Preparation of carbohydrate-iron complexes as electron dense receptors for membrane bound lectins

Summary The preparation of a mannan-iron complex is described. The mannan-iron complex can be used for electron microscopic demonstration of membrane bound Concanavalin A or Lens culinaris lectin because the high reactivity of these lectins toward the mannan.     

Histochemical lectin affinity technique by means of FITC-labeled serum protein fractions

Summary A two-step affinity technique is described for light microscopic demonstration of the Concanavalin A, Agaricus bisporus lectin and Ricinus communis lectin binding sites by means of various FITC-labeled human and rabbit serum protein fractions. Experiments for the visualization of the Lens culinaris lectin and the Pisum sativum lectin binding sites gaves negative results. The technique consist of two reaction steps which involve the incubation of tissue sections in the lectins followed by the visualization of receptor-bound lectins with FITC-labeled serum protein fractions basing on their carbohydrate content. The specificity of the technique could be demonstrated by the addition of the hapten or by incubation in the FITC-labeled serum protein fractions only. In contrast to the direct or indirect staining methods only very small amounts of purified lectins are necessary.     

Electron microscope study of the binding of Con A-gold to superficial and inner ectoderm layers ofXenopus laevis and its relation to the neural-inducing activity of this lectin

Summary Isolated competent amphibian ectoderm differentiates into neural (archencephalic) structures when treated with the plant lectin concanavalin A (Con A). While the inner ectoderm layer ofXenopus laevis forms brain structures after incubation with Con A, the outer ectoderm layer differentiates into ciliated epidermis only. This difference can be correlated with the pattern of Con A bound to the plasma membrane. With gold-labelled Con A it could be shown by transmission electron microscopy (TEM) that the outer ectoderm binds substantially less lectin than the inner layer. Furthermore we observed characteristic differences at the apical and basal surfaces of the cells of the same layer, i.e. on the apical cell surface of the superficial layer almost no Con A-gold could be found. In contrast, we observed a lot of gold particles on the basal cell side of the superficial layer. However, the number on both surfaces (apical and basal side of the cell) of the inner ectoderm layer was essentially higher, which could explain its biological reaction to the Con A stimulus and the differentiation into neural structures. The data presented in this paper indicate that early and late gastrula ectoderm bind similar amounts of Con A and support the view that the decrease in competence is not correlated with a loss of receptors for inducing factors. Furthermore, we describe the binding and the internalization of Con A via receptor-mediated endocytosis and the further fate of the Con A-gold-receptor complex inside the target cell.     

Distribution and mobility of lectin receptors on synaptic membranes of identified neurons in the central nervous system

The distribution and mobility of concanavalin A (Con A) and Ricinus communis agglutinin (RCA) receptors (binding sites) on the external surfaces of Purkinje, hippocampal pyramidal, and granule cells and their attached boutons were studied using ferritin-lectin conjugates. Dendritic fields of these cells were isolated by microdissection and gently homogenized. Cell fragments and pre- and postsynaptic membranes were labeled with the ferritin-lectin conjugates at a variety of temperatures, and the distribution of lectin receptors was determined by electron microscopy. Both classes of these lectin receptors were concentrated at nearly all open and partially open postsynaptic junctional membranes of asymmetric-type synapses on all three neuron types. Con A receptors were most concentrated at the junctional membrane region, indicating that the mature neuron has a specialized nonrandom organization of carbohydrates on its outer surface. Lectin receptors located on postsynaptic junctional membranes appeared to be restricted in their mobility compared to similar classes of receptors on extrajunctional membrane regions. Labeling with ferritin-RCA and - Con A at 37 degrees C produced clustering of lectin receptors on nonjunctional surfaces; however, Con A and RCA receptors retained their nonrandom topographic distribution on the postsynaptic junctional surface. The restricted mobility of lectin receptors was an inherent property of the postsynaptic membrane since the presynaptic membrane was absent. It is proposed that structures in the postsynaptic density may be transmembrane-linked to postsynaptic receptors and thereby determine topographic distribution and limit diffusion of specialized synaptic molecules. Speicalized receptor displays may play an important role in the formation and maintenance of specific synaptic contacts.     

