Comparative analysis of galactoside-binding lectins isolated from mammalian spleens

Galactoside-inhibitable lectins have been isolated from rabbit, rat, mouse, pig, lamb, calf, and human spleens. Native molecular mass, subunit structure, pI, and hemagglutinating activity have been compared for these lectins. The yields of lectin varied from 1.8 mg/kg for rabbit spleen to 79 mg/kg for lamb spleen. Pig, lamb, calf, and human spleen lectins yielded single protein peaks when subjected to Superose 12 fast-protein liquid chromatography. The apparent molecular mass for these lectins was 33-34 kDa. In contrast, rat and mouse spleen lectin preparations were separated into three components ranging from 8.4 to 34 kDa. Superose 12 chromatography of rabbit spleen lectin revealed the presence of at least six components. Gradient slab gel sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed the presence of single polypeptides for pig, calf, lamb, and human lectins corresponding to a molecular mass of 14-14.5 kDa. Multiple polypeptides were detected for the mouse, rat, and rabbit lectins. The molecular mass of the major polypeptides were 15, 15, and 17 kDa for rat, mouse, and rabbit, respectively. The presence of isolectins in all preparations was shown by isoelectric focusing. The major isolectins were acidic proteins with pI 4.38-4.80. Hemagglutination and hemagglutination inhibition assays demonstrated similarities as well as differences among the lectin preparations. Hemagglutinating activity could not be demonstrated in rabbit spleen extracts nor for isolated putative lectin. Human buffy coat cells were reversibly agglutinated by calf and human spleen lectins, demonstrating the presence of leucocyte cell surface lectin receptors.     

The gastrulating chick blastoderm contains 16-kDa and 14-kDa galactose-binding lectins possibly associated with an apolipoportein

Extracts from chick blastoderms were subjected to affinity chromatography on lactoside-Sepharose. Lactose-eluted fractions were examined by gradient SDS-PAGE with silver staining, as well as by immunoblot analysis using antibodies to the chicken galactose-binding lectins of 14 kDa and 16 kDa and to an apolipoprotein of chicken very low density lipoprotein (Apo-VLDL-II). Fractions containing the highest lectin activity contained four main bands. One, unidentified, comigrated with albumin; two bands were identified by immunoblotting as the 14-kDa and 16-kDa lectins. The fourth band comigrated with Apo-VLDL-II and in immunoblot analysis reacted with antibodies to this apolipoprotein. In our electrophoretic system this protein migrates close to bovine trypsin inhibitor and has an apparent molecular weight of 6500 ± 500. The present studies establish the identity of this previously described 6.5 kDa protein (Zalik et al. J. Cell. Sci. 88, 483, 1987) as Apo-VLDL-II. While the 16-kDa lectin was present consistently in all the affinity-purified preparations, the relative frequencies of the 14-kDa lectin and Apo-VLDL-II varied. In sections of primitive streak blastoderms, lectin immunofluorescence was present in the lowest, most ventral area of the primitive groove and in the cells emerging laterally from the groove to form the endoderm. Cells of the extraembryonic endoderm also displayed high lectin immunoreactivity. The localization of the lectins is similar to the one described previously for Apo-VLDL-II. Double immunofluorescence staining indicates that Apo-VLDL-II and the lectin(s) colocalize. The copurification and colocalization of Apo-VLDL-II and the lectins in the chick blastoderm suggest that this apolipoprotein may associate with the galactose-binding lectins or may display lectin activity.     

