Light and electron microscopic detection of (3 Gal beta 1,4 GlcNAc beta 1) sequences in asparagine-linked oligosaccharides with the Datura stramonium lectin

The Datura stramonium lectin recognizes with high affinity the disaccharide N-acetyllactosamine (Gal beta 1,4 GlcNAc). We have developed a highly specific cytochemical affinity technique in which an ovomucoid-gold complex serves as second step reagent for the visualization of this lectin bound to reactive sequences present in tissue sections. The lectin binding sites were detected in semithin and ultrathin sections of aldehyde-fixed and low temperature Lowicryl K4M embedded tissues. For light microscopical labeling the photochemical silver reaction for signal amplification was required. The application of this technique for the detection of N-acetyllactosamine containing asparagine-linked oligosaccharides in various intracellular organelles and the plasma membrane is demonstrated.     

A new lectin-gold complex for ultrastructural localization of galacturonic acids

We report the development of a cytochemical affinity technique for detection of galacturonic acids at the ultrastructural level. The highly purified gonad lectin from Aplysia depilans (AGL) was tagged with colloidal gold particles and used for labeling carbohydrates in resin-embedded sections of various plant and fungal tissues. Patterns of AGL binding sites were compared to those obtained with a D-galactose-specific lectin, Ricinus communis agglutinin I. Differences in labeling patterns were noted, indicating that the lectins exhibited differential carbohydrate binding. In addition, the considerable loss of labeling over isolated wheat coleoptile walls treated for removal of pectin, after incubation with the AGL-gold complex, strongly suggested an affinity of AGL for pectic substances. A series of cytochemical controls, including sugar inhibition tests, has proven the specificity of the technique and the high affinity of AGL towards galacturonic acids. The potential value of this new lectin for ultrastructural studies on cell wall pectic substances in plant biology and pathology is demonstrated.     

Dolichos biflorus agglutinin (DBA) reacts selectively with mast cells in human connective tissues

Dolichos biflorus agglutinin (DBA) binds to N-acetyl-D-galactosamine (GalNAc) residues in glycoconjugates and agglutinates erythrocytes carrying blood group antigen A. In cryostat sections of various tissues from blood group-specified humans, fluorochrome-coupled DBA bound preferentially to fusiform connective tissue cells and to certain epithelial cells. The connective tissue cells were identified as mast cells by their typical metachromasia in consecutive staining with toluidine blue. Double labeling with DBA and conjugated avidin revealed two distinct populations of mast cells. In several tissues the DBA-reactive cells likewise displayed uniform avidin reactivity. In intestinal mucosa, however, morphologically distinct DBA-binding mast cells were found, which were labeled with the avidin conjugates only in specially fixed paraffin sections. DBA did not bind to vascular endothelial cells, which could be identified by double staining with antibodies to factor VIII-related antigen. Labeling with Helix pomatia agglutinin (HPA), another blood group A-reactive lectin, resulted in distinct blood group-dependent fluorescence of the endothelia. Sophora japonica agglutinin (SJA), a blood group B-reactive lectin, labeled vascular endothelial cells in tissues from blood group A, AB, and B donors. HPA and SJA reacted with small mast cells in the gastrointestinal mucosa but failed to label large mast cells in any of the tissues. These results indicate that the blood group reactivity of lectins, as determined by erythroagglutination, is not necessarily consistent with their reactivity with blood group determinants in tissue sections. Moreover, DBA conjugates appear to be a reliable probe for detection of mast cells in various human connective tissues.     

Light and electron microscopic detection of (3 Gal β1,4 GlcNAc β1) sequences in asparagine-linked oligosaccharides with the Datura stramonium lectin

Summary The Datura stramonium lectin recognizes with high affinity the disaccharide N-acetyllactosamine (Gal 1,4 GlcNAc). We have developed a highly specific cytochemical affinity technique in which an ovomucoid-gold complex serves as second step reagent for the visualization of this lectin bound to reactive sequences present in tissue sections. The lectin binding sites were detected in semithin and ultrathin sections of aldehyde-fixed and low temperature Lowicryl K4M embedded tissues. For light microscopical labeling the photochemical silver reaction for signal amplification was required. The application of this technique for the detection of N-acetyllactosamine containing asparagine-linked oligosaccharides in various intracellular organelles and the plasma membrane is demonstrated.This study was supported by the Swiss National Science Foundation grant nr. 31-26273.89 (to J.R.) and GM 29470 from the National Institutes of Health (to I.J.G.). Dr. G. Egea was a recipient of a European Molecular Biology Organization long term fellowship.     