Effect of concanavalin A on the level of sulfhydryl groups in thymocytes

Fluorescein mercury acetate (FMA), a fluorescent probe, is used for the investigation of SH-groups of thymocytes' plasma membrane. It is found that mitogenic lectin Con A decreases the amount of membrane SH-groups and increases the fluorescence polarization degree of FMA (PFMA). The value of PFMA increases also during the incubation of cells with potassium ferricyanide and H2O2 but it decreases in the presence of NADH. The analysis of the data permits a conclusion that the thymocyte activation by Con A results in the selective oxidation of certain SH-groups with the formation of disulphide cross-linking between the plasma membrane receptors bound with the lectin molecules.     

A new method for cytochemical demonstration of calcium in heart muscle

Summary The ortho-cresolphtalein complex was successfully adapted for the electron microscopic cytochemical demonstration of calcium. The reaction product is of granular nature with sufficient electron density for finer localization. Intense precipitation was found on the sarcolemma and transverse tubules and in the sarcoplasmic reticulum. Myofilaments, mitochondria and capillary endothelial cells also showed a positive reaction. The electron microprobe analysis of the precipitate proved the presence of calcium. Disturbing effects of magnesium ions were prevented by the incorporation of 8-hydroxyquinoline in the incubation medium.     

Selective binding and transcytosis of Ulex europaeus 1 lectin by mouse Peyer's patch M-cells in vivo

The in vivo interaction of the lectin Ulex europaeus agglutinin 1 with mouse Peyer's patch follicle-associated epithelial cells was studied in the mouse Peyer's patch gut loop model by immunofluorescence and electron microscopy. The lectin targets to mouse Peyer's patch M-cells and is rapidly endocytosed and transcytosed. These processes are accompanied by morphological changes in the M-cell microvilli and by redistribution of polymerised actin. The demonstration of selective binding and uptake of a lectin by intestinal M-cells in vivo suggests that M-cell-specific surface glycoconjugates might act as receptors for the selective adhesion/uptake of microorganisms.This work was supported under the LINK programme in Selective Drug Delivery and Targeting, funded by SERC/MRC/DTI and industry (SERC grant GR/F 09747). M.A.J. was also supported by a Wellcome Postdoctoral Research Followship (039684/Z/93/Z). Additional support was provided by the Royal Society for equipment.     

Location of glycoproteins on milk fat globule membrane by scanning and transmission electron microscopy, using lectin-labelled gold granules

Membrane glycoproteins of bovine and human milk fat globules (MFG) were located by scanning electron microscopy using lectin-labelled gold granules (50 nm diameter) as specific markers. Receptors for wheat germ agglutinin (WGA) and soybean lectin (SBA) were localized in clusters over the whole MFG surface. When MFG were treated with neuraminidase, the density of marking with SBA increased. Marking of MFG with Concanavalin A (ConA) was weak. No marking was obtained with lectins specific for -fucose, -galactose and α- -galactose. When thin sections of MFG marked with WGA (18 nm diameter gold granules) were examined by transmission electron microscopy, the membrane was uniformly marked. Using markers of different sizes (5 and 18 nm diam.) prefixed milk fat globule membranes (MFGM) were simultaneously marked with WGA and SBA. The lectin receptors appeared to belong to different glycoproteins which were clustered. Thin sections of this material showed that the receptors were located on one side of the membrane. No difference was observed between bovine MFG and human MFG from donors having blood group O and A. All results indicated that MFGM is a true biological membrane.     

Immune complex receptors on cell surface. I. Ultrastructural demonstration of macrophages.

A method is described for ultrastructural localization of immune complex receptors on the surface of viable peritoneal exudate cells. The technique entails incubation with a soluble complex of horseradish peroxidase (HRP) and specific antibody to HRP at 4 degrees C followed by exposure to diaminobenzidine and processing for electron microscopy. The bound immune complexes were evident as focal deposits of HRP reaction product, adhering closely to the external surface of macrophages with an uninterrupted periodicity varying between 30 and 120 nm. Following incubation with an insoluble immune complex containing a higher proportion of antibody, receptor sites stained frequently, but large aggregates adhered to the cells. Rinsing cells after staining with soluble complexes partially displaced the bound immune complexes. Fixation prior to exposure to immune complexes largely eliminated the binding capacity of the immune complex receptors.     

Localization of the binding sites for the Ricinus communis, Agaricus bisporus and wheat germ lectins on human erythrocyte membranes.