Cell-to-cell binding induced by different lectins

The cell-to-cell binding induced by concanavalin A (Con A) and the lectins from wheatgerm, soybean, and waxbean has been analyzed by measuring the ability of single cells to bind to lectin-coated cells immobilized on nylon fibers. The cells used were lymphoma, myeloid leukemia, and normal fibroblast cells. With all lectins, cell-to-cell binding was inhibited if both cells were prefixed with glutaraldehyde. However, in most cases cell-to-cell binding was enhanced when only the lectin-coated cell was prefixed. With normal fibroblasts, treatment of either one or both cells with trypsin enhanced the cell-to-cell binding induced by Con A and the wheatgerm lectin. Neuraminidase, which increases the number of receptors for soybean agglutinin, increased cell-to-cell binding only if both cells were treated. Although cell-to- cell binding induced by the lectins from soybean and wheatgerm could be partially reversed by the appropriate competitive saccharide inhibitor, binding induced by Con A could not be reversed. The experiments indicate that cell-to-cell binding induced by a lectin can be prevented by an insufficient density of receptors for the lectin, insufficient receptor mobility, or induced clustering of receptors. These effects can explain the differences in cell-to-cell binding and agglutination observed with different cell types and lectins. They also suggest that cell-to-cell binding induced by different lectins with a variety of cell types is initiated by a mechanism involving the alignment of complementary receptors on the colliding cells for the formation of multiple cell-to-lectin-to-cell bridges.     

Localization of soluble endogenous lectins and their ligands at specific extracellular sites

Soluble lectins of chicken, rat, frog, and the cellular slime mold, Dictyostelium discoideum, were purified and specific antibodies raised against these proteins were used to immunohistochemically localize the lectins in and around the tissues in which they were synthesized. Within cells, some of these soluble lectins (chicken-lactose-lectin-II in intestinal goblet cells, discoidin II in prespore cells) appear to be concentrated within vesicles whereas others (e.g., rat beta-galactoside lectin in pulmonary alveolar and smooth muscle cells) appear to be free in the cytoplasm. All of these lectins are eventually secreted to extracellular sites in developing or adult tissues. The sites include mucin (chicken-lactose-lectin-II in intestine); developing extracellular matrix (chicken-lactose-lectin-I in muscle; Xenopus laevis lectin in blastula stage embryos); slime (discoidin I); developing spore coat (discoidin II); and a specialized extracellular matrix, elastic fibers (rat beta-galactoside lectin in lung). In cases where this has been studied in detail (discoidin I, discoidin II, and chicken-lactose-lectin-II), the lectin is associated with a complementary extracellular ligand, at least transiently. Lectin-ligand interactions presumably confer specialized properties in these particular extracellular domains.     

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.     

Endogenous lectins in chickens and slime molds: Transfer from intracellular to extracellular sites

Endogenous lectins in both cellular slime molds and chicken tissues have been localized primarily intracellularly, in contrast with the predominantly extracellular localization of the glycoproteins, glycolipids, and glycosaminoglycans with which they might interact. Here we present evidence that lectins in both of these organisms may be externalized and become associated with the cell surface and/or extracellular materials. In chicken intestine, chicken-lactose-lectin-II is shown to be localized in the secretory granules of the goblet cells, along with mucin, and to be secreted onto the intestinal surface. In embryonic muscle, chicken-lactose-lectin-I is shown to be externalized with differentiation, ultimately becoming localized on the surface of myotubes and in the extracellular spaces. In a cellular slime mold, Dictyostelium purpureum, externalization of lectin is elicited by either polyvalent glycoproteins that bind the small amount of endogenous cell surface lectin, or by slime mold or plant lectins that bind unoccupied complementary cell surface oligosaccharides. These results suggest that externalization of endogenous lectin may be a response to specific external signals. We conclude that lectins are frequently held in intracellular reserves awaiting release for specific external functions.     

