Ultrastructural visualization of concanavalin A binding sites using alkaline phosphatase-labeled Con A and ultrathin glycol methacrylate sections

Summary A method for the visualization of concanavalin A (Con A) binding sites by electron microscopy of glycol methacrylate sections is presented. This method, which is an application of the alkaline phosphatase-labeled Con A conjugate technique, solves the problems not only of limited penetration of chemicals into tissue blocks but also of injuries to tissue sections due to irritative reagents experienced in Con A-peroxidase staining. Glycol methacrylate sections are incubated successively with an alkaline phosphatase-labeled Con A solution and a lead citrate medium for the enzyme activity. Different kinds of tissues from adult rats have been used to test the method; tracheal cartilage, aorta and jejunum. The localization of Con A binding sites demonstrated by this method is consistent with the results of other published studies. Appropriate controls have been performed (ie., omission of the conjugated lectin, lectin plus its inhibitor) and these substantiate the specificity of the method.     

Evaluation of the specificity of lectin binding to sections of plant tissue

Hand sections of young corn root tips have been used in a study of problems encountered in the binding of fluorescently-labelled lectins to plant tissues. It was found, surprisingly, that with lectins specific for a sugar known to be present (Lotus and Ulex lectins for L-fucose), with a lectin specific for a sugar thought not to be present (wheat-germ agglutinin for N-acetylglucosamine), with non-lectin glycoprotein and protein (gamma-globulin and bovine serum albumin) and with basophilic dyes (alcian blue and toluidine blue), a coincidental binding pattern similar to the pattern of autofluorescence in the same tissue was obtained. Corn root tissues include cell walls composed of complex polysaccharides esterified with ferulic acid residues, as well as mucilages which are highly hydrated and expanded. In such material, neither standard inhibition controls with haptens nor the use of a wide range of lectin concentrations are adequate to distinguish clearly specific and non-specific binding of fluorescently-labelled lectin. Therefore, lectins are not the simple test probes they have been supposed. Before interpreting results obtained in using fluorescently-labelled lectins on any tissue sections, all available information (biochemical as well as histochemical) about the tissue must be considered.     

Histochemical reactivity of the Geodia cydonium agglutinin (GCA) in human tissues

We applied a peroxidase-antiperoxidase technique to study the distribution pattern and binding characteristics of the lectin from the marine sponge Geodia cydonium (Geodia cydonium agglutinin; GCA) in various human tissues. This lectin has been shown to possess a broad reactivity, but there was a distinct distribution of binding sites within the different organs. In the histochemical system GCA displayed no blood group specificity and labeled red blood cells, the vascular endothelium, and epithelial cells showing blood group antigen expression independent of the ABH blood group status. However, inhibition of GCA reactivity by simple sugars and complex carbohydrates demonstrated tissue-specific differences of lectin binding related to the ABH blood group status of the tissue and revealed information on the structural requirements of the histological lectin binding site. Tissues that totally lacked blood group antigens or that expressed only the H-antigen disclosed a GCA reactivity which was completely inhibited by lactose. In contrast, tissues that expressed blood group A- or blood group B-antigen exhibited a lactose-resistant lectin binding which was inhibited only by water-soluble blood group substance A from peptone A and by bovine glycophorin but not by other complex carbohydrates, including human glycophorin and human asialoglycophorin. Competitive inhibition studies in situ revealed that GCA binding was not inhibited by blood group type I/II carbohydrate sequence-specific lectins or by lectins with other sugar specificities. Inhibition by lactose of GCA binding to some histological sites indicates that the binding site consists of a beta-linked galactose-containing disaccharide. However, periodate oxidation of tissue sections had no effect on lectin binding, pointing to a subterminal location of the relevant sequence. The results obtained from inhibition studies with simple saccharides and complex carbohydrates in relation to the expression of ABH blood group antigens suggest a complex lectin combining site(s) in histological specimens. The lectin may possess either one binding site with a range of affinities for different carbohydrates (besides beta-linked disaccharides the GCA binding site accommodates to carbohydrate determinants carrying the blood group A or blood group B determinant), or may possess two different binding sites. Besides an acceptor site for beta-linked disaccharides, an additional binding site may exist accommodating to extended carbohydrate sequences related to A or B blood group structures. In conclusion, GCA represents a blood group-nonspecific lectin whose binding affinities are determined by the ABH blood group status of the tissue.     

