Plasma membrane glycoproteins during anuran amphibian epidermal development

Summary A cytochemical and biochemical study of galactose (Gal) and N-acetyl-glucosamine (GlcNAc) containing glycoproteins of the anuran amphibian epidermis during development has been carried out. In premetamorphic tadpoles, theGriffonia simplicifolia II lectin (GS II, specific for N-acetyl glucosamine) bound to a glycoprotein of 49 kDa in the plasma membrane of all the epidermal strata showing a basal-to-apical binding gradient. During metamorphic climax GS II labeling was progressively polarized to the outermost plasma membrane. In epidermis from juveniles and adults the staining was observed mainly in a 52 kDa band.Griffonia simplicifolia I lectin (GS I, specific for galactose) also bound to a glycoprotein of about 49 kDa in tadpoles and 52 kDa in frogs. Furthermore, a GS I labeling in bands of about 110–150 kDa appears during metamorphosis. After this process, a definitive pattern of lectin staining and K⁺-stimulated, ouabain-sensitive p-nitrophenyl phosphatase activity is established.     

A Survey of Lectin Binding in Paramecium1

To better understand the general distribution of glycoproteins and the distribution of specific glycoprotein-bound sugar residues in Paramecium, a survey of the binding pattern of selected lectins was carried out in P. tetraurelia, P. caudatum, and P. multimicronucleatum. Lectins studied were concanavalin A (Con A), Griffonia simplicifolia agglutinins I and II (GS I and GS II), wheat germ agglutinin (WGA), Ulex europaeus (UEA I), peanut agglutinin (PNA), Ricinis communis toxin (RCA₆₀) and agglutinin (RCA₁₂₀), soybean agglutinin (SBA), Bauhinia purpurea agglutinin (BPA), Dolichos biflorus agglutinin (DBA), and Maclura pomifera agglutinin (MPA). Those giving the most distinctive patterns were Con A, GS II, WGA, UEA I, and PNA. No significant differences were found between the three species. Concanavalin A, a mannose/glucose-binding lectin, diffusely labeled the cell surface and cytoplasm and, unexpectedly, the nuclear envelopes. Events of nuclear division, and nuclear size and number were thus revealed. Both WGA and GS II, which are N-acetylglucosamine-binding lectins, labeled trichocyst tips, the cell surface, and the oral region, revealing stages of stomatogenesis. The lectin WGA, in addition, labeled the compartments of the phagosome-lysosome system. The lectin PNA, an N-acetyl galactosamine/galactose-binding protein, was very specific for digestive vacuoles. Finally, UEA I, a fucose-binding lectin, brightly labeled trichocysts, both their tips and body outlines. We conclude that a judicious choice of lectins can be used to localize glycoproteins and specific sugar residues as well as to study certain events of nuclear division, cellular morphogenesis, trichocyst discharge, and events in the digestive cycle of Paramecium.     

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

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

Histochemical Observations on Carbohydrates in Connective Tissue Structures and Basement Membranes of Hemi- and Cephalochordates

Connective tissue components and light microscopical basement membranes of Saccoglossus horsti (Enteropneusta, Hemichordata) and Branchiostoma lanceolatum have been studied with Aldehyde Fuchsin, the PAS-reaction, Alcian Blue (pH 0.2) and fluorescein conjugated (FITC) lectins: concanavalin A (Con A), wheat germ agglutinin (WGA), soy bean agglutinin (SBA), leucoagglutinin (LA), Griffonia (Bandeiraea) simplicifolia agglutinin (GSA I), Griffonia (Bandeiraea) simplicifolia isolectin B₄ (GS I B4). In Saccoglossus and Branchiostoma, both the PAS-reaction and Alcian blue give a good general survey over the distribution of the principal basement membranes and connective tissue structures. Lectin binding proved less intensive in Saccoglossus than in Branchiostoma, in which FITC-Con A, FITC-GSA and FITC-WGA react strongly with the dermal (especially in the metapleural folds) and axial connective tissue, as well as the myosepta, the gill arch skeleton and numerous basement membranes. Con A outlines distinctly the major blood vessels in the pharyngeal area. Con A, WGA, GSA and GSI B₄ are markers for basement membranes.     