Multiplicity of carbohydrate-binding sites in beta-prism fold lectins: occurrence and possible evolutionary implications

The beta-prism II fold lectins of known structure, all from monocots, invariably have three carbohydrate-binding sites in each subunit/domain. Until recently, beta-prism I fold lectins of known structure were all from dicots and they exhibited one carbohydrate-binding site per subunit/domain. However, the recently determined structure of the beta-prism fold I lectin from banana, a monocot, has two very similar carbohydrate-binding sites. This prompted a detailed analysis of all the sequences appropriate for two-lectin folds and which carry one or more relevant carbohydrate-binding motifs. The very recent observation of a beta-prism I fold lectin, griffthsin, with three binding sites in each domain further confirmed the need for such an analysis. The analysis demonstrates substantial diversity in the number of binding sites unrelated to the taxonomical position of the plant source. However, the number of binding sites and the symmetry within the sequence exhibit reasonable correlation. The distribution of the two families of beta-prism fold lectins among plants and the number of binding sites in them, appear to suggest that both of them arose through successive gene duplication, fusion and divergent evolution of the same primitive carbohydrate-binding motif involving a Greek key. Analysis with sequences in individual Greek keys as independent units lends further support to this conclusion.It would seem that the preponderance of three carbohydrate-binding sites per domain in monocot lectins, particularly those with the beta-prism II fold, is related to the role of plant lectins in defence.     

Isolation and some properties of mammalian hepatic membrane lectins

Membrane lectins were isolated from sheep, goat, and buffalo liver by chromatography on an asialofetuin (ASF)-Sepharose 4B column. The lectins moved as a single protein band in SDS-PAGE with molecular masses of 42, 54 and 50 kDa, respectively, for sheep, goat and buffalo lectins. The molecular masses remained unchanged in 0.2 M 2-mercaptoethanol. As judged from the inhibition of binding of the lectin to ASF gel, the three lectins were beta-galactoside-specific. Sheep, goat and buffalo lectins were found to be sialoglycoproteins containing 18.6, 27 and 38.8 mol/mol lectin of neutral hexose, respectively; the corresponding values for the sialic acid content being 5.3, 8.7 and 11.8 mol/mol lectin. Thus goat and buffalo lectins are physico-chemically different from many mammalian hepatic lectins described so far.     

Archeal lectins: An identification through a genomic search

Forty‐six lectin domains which have homologues among well established eukaryotic and bacterial lectins of known three‐dimensional structure, have been identified through a search of 165 archeal genomes using a multipronged approach involving domain recognition, sequence search and analysis of binding sites. Twenty‐one of them have the 7‐bladed β‐propeller lectin fold while 16 have the β‐trefoil fold and 7 the legume lectin fold. The remainder assumes the C‐type lectin, the β‐prism I and the tachylectin folds. Acceptable models of almost all of them could be generated using the appropriate lectins of known three‐dimensional structure as templates, with binding sites at one or more expected locations. The work represents the first comprehensive bioinformatic study of archeal lectins. The presence of lectins with the same fold in all domains of life indicates their ancient origin well before the divergence of the three branches. Further work is necessary to identify archeal lectins which have no homologues among eukaryotic and bacterial species. Proteins 2016; 84:21–30. © 2015 Wiley Periodicals, Inc.     

Distribution of lectins in membranes of soybean and peanut plants

The distribution of lectin activity in soybean and peanut plants has been investigated. In both plants activity is found in all tissues examined (roots, shoots and leaves) at all stages of development from seedling to maturity (7 weeks). The cellular location of the lectins differs between soybean and peanut: in soybean the lectins are generally membrane-associated, whereas in peanut plants lectin activity is present also in the soluble cytoplasmic fraction. The membrane-associated lectins appear to differ from the seed lectins of the respective plants. The function of membrane-associated lectins is discussed.Abbreviations RCA lectin of castor bean - SBA soybean agglutinin - PNA peanut agglutinin - HEPES 2-[4-(2-Hydroxyethyl)-piperazinyl-(1)]ethanesulphonic acid - MES morpholinoethane sulphonic acid - PBS phosphate-buffered saline     

Lectin binding in human skeletal muscle: a comparison of 15 different lectins

Summary Fifteen lectin-horseradish peroxidase conjugates have been used in a comprehensive histochemical study of human skeletal muscle. The staining patterns of many lectins were found to be coincident with the known distributions of types I, III, IV and V collagen, fibronectin and laminin. One lectin,Bandeiraea simplicifolia (BSA I), selectively stained capillaries in a blood group-specific manner, the significance of which is unknown. The results show that although lectins are useful cytochemical probes for identifying tissue glycoconjugates, lectin binding is not solely determined by monosaccharide specificity as lectins which interact with the same sugars may have completely different staining patterns. Factors such as accessibility, glycan conformation and oligosaccharide sequence also affect lectin binding in tissues. For these reasons, we conclude that a comprehensive histochemical investigation of tissue glycoconjugates should employ a large number of lectins, preferably with overlapping sugar specificities.     