Combined Lectin Binding and PAS/Alcian Blue Staining in Glycol Methacrylate Sections

Evaluation of cryofixation and paraffin and glycol methacrylate embedding showed that lectin binding was essentially independent of the embedding medium. Fluorescence intensity increased in the following order: glycol methacrylate, paraffin and cryostat sections, The optical resolution increased in the reverse order. Semi-thin glycol methacrylate sections provided satisfactory fluorescence intensities and the best resolution of all embedding techniques applied. Furthermore the lectin treated sections can be stained further using routine histological or specific histochemical methods. The potassium hy-droxide/alcian blue/periodic acid-phenylhydra-zine-Schiff method was used successfully to demonstrate sulfated and nonsulfated sialomucins. Lectins combined with mucin histochemistry allowed visualization of specific sugar residues in the same glycol methacrylate plastic section.     

Flow injection analysis of binding reaction between fluorescent lectin and cells

A fluorometric binding assay for lectin and yeast cells using the avidin-biotin system was previously reported (Y. Oda, M. Kinoshita, and K. Kakehi, Anal. Biochem. 254, 41-48, 1997). However, the true amount of bound lectin could not be determined by this method due to difficulty in determination of the number of bound biotin molecules. In the present study, we have developed a method for assaying the binding reaction between fluorescent lectin and cells using a flow injection technique, which allows estimation of the amount of lectin bound to cells. An aliquot of the cell suspension was directly analyzed by injection into a flow injection system after the binding between the fluorescently labeled lectin and cells. The labeled lectins showed good linearity, at least over a range of 20-1000 ng as the injected amount. The intrinsic fluorescence of the labeled lectins did not change upon the binding. The binding reaction of the hydroxycoumarin-labeled lectins with yeast cells was rapid and reached an equilibrium state within 10 min. Scatchard analysis showed that Saccharomyces cerevisiae cells contained approximately 1. 3-1.6 x 10(8) binding sites per cell for Concanavalin A, Lycoris radiata agglutinin, and Tulipa gesneriana lectin with affinity constants of 3.2-4.7 x 10(6) M-1. The present method was applied to the study of binding between lectins and bacteria and mouse spleen cells. The assay method described here is highly sensitive and will be an alternative to assays using lectins labeled with radioisotopes. The procedure is quite simple and can be completed within 1 h.     

Characterization of Cell Surface Lectin-binding Patterns of Human Airway Epithelium

Glycosylated structures on the cell surface have a role in cell adhesion, migration, and proliferation. Repair of the airway epithelium after injury requires each of these processes, but the normal cell surface glycosylation of non-mucin producing airway epithelial cells is unknown. We examined cell surface glycosylation in human airway epithelial cells in tissue sections and in human airway epithelial cell lines in culture. Thirty-eight lectin probes were used to determine specific carbohydrate residues by lectin-histochemistry. Galactose or galactosamine-specific lectins labeled basal epithelial cells, lectins specific for several different carbohydrate structures bound columnar epithelial cells, and fucose-specific lectins labeled all airway epithelial cells. The epithelial cell lines 1HAEo– and 16HBE14o– bound lectins that were specific to basal epithelial cells. Flow cytometry of these cell lines with selected lectins demonstrated that lectin binding was to cell surface carbohydrates, and revealed possible hidden tissue antigens on dispersed cultured cells. We demonstrate specific lectin-binding patterns on the surface of normal human airway epithelial cells. The expression of specific carbohydrate residues may be useful to type epithelial cells and as a tool to examine cell events involved in epithelial repair.     

Lectins for histochemical demonstration of glycans

Lectins have been proven to be invaluable reagents for the histochemical detection of glycans in cells and tissues by light and electron microscopy. This technical review deals with the conditions of tissue fixation and embedding for lectin labeling, as well as various markers and related labeling techniques. Furthermore, protocols for lectin labeling of sections from paraffin and resin-embedded tissues are detailed together with various controls to demonstrate the specificity of the labeling by lectins.     

Characterization of rat colonic cell surface glycoconjugates by fluoresceinated lectins

Summary Cryostat and paraffin embedded sections from cecum, proximal and distal colonic segments of male Sherman rats were examined by fluorescence microscopy after labeling with six fluorescein-conjugated lectins. These FITC-conjugated lectins were used as specific probes to define the labeling pattern of carbohydrate containing components of the lumenal and basolateral surfaces of epithelial cells, goblet cell mucin and lumenal mucin at all three sites. Marked regional differences in labeling were detected, indicating that the various carbohydrate components of these cells differ significantly along the length of the colon. Furthermore, the patterns of labeling components with each lectin appeared to vary depending on the fixation technique employed. Cryostat preparations generally resulted in a broader distribution of label and more intense staining with these lectins than fixed paraffin sections. While the reason(s) for these variations remain unclear at this time and will require further studies, the present data emphasize the importance of the fixation method when interpreting results obtained utilizing FITC-conjugated lectins.     