Morphological evidence of sperm maturation in the ampulla ductus deferentis of the bull

The present lectin histochemical comparison of cauda epididymal and ampullary bovine sperm was conducted to investigate whether ampullary secretions are involved in altering the plasma-membrane glycoconjugates of sperm. A marked redistribution of glycoconjugates between sperm from these two regions was indeed revealed on the basis of changes in binding patterns of the following fluoroscein-isothiocyanate (FITC)-labelled lectins: wheat-germ agglutinin (WGA), Maclura pomifera agglutinin (MPA), Griffonia simplicifolia I agglutinin (GS I) and Bauhinea purpurea agglutinin (BPA). This was evidenced in the first three cases by a relative reversal of staining intensity between the acrosomal and post-acrosomal regions, and by a pronounced increase in the staining of the midpiece. Changes in the distribution of BPA binding sites were limited to the latter phenomenon. The results are compared with previous findings, discussed in the context of the hypermotility characteristic of ampullary sperm and related to previously reported differences in the lectin-binding patterns of the luminal and glandular epithelia.     

Localization of prostatic glycoconjugates by the lectin-gold method.

The glycoconjugates of the lateral prostate were examined ultrastructurally by lectin-gold histochemistry in combination with a low-temperature embedding technique using Lowicryl K4M. The binding patterns of concanavalin A, wheat germ agglutinin, Griffonia simplicifolia, soybean agglutinin, peanut agglutinin, Ricinus communis agglutinin isolectin I, Griffonia simplicifolia isolectin B4, Ulex europaeus isolectin I and Phaseolus vulgaris agglutinin P have been documented in the subcellular compartments of the lateral prostate. The results show that the granular endoplasmic reticulum (GER) is rich in glycoproteins with mannosyl residues while the Golgi cisternae, secretory granules and microvilli are less so. The mannose (Man) and N-acetylglucosamine (GlcNAc) residues present in the GER of the epithelial cells may be associated with the initial assembly of the N-linked oligosaccharides of glycoproteins. The secretory granules exhibited different reactivities to lectins. Most of the lectin-binding sites confined to the limiting membranes may play a role in the transport of plasmalemma glycoconjugates to the apical plasma membrane. The epithelial Golgi stack is rich in GlcNAc, galactose (Gal), N-acetylgalactosamine (GalNAc) and sialic acid residues, and a compartmental organization of the Golgi stack is apparent which might be associated with the sequential addition of sugar residues to the oligosaccharides. The plasma membrane contains abundant Man, GlcNAc, Gal, GalNAc and complex carbohydrates, especially in the microvilli, and a differential lectin labelling was noted between the apical and basolateral plasma membrane. The present study showed that fucose-containing glycoconjugates were detected in the apical plasma membrane of the lateral prostate. The stromal extracellular matrices as well as the epithelial basement membranes demonstrated weak lectin reaction. Man, GlcNAc, Gal residues and complex sugars were also noted in the stromal tissues of the lateral prostate including the extracellular matrix, capillaries and smooth muscle.     

Lectin-induced apoptosis of tumour cells

The mechanisms of cytotoxic activity of Griffonia simplicifolia1-B₄ (GS1B₄) and wheat germ agglutinin (WGA) lectins againstvarious murine tumour cell lines were studied. Tumour cellsthat lack lectin-binding carbohydrates were resistant to lysisby these lectins. However, YAC-1 cells that expressed GS1B⁴lectin-binding sites showed low sensitivity to lysis. To furtheranalyse the relative importance of cell surface carbohydratesin lectin cytotoxicity, BL6–8 melanoma cells, which donot express the     

