreover, this method might provide a fast and reliable technique for identifying abnormalities in the surface topography of carbohydrates on platelets in several pathological states.     

Polymorphism and glycoprotein character of Ricinus communis lectins purified by affinity chromatography]

Two lectin fractions (S20W = 6,8 and 4,9 S) were purified from Ricinus communis seeds. The purification was carried out in four steps : ammonium sulfate fractionation, affinity chromatography on Sepharose 4 B, gel filtration on Sephadex G 150 and chromatography on CM celluloes. The purified lectins were glycoproteins whose chemical composition was determined. Amino terminal analysis of the two fractions revealed glycine and serine. Polyacrylamide gel electrophoresis of the higher molecular weight fraction allowed the separation of several components with different affinity for PAS staining.     

Lectins as Markers of Human Epidermal Cell Differentiation

The expression of sugar residues on human epidermal cells was investigated by means of lectin binding, as a way of determining membrane structural changes occurring during the differentiation of the epidermis. Fourteen lectins of different sugar specificity were conjugated with fluorescein isothiocyanate (FITC-lectins) and tested in fluorescence microscopy on frozen sections of normal human epidermis. In parallel, FITC-lectins were tested on psoriatic-involved epidermis to visualize differences in the expression of sugar residues that might occur during abnormal epidermal differentiation. No labelling could be obtained with lectins from Bandeira simplicifolia I, Dolichos biflorus, Limulus polyhemus, Tetragonolobus purpureas, Ulex europeus I , and Triticum vulgaris (group 1 lectins). A "pemphigus-like" intercellular labelling of the whole epidermis, except the stratum corneum, was obtained with lectins from Canavalia ensiformis, Maclura pomifera, Phaseolus vulgaris , and Ricinus communis I (group 2 lectins). A selective intercellular labelling of the stratum spinosum and the stratum granulosum was seen in normal epidermis with lectins from Arachis hypogaea, Glycine max, Helix pomatia , and Sophora japonica (group 3 lectins). In psoriatic epidermis, not only the basal cell layer, but also cells from the adjacent lower stratum spinosum were found to be negative, using FITC-lectins of group 3. These data indicate that the expression of lectin binding sites in normal epidermis differs according to the maturation of the cell from the basal cell to the more mature keratinocyte in the stratum granulosum. They suggest that lectins may be used as markers of epidermal cells in various stages of normal and abnormal differentiation.     

Fractionation of lymphocytes using affinity chromatography with 9 lectins

Lymphocyte subclasses from normal peripheral blood have been fractionated by affinity chromatography with lectins. Concanavalin A (Con A), Lens culinaris lectin (LC), Pisum sativum lectin (PS), Phaseolus vulgaris lectin (PHA), Dolichos biflours lectin (DB), Glicine max lectin (SBA), Ricinus communis lectin (RCA II), Tetragonolobus purpureus lectin (TP) and Triticum vulgaris lectin (WGA), were coupled to Sepharose 6MB, and lymphocytes labelled with 125I were eluted through the chromatographic columns. The binding of lymphocytes to WGA and SBA lectins was 32% and 13% respectively. The binding to the other lectins tested were found to be between 32% and 13%. When solutions of increasing concentrations of specific sugar were added to the columns a progressive elution of bound lymphocytes was observed. These results indicate the existence of a large range of lymphocyte subclasses, with different binding capacity to lectins, which was a function of the receptor number or/and receptor affinity to each lectin. Furthermore, these two parameters were found to vary in each functional population. Even though all the lymphocytes had lectin receptors, T lymphocytes showed higher affinity for Con A, PHA and TP lectins, while B lymphocytes appeared to be more specific for LC, PS, SBA, DB, RCAII and WGA lectins.     

Evaluation of structural and secretory glycoconjugates in normal human jejunum by means of lectin histochemistry

The labelling pattern of eight lectins was studied in jejunal samples from ten normal subjects, in order to define the normal distribution of structural and secretory glycoconjugates in the small bowel. The following lectins were studied by means of a peroxidase technique on formalin-fixed samples: Arachis hypogaea, Ricinus communis, Canavalia ensiformis, Lens culinaris, Phaseolus vulgaris, Triticum vulgaris, Ulex europaeus, Dolichos biflorus. Phaseolus vulgaris reacted with goblet cell mucus throughout the villus-crypt axis. Conversely Ulex europaeus, Dolichos biflorus and Triticum vulgaris lectin labelling of goblet cells appeared to be confined to the upper part of the villi. This finding suggests that during cell migration from crypt to villus tip, the continuing maturation of goblet cells is associated with the differentiation of secretory carbohydrates, which probably parallels the cell maturation cycle. Lectin histochemistry appears to be a reliable tool for the study of structural and secretory glycoconjugates in the jejunal mucosa, and might be of value in the study of diseases in which the cell-maturation cycle in the small bowel is altered.