Evaluation of the specificity of lectin binding to sections of plant tissue

Summary Hand sections of young corn root tips have been used in a study of problems encountered in the binding of fluorescently-labelled lectins to plant tissue. It was found, surprisingly, that with lectins specific for a sugar known to be present (Lotus andUlex lectins forl-fucose), with a lectin specific for a sugar thought not to be present (wheat-germ agglutinin for N-acetylglucosamine), with non-lectin glycoprotein and protein (-globulin and bovine serum albumin) and with basophilic dyes (alcian blue and toluidine blue), a coincidental binding pattern similar to the pattern of autofluorescence in the same tissue was obtained. Corn root tissues include cell walls composed of complex polysaccharides esterified with ferulic acid residues, as well as mucilages which are highly hydrated and expanded. In such material, neither standard inhibition controls with haptens nor the use of a wide range of lectin concentrations are adequate to distinguish clearly specific and non-specific binding of fluorescently-labelled lectin. Therefore, lectins are not the simple test probes they have been supposed. Before interpreting results obtained in using fluorescently-labelled lectins on any tissue sections, all available information (biochemical as well as histochemical) about the tissue must be considered.     

Binding Patterns of Lectins with GalNAc specificity in the mouse dorsal root ganglia and spinal cord

To localize membrane glycoconjugates in neurons of the mouse spinal cord and dorsal root ganglia (DRG), cryostat sections of newborn (P0), 7 day-old (P7), P14, P21 and P31 animals were stained with ten FITC-conjugated plant lectins, the majority of them recognizing N-acetyl-D-galactosamine (GalNAc) terminal sugar residues. In the dorsal root ganglia of P0 animals, the different lectins showed distinct patterns of labeling in either cells of the nervous system, including neurons, or other structures such as nerves or blood vessels. Moreover, some of these lectins showed important changes in their pattern of labeling during postnatal development. This was especially relevant for lectins that label a subpopulation of small-sized cells that have been previously identified as the nociceptive cells of the DRG. Enzymatic digestion of sections with neuraminidase removes sialic acid from the carbohydrate chains of glycoconjugates thus exposing novel sugar residues. When this treatment was applied to DRG sections from postnatal animals the pattern of lectin staining was either changed or eliminated and heterogeneous subsets of glycoconjugates normally masked by this sugar were exposed. In the spinal cord of PO animals, none of the lectins labeled cells in the central gray matter. However, after the enzymatic digestion of sections with neuraminidase, spinal cord motoneurons and some other cells were labeled by two of the lectins suggesting that GalNAc residues present in these cells are normally masked by terminal sialic acid. Altogether, these results show important changes in the temporal and spatial expression of glycoconjugates that may be relevant for the postnatal development of the CNS and PNS of mice.     

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.     

A new method of lectin histochemistry for the study of brain angiogenesis. Lectin angiography

In an attempt to analyse the kinetics of angiogenesis in the brain, we developed a new lectin-histochemical staining technique for identifying the vasculature. Three horseradish-peroxidase-conjugated lectins, i.e., Griffonia simplicifolia agglutinin 1 (GS1), Ricinus communis agglutinin 1 (RCA1) and soybean agglutinin (SBA), selectively stained vascular walls in brain-tissue sections. When these lectins were injected into the circulation of ether-anesthetized animals via the pulsating left ventricle, they bound specifically to the inner surface of endothelial cells and revealed the three-dimensional architecture of the vascular network within thick tissue preparations. When this technique, referred to a lectin angiography, was combined with 5-bromo-2-deoxyuridine (BudR) immunohistochemistry, proliferating capillary cells could be easily identified in three-dimensional structures of the developing vasculature. Because of its simplicity and wide applicability, lectin angiography should be useful for analysing the kinetics of angiogenesis in developmental, regenerative, and pathological conditions in various tissues and organs.     

Hematoxylin Toluidine Blue-Phloxinate Staining of Glycol Methacrylate Sections of Retina and Other Tissues

For a detailed study of the developing chick retina a technique has been developed using glycol methacrylate embedding and a hematoxylin toluidine blue-phloxinate stain. After removal of the vitreous body, one half-segment of the eye is dehydrated through graded ethyl alcohols to 95%, infiltrated and embedded in glycol methacrylate, and sectioned at 2 μm. The sections are stained in alum hematoxylin and then in a mixture containing toluidine blue-phloxinate from a stock solution of the dye that has matured for 2-3 weeks. Differentiation is not required and there is only slight staining of the plastic matrix. The quality and clarity of the sections contrasts markedly with that of similarly stained 5 μm paraffin wax sections of the retina. This technique has also been applied to skin, spinal cord, dorsal root ganglia, pancreas and small intestine. The stained sections from these tissues have proved very useful in revealing structural components.     