FLOW‐CYTOMETRIC CHARACTERIZATION OF THE CELL‐SURFACE GLYCANS OF SYMBIOTIC DINOFLAGELLATES (SYMBIODINIUM SPP.)1

Symbiodinium spp. dinoflagellates are common symbionts of marine invertebrates. The cell‐surface glycan profile may determine whether a particular Symbiodinium is able to establish and maintain a stable symbiotic relationship. To characterize this profile, eight Symbiodinium cultures were examined using eight glycan‐specific fluorescent lectin probes. Confocal imaging and flow‐cytometric analysis were used to determine significant levels of binding of each probe to the cell surface. No significant variation in glycan profile was seen within each Symbiodinium culture, either over time or over growth phase. No cladal trends in glycan profile were found, but of note, two different Symbiodinium cultures (from clades A and B) isolated from one host species had very similar profiles, and two other cultures (from clades B and F) from different host species had identical profiles. Two lectin probes were particularly interesting: concanavalin A (ConA) and Griffonia simplicifolia‐II (GS‐II). The ConA probe showed significant binding to all Symbiodinium cultures, suggesting the widespread presence of cell‐surface mannose residues, while the GS‐II probe, which is specific for glycans possessing N‐acetyl groups, showed significant binding to six of eight Symbiodinium cultures. Other probes showed significant binding to the following percentage of Symbiodinium cultures examined: wheat germ agglutinin (WGA), 37.5%; peanut agglutinin (PNA), 50%; Helix pomatia agglutinin (HPA), 50%; phytohemagglutinin‐L (PHA‐L), 62.5%; soybean agglutinin (SBA), 50%; and Griffonia simplicifolia‐IB₄ (GS‐IB₄), 12.5%. This study highlights the complexity of cell‐surface glycan assemblages and their potential role in the discrimination of different dinoflagellate symbionts by cnidarian hosts.     

A survey of lectin binding in Paramecium

To better understand the general distribution of glycoproteins and the distribution of specific glycoprotein-bound sugar residues in Paramecium, a survey of the binding pattern of selected lectins was carried out in P. tetraurelia, P. caudatum, and P. multimicronucleatum. Lectins studied were concanavalin A (Con A), Griffonia simplicifolia agglutinins I and II (GS I and GS II), wheat germ agglutinin (WGA), Ulex europaeus (UEA I), peanut agglutinin (PNA), Ricinis communis toxin (RCA60) and agglutinin (RCA120), soybean agglutinin (SBA), Bauhinia purpurea agglutinin (BPA), Dolichos biflorus agglutinin (DBA), and Maclura pomifera agglutinin (MPA). Those giving the most distinctive patterns were Con A, GS II, WGA, UEA I, and PNA. No significant differences were found between the three species. Concanavalin A, a mannose/glucose-binding lectin, diffusely labeled the cell surface and cytoplasm and, unexpectedly, the nuclear envelopes. Events of nuclear division, and nuclear size and number were thus revealed. Both WGA and GS II, which are N-acetylglucosamine-binding lectins, labeled trichocyst tips, the cell surface, and the oral region, revealing stages of stomatogenesis. The lectin WGA, in addition, labeled the compartments of the phagosome-lysosome system. The lectin PNA, an N-acetyl galactosamine/galactose-binding protein, was very specific for digestive vacuoles. Finally, UEA I, a fucose-binding lectin, brightly labeled trichocysts, both their tips and body outlines. We conclude that a judicious choice of lectins can be used to localize glycoproteins and specific sugar residues as well as to study certain events of nuclear division, cellular morphogenesis, trichocyst discharge, and events in the digestive cycle of Paramecium.     

Lectin binding sites on head structures of the spermatid and spermatozoon of the mosquito Culex quinquefasciatus (Diptera,Culicidae)

The presence of intranuclear and acrosomal lectin binding sites in spermatids and spermatozoa of the mosquito Culex quinquefasciatus was analysed. Direct and indirect lectin-gold techniques were used on LR White-embedded cells. The nuclear compartment was the structure most intensely labelled. Early spermatid nucleus showed moderate labelling for peanut agglutinin (PNA), Griffonia simplicifolia IB4 (GS-IB4) and Ricinus communis agglutinin (RCA), and light labelling for the other lectins tested. The sperm nucleus was intensely labelled by all lectins. The acrosome, an enzyme-containing structure, was labelled by some lectins. The anterior acrosomal region was labelled by PNA, while the proximal acrosomal region was labelled by PNA and G. simplicifolia II (GS II) lectins, and showed the presence of fucose residues with the use of Ulex europaeus I (UEA-I) lectin. The spermatozoa stored in the spermatheca showed the same pattern of labelling as that observed in spermatozoa localized in testis and seminal vesicles for all lectins tested. Carbohydrate residues in the nuclear compartment may be involved with the process of chromatin condensation. In the acrosomal region these residues may play a role in the process of spermoocyte interaction.     