Screening for and purification of novel self-aggregatable lectins reveal a new functional lectin group in the bark of leguminous trees

A solubility-insolubility transition assay was used to screen the bark and stems of seven leguminous trees and plants for self-aggregatable lectins. Novel lectins were found in two trees, Robinia pseudoacacia and Wisteria floribunda, but not in the leguminous plants. The Robinia lectin was isolated from coexisting lectin by combined affinity chromatographies on various sugar adsorbents. The purified lectins proved to be differently glycosylated glycoproteins. One lectin exhibited the remarkable characteristics of self-aggregatable lectins: localization in the bark of legume trees, self-aggregation dissociated by N-acetylglucosamine/mannose, and coexistence with N-acetylgalactosamine/galactose-specific lectins, which are potential endogenous receptors. Self-aggregatable lectins are a functional lectin group that can link enhanced photosynthesis to dissociation of glycoproteins.     

Identification of mycobacterial lectins from genomic data

Sixty‐four sequences containing lectin domains with homologs of known three‐dimensional structure were identified through a search of mycobacterial genomes. They appear to belong to the β‐prism II, the C‐type, the Microcystis virdis (MV), and the β‐trefoil lectin folds. The first three always occur in conjunction with the LysM, the PI‐PLC, and the β‐grasp domains, respectively while mycobacterial β‐trefoil lectins are unaccompanied by any other domain. Thirty heparin binding hemagglutinins (HBHA), already annotated, have also been included in the study although they have no homologs of known three‐dimensional structure. The biological role of HBHA has been well characterized. A comparison between the sequences of the lectin from pathogenic and nonpathogenic mycobacteria provides insights into the carbohydrate binding region of the molecule, but the structure of the molecule is yet to be determined. A reasonable picture of the structural features of other mycobacterial proteins containing one or the other of the four lectin domains can be gleaned through the examination of homologs proteins, although the structure of none of them is available. Their biological role is also yet to be elucidated. The work presented here is among the first steps towards exploring the almost unexplored area of the structural biology of mycobacterial lectins. Proteins 2013. © 2012 Wiley Periodicals, Inc.     

Localization of endogenous lectins in normal human breast, benign breast lesions and mammary carcinomas

Specific antisera against three mammalian beta-galactoside-specific lectins of apparent molecular weights 14.5 kDa, 18 kDa and 29 kDa have been used to localize these lectins in normal breast, and in benign and malignant mammary lesions. In normal breast tissue discrete localization of two lectins (Mrs 14.5 kDa and 18 kDa) was demonstrated in fibroblasts, smooth muscle cells, myoepithelial cells and capillary endothelium. Extracellular localization of one lectin (Mr 14.5 kDa) in collagen was apparent. The third lectin (Mr 29 kDa) labelled preferentially luminal cells and their secretory product. Two benign tumours (an analyzed fibroadenoma and a papilloma) revealed strong staining with two lectins (Mrs 18 kDa and 29 kDa). Of the 24 mammary carcinomas examined, the lectin (Mr 14.5 kDa) was expressed by only occasional tumour cells, the lectin (Mr 18 kDa) occurred in many tumour cells and the lectin (Mr 29 kDa) labelled tumour cells in nearly all cases. The expression of these beta-galactoside-specific endogenous lectins therefore appears to be regulated differently in normal breast compared with mammary tumours.     