Role of Lectins in Plant-Microorganism Interactions: II. Distribution of Soybean Lectin in Tissues of Glycine max (L.) Merr

Three different assay procedures have been used to quantitate the levels of soybean (Glycine max [L.] Merr.) lectin in various tissues of soybean plants. The assays used were a standard hemagglutination assay, a radioimmunoassay, and an isotope dilution assay. Most of the lectin in seeds was found in the cotyledons, but lectin was also detected in the embryo axis and the seed coat. Soybean lectin was present in all of the tissues of young seedlings, but decreased as the plants matured and was not detectable in plants older than 2 to 3 weeks. Soybean lectin isolated from seeds of several soybean varieties were identical when compared by several methods.     

A Peanut Nodule Lectin in Infected Cells and in Vacuoles and the Extracellular Matrix of Nodule Parenchyma

Root nodules on peanut (Arachis hypogaea L.) accumulate a galactose/lactose-binding lectin that is similar, but not identical, to the major seed lectin in peanut. The function of the peanut nodule lectin (PNL) is not known. In the current study, we have investigated the location of lectin in the nodule using immunogold labeling and enzyme-linked immunosorbant assays (ELISA). Lectin was most abundant in the nodule parenchyma, where it accumulated in vacuoles, suggesting a possible role as a vegetative storage protein. Lectin was also detected in the extracellular matrix in the nodule parenchyma, a location that corresponds to the tissue layer forming a barrier to oxygen diffusion. The potential for interactions between PNL and other cell wall components, including a previously described high-molecular weight glycoprotein that co-localizes with PNL, is discussed. Within infected cells, lectin was not detectable by immunogold labeling within the cytoplasm, but light labeling was suggestive of lectin localization within the symbiosome lumen. Analysis of fractionated symbiosomes by the more sensitive ELISA technique confirmed that lectin was present within the symbiosome, but was not bound to bacteroids. Our results indicate that PNL probably plays several roles in this nitrogen-fixing symbiosis.     

Lectin--digoxigenin conjugates: a new hapten system for glycoconjugate cytochemistry.

We report the use of a novel hapten system for lectin cytochemistry. Various lectins conjugated to the steroid hapten digoxigenin (DIG) and monospecific anti-digoxigenin antibodies were applied for the light and electron microscopic detection of glycoconjugates in tissue sections. Both IgG and Fab' anti-DIG antibodies were complexed to particles of colloidal gold and compared to commercially available alkaline phosphatase and horseradish peroxidase conjugated Fab' as general second step reagents. The three different markers performed equally well on paraffin sections whereas the gold-labeled antibodies were superior reagents for semithin and ultrathin sections of Lowicryl K4M embedded tissues. In conjunction with the latter marker, no pretreatment to abolish endogenous enzyme activity was necessary. At the light microscope level, gold signal amplification by the photochemical silver reaction was required. DIG, in contrast to biotin, does not occur in animal tissues thus eliminating the need for blocking reactions prior to lectin incubation. Compared to affinity techniques using glycoprotein-gold complexes as second step reagent the DIG hapten system required smaller amounts of lectins. The staining patterns were indistinguishable from those obtained in other lectin-gold techniques and the specificity of the labeling could be demonstrated in sugar inhibition tests.     