Distribution of lectin receptors sites in the zona pellucida of follicular and ovulated rat oocytes.

Carbohydrates of the zona pellucida (ZP) in mammals are believed to have a role in sperm-egg interaction. We have characterized the biochemical nature and distribution of the carbohydrate residues of rat ZP at the light (LM) and electron microscope (EM) levels, using lectins as probes. Immature female rats were induced to superovulate and cumulus-oocyte complexes were isolated from the oviduct, fixed with glutaraldehyde, and embedded in araldite for LM and LR-Gold for EM histochemistry. For examination of follicular oocytes, rat ovaries were fixed with glutaraldehyde and embedded in paraffin. The araldite or paraffin sections were deresined or deparaffinized, respectively, labeled with biotin-tagged lectins as probes, and avidin-biotin-peroxidase complex as visualant. For EM examination, thin LR-Gold sections were labeled with RCA-I colloidal gold complex (RCA/G) and stained with uranyl acetate. LM analyses indicate that in ovulated oocytes the ZP intensely binds peanut agglutinin (PNA); succinylated wheat germ agglutinin, (S-WGA), Griffonia simplisifolia agglutinin-I (GS-I) and soybean agglutinin (SBA), and to a lesser extent, lectins from Ricinus communis (RCA-I), Concanavaia ensiformis (Con A), Ulex europoeus (UEA-I), and wheat germ agglutinin (WGA). The neighboring cumulus cells are considerably less reactive and exhibit membrane staining only with Con A, WGA, and PNA. EM analysis of RCA/G binding revealed intensive binding to the inner layer region of the ZP and moderate binding to cytoplasmic vesicles of the cumulus cells. The ZP of follicular oocytes exhibits a different lectin binding pattern, expressed in staining strongly with PNA and S-WGA, and in a tendency of the lectin receptors to occur in the outer portion of the ZP.(ABSTRACT TRUNCATED AT 250 WORDS)     

Plant‐insect interactions: what can we learn from plant lectins?

Many plant lectins have high anti‐insect potential. Although the effects of most lectins are only moderately influencing development or population growth of the insect, some lectins have strong insecticidal properties. In addition, some studies report a deterrent activity towards feeding and oviposition behavior. Transmission of plant lectins to the next trophic level has been investigated for several tritrophic interactions. Effects of lectins with different sugar specificities can vary substantially with the insect species under investigation and with the experimental setup. Lectin binding in the insect is an essential step in exerting a toxic effect. Attempts have been made to study the interactions of lectins in several insect tissues and to identify lectin‐binding receptors. Ingested lectins generally bind to parts of the insect gut. Furthermore, some lectins such as the Galanthus nivalus agglutinin (GNA) cross the gut epithelium into the hemolymph and other tissues. Recently, several candidate lectin‐binding receptors have been isolated from midgut extracts. To date little is known about the exact mechanism for insecticidal activity of plant lectins. However, insect glycobiology is an emerging research field and the recent technological advances in the analysis of lectin carbohydrate specificities and insect glycobiology will certainly lead to new insights in the interactions between plant lectins and insects, and to a better understanding of the molecular mechanisms involved. © 2010 Wiley Periodicals, Inc.     

Comparative analysis of carbohydrate binding properties of Sambucus nigra lectins and ribosome-inactivating proteins

In the past three decades a lot of research has been done on the extended family of carbohydrate-binding proteins from Sambucus nigra, including several so-called type 2 RIPs as well as hololectins. Although all these proteins have been studied for their carbohydrate-binding properties using hapten inhibition assays, detailed carbohydrate specificity studies have only been performed for a few Sambucus proteins. In particular SNA-I, has been studied extensively. Because of its unique binding characteristics this lectin was developed as an important tool in glycoconjugate research to detect sialic acid containing glycoconjugates. At present much less information is available with respect to the detailed carbohydrate binding specificity of other S. nigra lectins and RIPs, and as a consequence their applications remain limited. In this paper we report a comparative analysis of several lectins from S. nigra using the glycan microarray technology. Ultimately a better understanding of the ligands for each lectin can contribute to new/more applications for these lectins in glycoconjugate research. Furthermore, the data from glycan microarray analyses combined with the previously obtained sequence information can help to explain how evolution within a single lectin family eventually yielded a set of carbohydrate-binding proteins with a very broad specificity range.     