Peroxidase Localization of Lectin Binding Sites on Plasma Membrane of the Surface Epidermis in the Rusty Blenny,Blennius sanguinolentus (Pallas, 1811)

Abstract Various horseradish peroxidase-conjugated lectins have been used for the ultrastructural localization of carbohydrate moieties of glycoconjugates on plasma membranes of the surface cells of Blennius sanguinolentus epidermis. Concanavalia ensiformis (Con A), Arachis hypogaea (PNA), Pisum sativum (PSA) and Ulex europaeus (UEA I) lectins bind only to the outermost plasma membranes, the glycocalyx and the intercellular spaces of the surface cells. Other lectins applied, such as Triticum vulgare (WGA), Glycine max (SBA) and Griffonia simplicifolia (GS I), presenting GlcNAc and GaINAc specificity, reacted with the plasma membranes of basolateral domains and gave an attenuated reaction with the outermost plasma membranes. The results suggest that regional differences exist in the distribution patterns of GlcNAc and GalNAc-terminating glycoconjugates. The possible implication of the polarized expression of these glycoconjugates in ion transport is discussed.     

Lectin binding in skeletal muscle. Evaluation of alkaline phosphatase conjugated avidin staining procedures

Summary Cryostat sections from rat gracilis muscles were incubated with different biotinylated lectins: Con A (Concanavilin A), WGA (Wheat germ agglutinin), SBA (soybean agglutinin), GS I and GS II (Griffonia simplicifolia agglutinin), LCA (Lens culinaris agglutinin), PNA (peanut agglutinin) and PSA (Pisum sativum agglutinin). The sections were subsequently treated with alkaline phosphatase conjugated avidin. The lectin binding sites were visualized after incubation in substrate media containing: (1) 5-bromo-4-chloro indoxyl phosphate and Nitro Blue tetrazolium or copper sulphate; (2) naphthol AS-MX phosphate or naphthol AS-BI phosphate and various types of diazonium salts; (3) -naphthylphosphate and Fast Blue BB; (4) -glycerophosphate according to the method of Gomori. The results obtained with the alkaline phosphatase methods were compared with those seen with a streptavidin-horseradish peroxidase procedure. Several chromogen protocols for visualizing alkaline phosphatase activity showed differences in the ability to detect lectin binding sites. A sarcoplasmic reaction was evident for Con A, GS II, WGA, LCA, and PSA after incubation in the indoxyl phosphate medium. Sarcoplasmic reaction for GS II was also noticed after incubation with naphthol AS-MX Fast Blue BB and -glycerophosphate. The latter substrate also gave rise to a sarcoplasmic Con A reaction. With the indoxylphosphate tetrazolium salt method some muscle fibres showed a very strong intracellular reaction after incubation with Con A and GS II while the staining intensity was weak in other fibres. The same muscle fibres were stained with PAS. No sarcoplasmic reactions were observed with either naphthol phosphate media or with the diaminobenzidine peroxidase methods. Further, the staining of the muscle fibre periphery, connective tissue, and capillaries was intensified using the indoxyl method. The indoxylphosphate-tetrazolium salt method seems to be suitable for future investigations of lectin binding sites in muscle sections.     