Lectin — digoxigenin conjugates: a new hapten system for glycoconjugate cytochemistry

Summary We report the use of a novel hapten system for lectin cytochemistry. Various lectins conjugated to the steroid hapten digoxigenin (DIG) and monospecific anti-digoxigenin antibodies were applied for the light and electron microscopic detection of glycoconjugates in tissue sections. Both IgG and Fab' anti-DIG antibodies were complexed to particles of colloidal gold and compared to commercially available alkaline phosphatase and horseradish peroxidase conjugated Fab' as general second step reagents. The three different markers performed equally well on paraffin sections whereas the gold-labeled antibodies were superior reagents for semithin and ultrathin sections of Lowicryl K4M embedded tissues. In conjunction with the latter marker, no pretreatment to abolish endogenous enzyme activity was necessary. At the light microscope level, gold signal amplification by the photochemical silver reaction was required. DIG, in contrast to biotin, does not occur in animal tissues thus eliminating the need for blocking reactions prior to lectin incubation. Compared to affinity techniques using glycoprotein-gold complexes as second step reagent the DIG hapten system required smaller amounts of lectins. The staining patterns were indistinguishable from those obtained in other lectin-gold techniques and the specificity of the labeling could be demonstrated in sugar inhibition tests.     

Distribution of a lectin in tissues of Phaseolus vulgaris

The distribution of lectin in various tissues of Phaseolus vulgaris L. (var. red) has been investigated with the use of a sensitive solid phase enzyme immunoassay. Plants were divided into roots, stems and leaves with a further dissection of the stem into internodes. Isolated tissues, from plants 3-10 weeks old, were screened for their lectin content, and the development of the lectin over this period determined. Stems and roots contained significant amounts of lectin, whereas the leaves only exhibited very low levels. Furthermore, a pronounced and differential increase in the biosynthesis of the lectin was observed in stem sections between 6 and 10 weeks, where the third internode displayed the highest lectin level.     

Detection and characterization of a lectin from non-seed tissue ofPhaseolus vulgaris

The distribution of lectin in various tissues ofPhaseolus vulgaris L. (cv. red) has been investigated using a sensitive solid-phase enzyme immunoassay. Roots, leaves and stems from 3- to 4-week-old plants were screened for their lectin content; low levels could be detected in all organs, with a relative distribution of 37% in roots, 20% in leaves and 43% in stems. The lectin from stemsleaves and roots was then isolated from 5- to 6-week-old plants using extraction, salt fractionation and affinity chromatography on immobilized porcine thyroglobulin. A comparative study of the seed lectin and the lectin isolated from 5- to 6-week-old plants was made using hemagglutination, inhibition of hemagglutination, immunodiffusion, polyacrylamide and agarose electrophoresis. The results showed that lectin isolated from the different tissues was immunologically identical and exhibited the same subunit structure and similar isolectin composition as the seed lectin.Abbreviations EDTA ethylenediaminetetraacetic acid - PHA phytohemagglutinin - SDS sodium dodecyl sulfate     

Implication of Pectic Components in Cell Surface Interactions between Tomato Root Cells and Fusarium oxysporum f. sp. radicis-lycopersici: A Cytochemical Study by Means of a Lectin with Polygalacturonic Acid-Binding Specificity

Aplysia gonad lectin, a polygalacturonic acid-binding lectin isolated from the sea mollusc Aplysia depilans, was complexed to colloidal gold and used for localizing polygalacturonic-acid-containing molecules in tomato root tissues infected with Fusarium oxysporum f. sp. radicis-lycopersici (FORL). Colonization of host tissues by FORL was associated with striking wall modifications including disruption and even loss of middle lamellae. According to the labeling pattern observed in host wall areas adjacent to fungal penetration channels, it is likely that FORL pectolytic enzymes act through localized wall degradation. The release of polygalacturonic acid-rich wall fragments and the accumulation of polygalacturonic acid-containing molecules in some altered phloem cells were frequently observed and considered to be specific host reactions to fungal attack. The heavy deposition of such molecules at strategic sites such as wall oppositions and intercellular spaces provides support to their implication in the plant defense system. The possible interrelation between polygalacturonic acid-containing molecules and other polymers such as lignin and phenolic compounds remains to be investigated further. The role of these molecules in host-pathogen interactions is discussed in relation to plant defense.     