Freeze-etch electron microscopy has been utilized to localize the binding sites for the Ricinus communis, Agaricus bisporus and wheat germ lectins on human erythrocyte membranes and to determine the relation of these different glycoprotein receptors to the intramembranous particles. A. bisporus lectin, which could be visualized directly on the surface of erythrocyte membranes, and ferritin conjugates of wheat germ agglutinin showed a distribution that correlates exactly with the intramembranous particles at all lectin concentrations tested. The binding sites for both of these lectins are located on the major sialoglycoprotein of the membrane. The R. communis agglutinin-ferritin conjugate which binds to receptors on membrane glycoproteins that are distinct from the major sialoglycoprotein showed a close correlation with the intramembranous particles at low lectin concentrations and a poor correlation at high lectin concentrations. High concentrations resulted in virtually complete coating of the surface of trypsinized ghosts which displayed marked aggregation of the intramembranous particles. We conclude that the intramembranous particles of erythrocyte membranes contain at least two glycoproteins and that some membrane lectin receptors are not associated with the intramembranous particles.     

Time-dependent lectin binding to isolated receptors in model membranes

Binding of lectins to two integral membrane glycoproteins has been measured in lipid bilayer model membranes and in their cell of origin with an eye to clarifying the basis of time-dependence in such processes. Specific binding was monitored as a function of time using an assay that involved membrane exposure to radiolabelled wheat-germ agglutinin or concanavalin A, and subsequent differential centrifugation to remove unbound material. Qualitatively, the time dependence of lectin binding to the isolated receptors in lipid bilayers was found to be similar to that for the same receptors in the intact cell - hence the phenomenon does not depend for its existence upon receptor interaction with other specific native membrane components. Quantitatively, the time-course was sensitive to structural features of the model membrane involved. The results may be understood by viewing the glycopeptide headgroups as deformable structures which rearrange as a direct result of lectin attachment, and it would appear that rearrangement is essential for high-affinity binding. Model membrane structure was examined by light microscopy and freeze-etch electron microscopy in an attempt to assess the applicability of this type of study to a more detailed analysis of the processes involved in lectin binding. Although the freeze-etch technique is a promising one, it was concluded that heterogeneity in receptor arrangement within the lipid bilayer is the most important limitation to correlation of binding curves with membrane structure.     

Urothelium-specific antibody and lectin surface mapping of bladder urothelium

Summary Coupled ligand-colloidal gold complexes were found to provide a convenient approach for the localization by scanning electron microscopy of cell surface membrane antigens and lectin-binding sites on bladder urothelium and for the immunocytochemical identification of urothelial cell populations at different stages of differentiation. The ligands used to probe the membrane were a urothelium-specific rabbit antibody raised to a urothelial membrane-associated antigen (UMA), and two lectins: Concanavalin A (Con A) and peanut agglutinin (PNA). A complex luminal surface distribution pattern was demonstrated by the UMA antigen related to the stage of urothelial cell maturation and differentiation. UMA could be detected on the surface of immature and early differentiating intermediate cells, but was absent from the late differentiation stage, becoming re-expressed as the cells matured and was found in greatest abundance on the terminally differentiated superficial cells. It was absent on cells in benign hyperplasia of the urothelium. Cellular and regional differences in lectin binding to the urothelial cell surface was suggested with Con A receptors localized uniformly over the superficial cells, and PNA receptors confined to linear arrays or occasional clusters over the apical surface but evenly dispersed over the lateral surface of these cells.     

Histochemical technique for the demonstration of pyruvate kinase activity

We describe an enzyme histochemical multistep technique for the demonstration of pyruvate kinase activity. In this technique, a semipermeable membrane is interposed between the incubation medium and the tissue sections, thus preventing diffusion of the enzyme into the medium during the incubation period. In this histochemical system, phosphoenolpyruvate (PEP) donates its phosphate group to ADP in a reaction catalysed by pyruvate kinase. Next, exogenous and endogenous hexokinase catalyses the reaction between ATP and D-glucose to yield D-glucose-6-phosphate and ADP. The D-glucose-6-phosphate is oxidized by exogenous and endogenous D-glucose-6-phosphate dehydrogenase, and concomitantly, the generated electrons are transported via NADP+, phenazine methosulphate and menadione to nitro-BT, which is finally precipitated as formazan. Sodium azide and amytal are included to block electron transfer to cytochromes. The method proved to be of value for the qualitative demonstration of pyruvate kinase activity in tissue sections of kidneys, heart muscle and skeletal muscle. For quantitative studies and for investigating the activity of this enzyme in liver sections, the method cannot be recommended.     