Lectin binding in the anterior segment of the bovine eye

Summary Eleven different fluorescent lectin-conjugates were used to reveal the location of carbohydrate residues in frozen sections of the anterior segment of bovine eyes. The lectins were specific for the following five major carbohydrate groups: (1) glucose/mannose group (Concanavalin A (Con A)); (2)N-acetylglucosamine group (wheat germ agglutinin (WGA)); (3) galactose/N-acetylgalactosamine group (Dolichos biflorus agglutinin (DBA),Helix pomatia agglutinin (HPA),Helix aspersa agglutinin (HAA),Psophocarpus tetragonolobus agglutinin (PTA),Griffonia simplicifolia agglutinin-I-B₄ (GSA-I-B₄),Artocarpus integrifolia agglutinin (JAC), peanut agglutinin (PNA) andRicinus communis agglutinin (RCA-I)); (4)l-fucose group (Ukex europaeus agglutinin (UEA-I)); (5) sialic acid group (wheat germ agglutinin (WGA)). All the studied lectins except UEA-I reacted widely with different structures and the results suggest that there are distinct patterns of expression of carbohydrate residues in the anterior segment of the bovine eye. UEA-I bound only to epithelial structures. Some of the lectins reacted very intensely with apical cell surfaces of conjunctival and corneal epithelia suggesting a different glycosylation at the glycocalyx of the epithelia. Also, the binding patterns of conjunctival and corneal epithelia differed with some of the lectins: PNA and RCA-I did not bind at all, and GSA-I-B₄ bound only very weakly to the epithelium of the cornea, whereas they bound to the epithelium of the conjunctiva. In addition, HPA, HAA, PNA and WGA did not bind to the corneal basement membrane, but bound to the conjunctiva and vascular basement membranes. This suggests that corneal basement membrane is somehow different from other basement membranes. Lectins with the same carbohydrate specificity (DBA, HPA, HAA and PTA) reacted with the sections almost identically, but some differences were noticed: DBA did not bind to the basement membrane of the conjunctiva and the sclera and did bind to the basement membrane of the cornea, whereas other lectins with same carbohydrate specificities reacted vice versa. Also, the binding of PTA to the trabecular meshwork was negligible, whereas other lectins with the same carbohydrate specificities reacted with the trabecular meshwork. GSA-I-B₄ reacted avidly with the endothelium of blood vessels and did not bind to the stroma, so that it made blood vessels very prominent and it might be used as an endothelial marker. This lectin also reacted avidly with the corneal endothelium. Therefore, GSA-I-B₄ appears to be a specific marker in bovine tissues for both blood vessel and corneal endothelium cells.     

Cell Surface Saccharides in Three Phytomonas Species Differing in Host Specificity

ABSTRACT. Cell surface carbohydrates of three phytoflagellates, Phytomonas francai. Phytomonas serpens and Phytomonas sp. from different hosts including cassava, coreid insect Phthia picta and the milkweed plant Euphorbia hyssopifolia, respectively, were analysed by agglutination assays employing a battery of highly purified lectins with affinity for receptor molecules containing N-acetylglucosamine (d-GlcNAc), N-acetylgalactosamine (D-GalNAc), galactose, mannose-like (D-Man-like) residues and fucose, and by binding assay using radiolabeled [¹²⁵I]-wheat germ agglutinin (WGA) and fluorescent WGA lectin, as well as glycosidases of known sugar specificity, Escherichia coli K with mannose-affinity fimbrial lectin was also used as an agglutination probe. In general, the presence of D-GlcNAc. D-GalNAc and D-Man-like residues was detected in the phytomonads' plasma membrane. These sugar moieties were confirmed in whole cell hydrolysates as assessed by gas-liquid chromatography (GLC) which in addition, also showed the presence of galactose and xylose. However, marked differences in cell surface carbohydrate structures were observed. Wheat germ agglutinin, which binds to sialic acid and/or d-GlcNAc-containing residues, shows selective agglutinin activities for P. francai and Phytomonas sp., while Bandeiraea simplicifolia II agglutinin (which recognizes d-GlcNAc units) specifically bound to Phytomonas sp. Helix pomatia agglutinin which binds to D-GalNAc-containing residues reacted preferentially with Phytomonas sp. and P. serpens. Con A, which recognizes D-Man-like receptors, agglutinates all the phytomonads; however, the higher interaction was observed with Phytomonas sp. P. francai was selectively agglutinated in the presence of E. coli fimbrial lectin. Fluorescence WGA binding was significantly decreased by N-acetylglucosaminidase activities and the cell agglutination was not altered by neuraminidase treatment, suggesting the presence of an exposed D-GlcNAc moiety on the P. francai and Phytomonas sp. surfaces. Binding studies with [¹²⁵I]-WGA essentially confirmed the fluorescence WGA binding and agglutination assays.     