Characterization of the carbohydrate moiety of Clerodendron trichotomum lectins. Its structure and reactivity toward plant lectins

Lectins were isolated from fruits and leaves of Clerodendron trichotomum by affinity chromatography on lactamyl-Sepharose. The purified lectins (C. trichotomum agglutinin: CTA) were homogeneous on SDS/polyacrylamide gel electrophoresis, and the carbohydrate moiety was characterized by physicochemical and immunochemical methods. The asparagine-linked oligosaccharides were released by treatment with N-oligosaccharide glycopeptidase (almond, EC 3.5.1.52) of peptic glycopeptides obtained from fruit CTA, and separated by gel filtration and thin-layer chromatography. The structure of the predominant oligosaccharide was determined as Xyl beta 1----2 (Man alpha 1----6)(Man alpha 1----3)Man beta 1----4GlcNAc beta 1----4(Fuc alpha 1----3)GlcNAc by high-performance liquid chromatography, sugar analysis and 1H-NMR spectroscopy. The reactivity of the carbohydrate moiety of CTA toward various lectins was studied. Fruit and leaf CTAs were applied to polyacrylamide gel electrophoresis, transferred to nitrocellulose sheets and detected with horseradish-peroxidase-conjugated lectins. Concanavalin A, lentil lectin, pea lectin, Vicia faba lectin and Ulex europeus agglutinin I, but not wheat germ lectin, bound to fruit CTA. The results indicate new binding properties of these plant lectins: a beta-xylosyl residue substituted at C-2 of the beta-mannosyl residue of N-linked oligosaccharide does not affect the binding with mannose-specific lectins, lentil, pea and Vicia faba lectins can bind to N-linked oligosaccharides containing an alpha-L-fucosyl residue attached to C-3 of the asparagine-linked N-acetyl-D-glucosamine residue, and Ulex europeus agglutinin I can bind to the (alpha 1----3)-linked fucose residue of the N-linked oligosaccharide.     

Ligand-binding characteristics of rat serum-type mannose-binding protein (MBP-A). Homology of binding site architecture with mammalian and chicken hepatic lectins

Sugar-binding characteristics of rat serum mannose-binding protein (MBP) were studied using the carbohydrate-recognition domain of this protein expressed from a cloned cDNA. To assess the binding affinity of various test compounds, they were added as inhibitors in a binding assay in which 125I-MBP was incubated with yeast cells and the extent of binding was estimated from the radioactivity associated with the pelleted cells. The results of such inhibition assays suggest that MBP has a small binding site which is probably of the trough-type. The 3- and 4-OH of the target sugar are indispensable, while the 6-OH is not required. These characteristics are shared by the rat hepatic lectin and chicken hepatic lectin, both of which are C-type lectins containing carbohydrate-recognition domains highly homologous to that of MBP. Apparently, the related primary structures of these lectins give rise to similar gross architecture of their binding sites, despite the fact that each exhibits different sugar binding specificities.     

Soluble galactoside-binding vertebrate lectins: a protein family with common properties

1. Soluble galactoside-binding lectins could play a key role in vertebrates by specifical binding to complementary glycoconjugates. 2. Their expression and localization are developmentally regulated. 3. They constitute a large family of structurally related proteins which contain a series of conserved aminoacids. 4. Their functional role could vary from an organ to another, and the same lectin may probably mediate several biological activities.     

Multiple soluble beta-galactoside-binding lectins from human lung

Soluble extracts of human lung contain three major beta-galactoside-binding proteins with apparent subunit molecular weights of 14,000 (HL-14), 22,000 (HL-22), and 29,000 (HL-29). HL-14 and HL-29 were abundant in all the specimens that we tested whereas HL-22 was abundant in some and very scarce in others. HL-14 could be resolved into at least six acidic forms by isoelectric focusing and HL-29 into at least five acidic forms by this procedure. In contrast, HL-22 is a basic protein. Other beta-galactoside-binding proteins with subunit molecular weights ranging from about 16,000 to 27,000 were also detected in lung extracts, but the possibility that they are degradation products cannot be excluded. HL-14 is very similar to a rat lung lectin (RL-14.5) in carbohydrate binding specificity and amino acid composition and reacts strongly with an antiserum raised against the rat lectin. HL-29 is similar to the rat lectin RL-29 in the same respects, but its carbohydrate binding specificity is somewhat different. Of the known rat lectins, HL-22 resembles RL-18 most closely in carbohydrate binding specificity, but it is significantly different in other properties and does not react with an antiserum raised against the rat lectin.     