Distribution and mobility of concanavalin a receptors on isolated guinea pig epidermal cells at various stages of differentiation

Trypsinized guinea pig epidermal cells were separated by velocity sedimentation at unit gravity. Based on the relationship between cell size and both morphological and functional aspects of differentiation, the cells were classified as lower (a diameter <12.5 μM), middle (a diameter between 12.5 and 15 μM), and upper (a diameter >15 μM) epidermal cells. Fresh cells exposed to rhodaminated concanavalin A (Con A) were sedimented and reacted with fluoresceinated anti-Con A serum to distinguish cell surface Con A from intracellular lectin. Labeling at 4°C resulted in a uniform surface distribution of Con A irrespective of cell size. After a 1-hr incubation of Con A-labeled cells in lectin-free medium at 37°C, lower epidermal cells and approximately half of middle epidermal cells internalized Con A/receptor complexes by endocytosis while lectin remained diffusely on the remainder of middle epidermal cells and upper epidermal cells. By electron microscopy, ferritin-Con A was clustered on surface areas and invaginations of the plasma membrane before being endocytosed. We concluded that the differentiation of epidermal cells was accompanied by progressive decrease in endocytosis and, most probably, mobility of Con A receptors.     

Changes of localization of lectin-binding sites on the intestinal epithelial cell surface membrane during differentiation of the columnar intestinal cells

Light and electron microscopically localizations of Concanavalin A, Soybean Agglutinin, and Asparagus Pea Lectin-binding sites on the intestinal microvillous membrane were studied by means of horseradish peroxidase labelled lectins. The distribution of the lectin-binding sites was composed with the cell differentiation from the crypts to the tip of the intestinal villi. The visualization of lectin receptors in the mucin vesicles in the goblet cells was established as well. The controls for the determination of the specificity of reactions were carried out.     

Lectins as biochemical agents for the isolation of sealed membrabe vesicles of defined polarity

The asymmetric distribution of carbohydrate on biological membranes has provided the basis for the development of lectin-affinity methodology which permits the isolation of sealed, inside-out membrane fractions from heterogeneous populations of vesicles.Optimal conditions for these separations have been assessed employing purified right-side-out and inside-out vesicles derived from the plasma membrane of human erythrocytes as a model system. In this special case, homogeneous populations of defined polarity can be produced by varying the ionic conditions during formation of the vesicles. Surface-specific enzymic markers exist also for monitoring the integrity and orientation of a given population.Multivalent lectins such as wheat germ agglutinin and soya bean agglutinin, which induce direct agglutination of erythrocyte membrane fragments containing accessible carbohydrate residues, selectively remove more than 90% of right-side-out and non-sealed membrane from mixed population, a reaction which is inhibited by GluNAc or GalNAc, respectively.Non-agglutinating lectins, e.g. concanavalin A, immobilized on an inert matrix such as Sepharose 4B, may be employed to adsorb out specifically vesicles with exposed glycopeptides on their surface. In this technique, it is necessary normally to remove the non-sealed membranes on Dextran density gradients prior to the final preparation of inside-out vesicles on Con A-Sepharose.Finally, selective immunoprecipitation of fragments with accessible sugars may also be achieved after treatment with a non-agglutinating lectin (concanavalin A) followed by incubation with anti-concanavalin A IgG which promotes rapid aggregation of membrane containing exposed receptors for the lectin.These procedures should prove generally suitable for the isolation of tightly-sealed, inside-out membrane populations in a variety of biological systems. Pure populations of vesicles, exhibiting reversed polarity, are valuable in surface-labelling studies for investigating the structure, function and transmembrane distribution of integral membrane proteins/glycoproteins.     

Insights from the structure of the yeast cytochrome bc1 complex: crystallization of membrane proteins with antibody fragments

The ubiquinol:cytochrome c oxidoreductase (EC 1.20.2.2, QCR or cytochrome bc1 complex) is a component of respiratory and photosynthetic electron transfer chains in mitochondria and bacteria. The complex transfers electrons from quinol to cytochrome c. Electron transfer is coupled to proton translocation across the lipid bilayer, thereby generating an electrochemical proton gradient, which conserves the free energy of the redox reaction. The yeast complex was crystallized with antibody Fv fragments, a promising technique to obtain well-ordered crystals from membrane proteins. The high-resolution structure of the yeast protein reveals details of the catalytic sites of the complex, which are important for electron and proton transfer.     