Lectin in Vegetative Tissues of Adult Barley Plants Grown under Field Conditions

A study of the distribution of lectins over different vegetative tissues of barley (Hordeum vulgare L.) plants, which were grown under normal crop conditions, indicated that lectin occurs in roots, leaves, and developing ears. Isolation and characterization of both root and leaf lectins led to the conclusions (a) that they are indistinguishable from the embryo lectin and (b) that the total lectin content of these vegetative organs is many times higher than that of the embryo. Finally, in vivo labeling experiments demonstrated that the lectin is synthesized de novo in roots and leaves.     

Purification and characterization of beta-galactoside-binding lectin from chick embryonic skin

Lectin activity was found in tarsometatarsal skin of chick embryo. It was specific for beta-linked galactosyl residues and required a thiol-reducing agent for hemagglutination activity. The lectin was extracted from dermis and epidermis (skin) with lactose and purified to apparent homogeneity by affinity chromatography on asialofetuin-Sepharose. Examination of their biochemical properties showed that although dermis and epidermis develop from different origins, they contain the same lectin. The apparent subunit Mr of lectin was 14000 and its isoelectric point was 7.0. Under non-dissociating conditions, the lectin exists mainly as a dimer. Radioimmunoassay showed that this skin-type lectin is present in many tissues including skin, muscle, bone, eye, heart, liver and brain at various developmental stages. A wide distribution and a marked change in its content during development strongly suggest that the lectin might have a fundamental role in cellular function, embryonic development and tissue differentiation.     

Immunocytochemical evidence for the involvement of golgi apparatus in the deposition of seed lectin ofBauhinia purpurea (Leguminosae)

Summary The seed lectin of the tree legume,Bauhinia purpurea alba, was localized by electron microscopic immunocytochemistry. The pattern of lectin deposition and site of intracellular localization was examined in mid- to late-maturation seeds. The seed tissue was embedded in Lowicryl K4M, the use of which with seed tissues is discussed. Immunocytochemical labeling was accomplished with colloidal gold coupled to a second antibody. The immunocytochemical reaction was specific and sensitive. Protein bodies, Golgi apparatus and Golgi secretion vesicles were densely labeled. Golgi apparatus was oriented such that Golgi secretion vesicles were in close proximity to the protein bodies. The entire Golgi apparatus was labeled with no concentration gradient across the Golgi stack. These observations indicate that the final site of lectin deposition is the protein body, and that the Golgi apparatus plays an essential role in the deposition process.     

Characterization of carbohydrates of adult Echinococcus granulosus by lectin-binding analysis

The identification of lectin-binding structures in adult worms of Echinococcus granulosus was carried out by lectin fluorescence; the distribution of carbohydrates in parasite glycoconjugates was also studied by lectin blotting. The lectins with the most ample recognition pattern were ConA, WGA, and PNA. ConA showed widespread reactivity in tegument and parenchyma components, including the reproductive system, suggesting that mannose is a highly expressed component of the adult glycans. Although reproductive structures appeared to be rich in N-acetyl-D-glucosamine (GlcNAc)-N-acetyl neuraminic acid (NeuAc) and galactose (Gal) as demonstrated by their strong reactivity with WGA and PNA, respectively, some differences were observed in their labeling patterns. This was very clear in the case of the vagina, which only reacted with WGA. Furthermore, WGA and ConA both had reactivity with the excretory canals. RCA, the other Gal binding lectin used, only reacted with the tegument, suggesting that widespread PNA reactivity with the reproductive system is related to the presence of the D-Gal-beta-(1,3)D-GalNAc terminal structure. UEA I failed to bind to any parasite tissues as determined by lectin fluorescence, whereas DBA and SBA showed a very faint staining of the tegument. However, in transferred glycans, N-acetyl-D-galactosamine (GalNAc) and fucose (Fuc) containing glycoproteins were distinctly detected.     