Morphological study of lectin binding in the rabbit temporomandibular joint disc

Summary Glycoconjugates of the extracellular matrix are important for the normal mechanical functions of connective tissue structures such as the temporomandibular joint disc. Since lectins are known to bind to sugar residues with high affinity, a variety of lectins were used to study the presence and distribution of glycoconjugates in the temporomandibular joint disc. Discs were removed from 6 to 8-month-old rabbits and either sectioned in a cryostat and processed for light microscopy or fixed in 2% glutaraldehyde and processed for electron microscopy. The frozen sections were incubated with fluorescein- or peroxidaseconjugated lectin solutions. Ultrathin sections mounted on grids were incubated with lectins combined with a colloidal gold marker system for electron microscopical study. Our results indicate thatCanavalia ensiformis agglutinin (ConA) showed little or no binding to the discal tissue.Triticum vulgaris agglutinin (WGA) andMacluras pomifera (MPA) were bound strongly to both the synovium and the extracellular matrix and WGA also bound to the territorial matrix of chondrocyte-like cells.Glycine max andArachis hypogoea agglutinins (SBA and PNA), were localized in the synovium and extracellular matrix but to a lesser degree than WGA and MPA. WGA, MPA,Griffonia simplicifolia II andUlex europaeus were bound by discal fibroblasts. WGA was also localized in lysosomes of synovial A-cells (macrophages). The electron microscopical studies with lectins and colloidal gold marker systems indicated that some areas of the disc may be fibrocartilagenous as had been suggested by earlier immunohistochemical studies using monoclonal antibodies to characteristic glycosaminoglycans (GAGs) in cartilage.     

Changes in cell surface and intracellular glycoproteins of trophoblastic giant cells during mouse placentation

Summary Changes in lectin bindings of mouse trophoblastic giant cells (TGCs) were examined by light and electron microscopy. Neither Griffonia simplicifolia agglutinin (GS)-II nor succinyl-wheat germ agglutinin (s-WGA) bound to the 1st and 2nd TGCs on day 6.5 post coitum (p.c.), but did so from days 8.5 to 12.5 p.c. Positive reactions with s-WGA were localized in the perinuclear region and cell surface of both 1st and 2nd TGCs; while GS-II bound only to the perinuclear region, where it appeared as network-like deposits. This region was identified as well-developed Golgi lamellae by electron microscopy. Moreover, SDS-PAGE and lectin-blot analysis of the 1st TGCs indicated that the intensity of s-WGA and GS-II bindings increased in the glycoproteins of approximately 43, 40, 37, and 26 kDa and in those of 43 and 38 kDa, respectively, during the 8.5th to 10.5th day p.c. The reaction with GS-I was detected on cell surface of both the 1st and 2nd TGCs on day 6.5 p.c. The reaction in the 1st TGCs was intensely positive throughout their development, whereas the reactivity decreased in the 2nd TGCs on day 10.5 p.c. and completely disappeared on day 12.5 p.c. The GS-I reaction in TGCs was more intense at the maternal side than at the embryonic side. These results suggest that certain Gal and/or GlcNAc glycoproteins on the cell surface and in Golgi lamellae of TGCs dynamically change from the 8.5th to 10.5th day p.c. in association with mouse placentation.     

Studies of lectin binding to the human cervix uteri: II. Cervical intraepithelial neoplasia and invasive squamous carcinoma

Summary The cell surface carbohydrate profile of formalin-fixed paraffin-embedded tissue sections of neoplastic cervical squamous epithelium was evaluated using lectins ofBauhinia purpurea (BPA),Canavalin ensiformis (Con A),Griffonia simplicifolia I (GS I),Griffonia simplicifolia II (GS II),Maclura pomifera (MPA),Archis hypogaea (PNA),Glycine max (SBA),Ulex europaeus I (UEA I) andTriticum vulgaris (WGA). Three lectins (BPA, Con A and PNA) showed a similar pattern of staining in both normal squamous epithelium and in cervical intraepithelial neoplasia (CIN). Variable alterations were seen in lectin-binding patterns in CIN with seven lectins (GS I, GS II, MPA, PNA, SBA, UEA I and WGA). A significant difference was seen between the intensity of staining of normal squamous epithelium and CIN with all lectins except WGA. The alteration in GS II-binding pattern and intensity was significantly related to grade of CIN. No correlation was found between lectin binding and the presence of koilocytes in squamous epithelium. Cases of invasive squamous carcinoma showed a heterogeneous lectin-binding pattern and no siginificant association was found between lectin binding and tumour differentiation or patient survival. These results indicate that neoplasia in cervical squamous epithelium is associated with alterations in terminal -Man residues, - and -GalNAc residues, - and -GlcNAc residues, - and -Gal residues, and -Fuc-containing residues, present in the outer parts of bothN-linked andO-linked glycoconjugates. The implications of these findings are discussed.     