Heterogeneity of the blood group ABH antigens and variation in the expression of these antigens of secretory granules in human cervical glands. An electron microscopic observation using lectins and monoclonal antibodies

Cytochemical localization of blood group ABH antigens was examined in secretory cells of human cervical glands by application of a post-embedding lectin-gold as well as immuno-gold labeling procedure using monoclonal antibodies. Blood group specific lectins such as Dolichos biflorus agglutinin (DBA), Helix pomatia agglutinin (HPA), Griffonia simplicifolia agglutinin I-B4 (GSAI-B4) and Ulex europaeus agglutinin-I (UEA-I) reacted with secretory granules but not with other cytoplasmic organellae such as nucleus and cell membrane. The reactivity of secretory granules with these lectins showed strict dependence on the blood group and secretor status of tissue donors. The binding patterns with these lectins were not homogeneous, but exhibited marked cellular and subcellular heterogeneity. Thus, for example, in blood group A individuals, some granules were stained strongly with DBA and others were weakly or not at all with the lectin. Such a heterogenous labeling with the lectin was observed even in the same cells. Similar results were obtained with UEA-I and GSAI-B4 staining in blood group O and B secretor individuals, respectively. Monoclonal antibodies likewise reacted specifically with the granules but they occasionally bound to some nucleus. The labeling pattern of the antibodies with the granules was essentially the same as those of lectins.(ABSTRACT TRUNCATED AT 250 WORDS)     

The binding of lectins to components of plasma membranes from porcine submaxillary lymph node lymphocytes

By sodium dodecyl sulfate-polyacrylamide gel electrophoretic analysis the plasma membranes from porcine lymphocytes contain at least 30--35 glycopolypeptides and one or more glycolipids to which one or more of 12 purified lectins bind. The specificities of binding generally followed the same pattern as those of the reaction of the lectin with intact pig lymphocytes. Some lectins (e.g., the isolectin pair, Agaricus bisporus lectins A and B and a group consisting of the Lens culinaris A and B isolectins and the closely related Pisum sativum lectins) bind to almost identical populations of plasma membrane components and compete with each other for all their binding sites. Others (e.g., Concanavalin A and the Lens culinaris-Pisum sativum group and a group consisting of phytohemagglutinin-L, Ricinus communis lectin-60 and Ricinus communis lectin-120 bind in a cross reactive manner to some common binding moieties but, in addition, to certain nonshared ones. Still others (e.g., soybean agglutinin, peanut agglutinin and wheat germ agglutinin) do not share any common binding moieties with the other lectins. The amount of lectin binding and the number of membrane components to which a lectin binds is directly related to the Ka of binding of the lectin to the intact lymphocyte. Those with high Ka (Cocanavalin A Lens culinaris lectins, Pisum sativum lectins, phytohemagglutinin-L), bind to 20-30 different components giving very complex binding patterns while those with lower Ka (Agaricus bisporus lectins, wheat germ agglutinin, peanut agglutinin, and soybean agglutinin) bind to 8--13 components with easily distinguishable patterns. Soybean agglutinin binds almost exclusively to a glycolipid fraction while for the others one or more glycopolypeptides served as the major lectin-binding molecule. The Ricinus lectins, two lymphocyte toxins, bind to essentially every plasma membrane component to which the mitogen phytohemagglutinin-L binds, in fact competing for most of those plasma membrane moieties which bind phytohemagglutinin-L.