Isolation and properties of a mannan-binding lectin from the coelomic fluid of the holothurian Cucumaria japonica

A new 44-kD, C-type mannan-binding lectin (MBL-C) consisting of two identical subunits was isolated from the coelomic fluid of the holothurian Cucumaria japonica. In the direct hemagglutination assay, the lectin was effectively inhibited by highly branched mannans similar in structure to yeast mannans and composed of alpha-(1-->2)- and alpha-(1-->6)-bound D-mannopyranose residues. Hemagglutination was not inhibited by mannosaccharides, common constituents of the hydrocarbon chains of "normal" glycoproteins. The lectin reaction depends on Ca2+ concentration: maximum activity of MBL-C is observed at 10 mM Ca2+. The activity of MBL-C increases in the pH range from 5 to 7 and reaches maximum at pH 7.0. The lectin is sensitive to temperature. Heating of the lectin solution at temperatures above 40 degrees C decreases activity, while incubation at 90 degrees C for 1 h leads to complete irreversible inactivation. Carbohydrate specificity, Ca2+-dependence, and amino acid composition indicate that MBL-C belongs to the C-type mannan-binding lectins. Polyclonal antibodies against MBL-C revealed its immunochemical similarity to a mannan-binding lectin from another holothurian species, Stichopus japonicus; this provides evidence for structural homology between these proteins.     

C32 human melanoma cell endogenous lectins: characterization and implication in vesicle-mediated melanin transfer to keratinocytes.

To optimize skin pigmentation in order to help body prevention against UV radiation, the mechanism of melanin pigment transfer from melanocytes to keratinocytes must be elucidated. Melanin transfer to keratinocytes requires specific recognition between keratinocytes and melanocytes or melanosomes. Cell surface sugar-specific receptor (membrane lectin) expression was studied in human C32 melanoma cells, an amelanotic melanoma, by flow cytometry analysis of neoglycoprotein binding as an approach to the molecular specificity. Sugar receptors on melanocytes are mainly specific for alpha-L-fucose. Their expression is enhanced upon treatment by the diacylglycerol analogue 1-oleoyl-2-acetylglycerol, which can induce melanin synthesis in amelanotic human melanoma cells in a dose-dependent manner. Flow cytometry analyses showed a small-sized population of vesicles distinguishable from large cells by their fluorescence properties upon neoglycoprotein binding. Sorting indicated that the small-sized subpopulation is composed of vesicles produced by melanocytic cells. Upon vesicle formation, a selective concentration of sugar receptors specific for 6-phospho-beta-D-galactosides appears in the resulting melanocytic vesicles. Vesicles are recognized and taken up by cultured keratinocytes and a partial inhibitory effect was obtained upon cell incubation in the presence of neoglycoproteins, indicating a possible participation of sugar receptors in this recognition. The validity for such a model to help in understanding the natural melanin transfer by melanosomes is confirmed by electron microscopy, which demonstrates the presence of melanin inside keratinocytic cells upon incubation with melanocytic vesicles.     

Localization of the binding sites for the Ricinus communis, Agaricus bisporus and wheat germ lectins on human erythrocyte membranes

Freeze-etch electron microscopy has been utilized to localize the binding sites for the Ricinus communis, Agaricus bisporus and wheat germ lectins on human erythrocyte membranes and to determine the relation of these different glycoprotein receptors to the intramembranous particles. A. bisporus lectin, which could be visualized directly on the surface of erythrocyte membranes, and ferritin conjugates of wheat germ agglutinin showed a distribution that correlates exactly with the intramembranous particles at all lectin concentrations tested. The binding sites for both of these lectins are located on the major sialoglycoprotein of the membrane. The R. communis agglutinin-ferritin conjugate which binds to receptors on membrane glycoproteins that are distinct from the major sialoglycoprotein showed a close correlation with the intramembranous particles at low lectin concentrations and a poor correlation at high lectin concentrations. High concentrations resulted in virtually complete coating of the surface of trypsinized ghosts which displayed marked aggregation of the intramembranous particles. We conclude that the intramembranous particles of erythrocyte membranes contain at least two glycoproteins and that some membrane lectin receptors are not associated with the intramembranous particles.