Fluorescein Isothiocyanate-Labeled Lectin Analysis of the Surface of the Nitrogen-Fixing Bacterium Azospirillum brasilense by Flow Cytometry

The cell surface of Azospirillum brasilense was probed by using fluorescein isothiocyanate (FITC)-labeled lectins, with binding determined by fluorescence-activated flow cytometry. Cells from nitrogen-fixing or ammonium-assimilating cultures reacted similarly to FITC-labeled lectins, with lectin binding in the following order: Griffonia simplicifolia II agglutinin > Griffonia simplicifolia I agglutinin > Triticum vulgaris agglutinin > Glycine max agglutinin > Canavalia ensiformis agglutinin > Limax flavus agglutinin > Lotus tetragonolobus agglutinin. The fluorescence intensity of cells labeled with FITC-labeled G. simplicifolia I, C. ensiformis, T. vulgaris, and G. max agglutinins was influenced by lectin concentration. Flow cytometry measurements of lectin binding to cells was consistent with measurements of agglutination resulting from lectin-cell interaction. Capsules surrounding nitrogen-fixing and ammonium-assimilating cells were readily demonstrated by light and transmission electron microscopies.     

Studies of lectin binding to the human cervix uteri: I. Normal cervix

Summary Lectins ofBauhinia purpurea (BPA),Canavalin ensiformis (Con A),Griffonia simplicifolia I (GS I),Griffonia simplicifolia II (GS II),Maclura pomifera (MPA),Arachis hypogaea (PNA),Glycine max (SBA),Ulex europaeus I (UEA I) andTriticum vulgaris (WGA) were used to evaluate cell surface carbohydrates in formalin-fixed paraffin-embedded tissue sections of normal human cervix uteri. Consistent patterns of staining of the squamous epithelium were obtained in all 30 cases with BPA, GS II, MPA, PNA, SBA and WGA. A variable distribution of lectin binding was seen in squamous epithelium with Con A, GS I and UEA I. The patterns of GS I and GS II binding reflected squamous epithelial maturation. Columnar epithelium did not stain with GS II, stained variably with Con A, and stained consistently with the remaining seven lectins in all cases. No association between lectin binding and blood group or phase of the menstrual cycle was found. These findings may be used as a baseline for evaluation of lectin binding in both preinvasive and invasive lesions of the cervix uteri.     

Identification of Plasma Membrane Glycoproteins Specific to Human Glioblastoma Multiforme Cells Using Lectin Arrays and LC‐MS/MS

Glioblastoma, also known as glioblastoma multiforme (GBM), is the most malignant type of brain cancer and has poor prognosis with a median survival of less than one year. While the structural changes of tumor cell surface carbohydrates are known to be associated with invasive behavior of tumor cells, the cell surface glycoproteins to differentiate the low‐ and high‐grade glioma cells can be potential diagnostic markers and therapeutic targets for GBMs. In the present study, lectin arrays consisting of eight lectins were employed to explore cell surface carbohydrate expression patterns on low‐grade oligodendroglioma cells (Hs683) and GBM cells (T98G). Griffonia simplicifolia I (GS I) was found to selectively bind to T98G cells and not to Hs683 cells. For identification of the glioblastoma‐specific cell surface markers, the glycoproteins from each cell type were captured by a GS I lectin column and analyzed by LC‐MS/MS. The identified proteins from the two cell types were quantified using label‐free quantitative analysis based on spectral counting. Of cell surface glycoproteins showing significant increases in T98G cells, five proteins were selected for verification of both protein and glycosylation level changes using Western blot and GS I lectin‐based immunosorbent assay.