A method of selective histochemical analysis of sialoglycoproteins using lectins from elder (Sambucus nigra L.)]

Good potentialities in application of elderberry (Sambucus nigra L.) bark lectin for selective histochemical identification of sialylated glycoconjugates has been demonstrated using lectin-peroxidase technique. In order to omit this lectin binding to D-galactose and N-acetyl-D-galactosamine residues, preincubation of tissue sections with non-marked PNA and SBA (or other lectins with similar carbohydrate specificity) is proposed. By means of neuraminidase digestion it has been ascertained, that oligosaccharide chains of secretory glycopolymers, synthesised in ovine submandibular gland mucocytes, contain DGal and DGalNAc residues penultimate to terminal sialic acids.     

Studies on lectins. LVII. Immunofluorescence localization of lectins present in fish ovaries

The occurrence of endogeneous lectins in the ovaries of four fish species has been studied by indirect immunofluorescence staining with antibodies against individual lectins. Paraffin sections of the ovary of perch (Perca fluviatilis L.) were treated with an antibody against perch lectin. In cryostat sections of the tench (Tinca tinca L.) ovary, the L-rhamnose-specific lectin "I" was detected with a specific antibody. In cryostat sections of both roach (Rutilus rutilus L.) and rudd (Scardinius erythrophthalmus L.) ovaries, lectins were localized using a single antibody against roach lectin. The isolation of tench lectins is briefly described. In the fish species employed for this study, lectins are associated exclusively with the content and surrounding membrane of cortical vesicles situated within the cytoplasm of maturing oocytes. The positive reaction with lectin antibody was observed almost immediately after the formation of the first cortical vesicles in the peripheral cytoplasm of early previtellogenic oocytes. Their lectin content increases during the later stages when cortical granules fill the whole cytoplasm before moving towards the cell periphery, as the oocyte starts to accumulate yolk. The presence of lectins within cortical vesicles is significant also in view of the polysaccharide content of these structures. In the vitellogenic oocytes lectins seem to move towards the cell periphery and accumulate beneath the plasma membrane. Our observations are discussed in view of the present ideas on the intracellular function of lectins, and with respect to the role of cortical vesicles in fertilization and in post-fertilization modifications of the egg envelopes.     

Lectin-binding analysis of the biofilm exopolymeric matrix carbohydrate composition of corrosion-aggressive bacteria

The carbohydrate components of biofilms of corrosion-aggressive bacteria were studied by transmisstion electron microscopy using lectins labeled with colloidal gold. N-acetyl-D-glucosamine, N-acetyl-D-galactosamine, and neutral carbohydrates D-glucose and D-mannose were found within the exopolymeric matrix. Lectins with equal carbohydrate specificity demonstrated different degrees of interaction with the carbohydrate components of bacterial biofilms. To identify N-acetyl-D-galactosamine in biofilms of Desulfovibrio sp. 10 and Bacillus subtilis 36, the LBA lectin appeared to be most specific; in the case of N-acetyl-D-glucosamine in biofilms of B. subtilis 36 and Pseudomonas aeruginosa 27, the WGA lectin. During visualization of neutral carbohydrates in the studied cultures, the PSA lectin was most specific. We have shown that lectins labeled with colloidal gold could be used as an express method for the identification and localization of carbohydrates in glycopolymers of the biofilm exopolymeric matrix.     

Expression analysis of a type S2 EUL-related lectin from rice in Pichia pastoris

Rice (Oryza sativa) expresses different putative carbohydrate-binding proteins belonging to the class of lectins containing an Euonymus lectin (EUL)-related domain, one of them being OrysaEULS2. The OrysaEULS2 sequence consists of a 56 amino acid N-terminal domain followed by the EUL sequence. In this paper the original sequence of the EUL domain of OrysaEULS2 and some mutant forms have been expressed in Pichia pastoris. Subsequently, the recombinant proteins were purified and their carbohydrate binding properties determined. Analysis of the original protein on the glycan array revealed interaction with mannose containing structures and to a lesser extent with glycans containing lactosamine related structures. It was shown that mutation of tryptophan residue 134 into leucine resulted in an almost complete loss of carbohydrate binding activity of OrysaEULS2. Our results show that the EUL domain in OrysaEULS2 interacts with glycan structures, and hence can be considered as a lectin. However, the binding of the protein with the array is much weaker than that of other EUL-related lectins. Furthermore, our results indicate that gene divergence within the family of EUL-related lectins lead to changes in carbohydrate binding specificity.