Assay of lectin binding sites in colon cancer-associated mucins: comparison of fluorescence microscopy with a quantitative chromatographic technique

We have developed a technique for quantitation of binding of fluorescent lectins to glycoconjugates in specimens of tumors derived from cultured human colorectal cancer cells. Tumor cells were injected subcutaneously into nude mice, giving rise to xenografts that resemble primary human colorectal cancers. The tumors were extracted with saline and were subjected to dialysis and lyophilization. Standardized amounts of the tumor extract were then incubated with fluorescent lectins and subjected to gel permeation liquid chromatography to separate lectin bound to high molecular weight glycoproteins from free (unbound) lectin, and were quantitated using a spectrofluorometer. This assay permitted quantitative measurement of the lectin bound to high molecular weight glycoconjugates such as mucin. The results of this assay were compared with the standard histochemical assessment of tissue labeling by fluorescent lectins. A close correlation between the two techniques was found, especially when little or no labeling was present. Greater variations were observed at higher levels of labeling. The quantitative assay confirms that lectins bind to high molecular weight mucin-type glycoconjugates on fixed sections of tumors, and supports the use of semi-quantitative histochemical assessments of tissue labeling.     

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.     

Chicken tissue binding sites for a purified chicken lectin

A lactose-binding lectin previously purified from embryonic chicken muscle and adult chicken liver, and here referred to as chicken-lactose-lectin-I (CLL-I), was added to sections of various adult chicken tissues to detect available binding sites. Both the sites of binding of added CLL-I as well as the tissue distribution of endogenous CLL-I were determined by indirect immunofluorescence using a rabbit antibody to CLL-I followed by fluorescent goat anti-rabbit IgG. Some tissues such as intestine and kidney showed abundant extracellular binding sites for the lectin, primarily between cells, in basement membrane, and in material on the luminal surface. In contrast, adult heart showed no significant binding sites for CLL-I. Adult pancreas showed considerable endogenous CLL-I in an extracellular site surrounding exocrine lobules, but added CLL-I did not bind substantially. The distribution of CLL-I binding sites in intestine were mimicked by those of purpurin, another lactose-binding lectin. CLL-I binding sites were also detected on the surface of cultured chick embryo skin fibroblasts. The factors controlling the specific distribution of occupied and unoccupied CLL-I binding sites are not known.     

Tissue and subcellular distribution of the lectin from Datura stramonium (thorn apple).

Plants of Datura stramonium (thorn-apple) were dissected into their component tissues and examined for the presence of the Datura lectin. This lectin was easily detected in seeds and in various parts of the flowers of adult plants. Traces were also found in green (emerged) cotyledons and roots of seedlings. The specific lectin activity in seeds contained within the fruits increased as the seeds matured. Mature seeds were homogenized in sucrose and separated by differential centrifugation into four fractions, three of which were clearly of distinct composition. Most of the lectin activity sedimented with the low-speed (cell-wall/protein-body) pellet, but a similar specific activity was recovered from the other fractions. However, if EDTA was included in the homogenization medium, three or four times more lectin activity was recovered in the soluble fraction. Immunofluorescent staining of formaldehyde-fixed sections showed that the lectin was localized in the cytoplasm, with little associated with cell walls. The possible relevance of these results to the function of the lectin in plant cells is discussed.     

Phosphotyrosine-modified proteins are concentrated at the membranes of epithelial and endothelial cells during tissue development in chick embryos

We have used high affinity polyclonal antibodies specific for phosphotyrosine (PTyr) residues to examine the localization in various chick embryonic tissues in situ of PTyr-modified proteins by immunocytochemical methods. During the period from 9 to 21 d of development, most tissues exhibit elevated levels of PTyr-modified proteins as determined by immunoblotting experiments of tissue extracts with the anti-PTyr antibodies (Maher, P. A., and E. B. Pasquale. 1988. J. Cell Biol. 106:1747-1755). By immunofluorescence labeling of semithin frozen sections, the highest concentrations of PTyr immunolabeling in all of the embryonic tissues examined were localized to the membranes of the epithelial and endothelial cells with other cells showing no detectable labeling. These results were confirmed by immunoelectron microscopic labeling, which showed particularly high concentrations of PTyr-modified proteins close to the membranes at the apical junctions. The corresponding adult tissues showed no labeling. It is proposed that these results reflect the molecular basis for the functional plasticity of epithelial and endothelial cell junctions during embryonic development.