Histochemical study of glycoconjugates in the epididymis of the hamster (Mesocricetus auratus)

Summary The glycoconjugates of hamster epididymis were investigated with conventional and lectin histochemistry. A zone of the caput epididymis, with particular histochemical characteristics, has been differentiated. β-Elimination in combination with lectins was used to establish the presence and distribution of N- and O-linked glycoconjugates. The epithelium, spermatozoa and the intertubular matrix were rich in glycoconjugates. The Golgi apparatus and stereocilia of the principal cells were intensely positive with HPA, PNA and SBA lectins. β-limination indicated that these cells contained abundant O-linked glycoconjugates. Apical and clear cells presented a common lectin affinity; their reactivities towards WGA and UEA-I were very positive. These cells probably contain abundant N-glycoconjugates. The spermatozoa were stained by periodic acid-Schiff (PAS) and by all the lectins (especially in the acrosome), except by those with an affinity for α-l-fucosyl residues; the most intense reaction was found with HPA, WGA, PNA and SBA. Changes in the sperm lectin binding along the ductus were observed: sperm flagellum abruptly acquired WGA and PNA labelling from the posterior caput, and HPA reactivity was negative only in the zone between the caput and the corpus.     

Sialoconjugates and development of the tail bud

Using lectin histochemistry, we have previously shown that there are alterations in the distribution of glycoconjugates in the tail bud of chick embryos that parallel the developmental sequence of the caudal axis. If glycoconjugates or the cells bearing them play a role in caudal axial development, then, restriction of their availability by binding with lectins would be expected to produce abnormalities of caudal development. In the present study, we treated embryos at various stages of tail bud development by microinjection with a variety of lectins. Administration of WGA by sub-blastodermal injection resulted in high incidences of secondary neural tube and notochordal abnormalities in lectin-treated embryos. The incidence of malformations was dependent upon both the dose of WGA received and the stage of development at the time of treatment. Using an anti-WGA antibody, we have also shown binding of the lectin in regions where defects were found. The lectin WGA binds to the sialic acid residues of glycoconjugates and to N-acetylglucosamine. Treatment of embryos with Limulus polyphemus lectin (LPL), which also binds to sialic acid, produced results similar to those of WGA. Treatments using lectins with other sugar-binding specificities, including succinylated WGA (with N-acetylglucosamine specificity only) produced defects that differed from those produced by WGA and LPL, and only with the administration of much higher doses. The results suggest that glycoconjugates in general and sialoconjugates in particular, or the cells carrying them, may have a role in caudal axial development.     

Distribution of lectin binding sites in Xenopus laevis egg jelly.

Eggs from the anuran Xenopus laevis are surrounded by a thick jelly coat that is required during fertilization. The jelly coat contains three morphologically distinct layers, designated J1, J2, and J3. We examined the lectin binding properties of the individual jelly coat layers as a step in identifying jelly glycoproteins that may be essential in fertilization. The reactivity of 31 lectins with isolated jelly coat layers was examined with enzyme-linked lectin-assays (ELLAs). Using ELLA we found that most of the lectins tested showed some reactivity to all three jelly layers; however, two lectins showed jelly layer selectivity. The lectin Maackia amurensis (MAA) reacted only with J1 and J2, while the lectin Trichosanthes kirilowii (TKA) reacted only with J2 and J3. Some lectins were localized in the jelly coat using confocal microscopy, which revealed substantial heterogeneity in lectin binding site distribution among and within jelly coat layers. Wheat germ agglutinin (WGA) bound only to the outermost region of J3 and produced a thin, but very intense, band of fluorescence at the J1/J2 interface while the remainder of J2 stained lightly. The lectin MAA produced an intense fluorescence-staining pattern only at the J1/J2 interface. Several lectins were also tested for the ability to inhibit fertilization. WGA, MAA, and concanavalin A significantly inhibited fertilization and WGA was found to block fertilization by preventing sperm from penetrating the jelly. Using Western blotting, we identified high-molecular-weight components in J1 and J2 that may be important in fertilization.     

Distribution of Lectin Binding Sites in Xenopus laevis Egg Jelly

Eggs from the anuran Xenopus laevis are surrounded by a thick jelly coat that is required during fertilization. The jelly coat contains three morphologically distinct layers, designated J1, J2, and J3. We examined the lectin binding properties of the individual jelly coat layers as a step in identifying jelly glycoproteins that may be essential in fertilization. The reactivity of 31 lectins with isolated jelly coat layers was examined with enzyme-linked lectin-assays (ELLAs). Using ELLA we found that most of the lectins tested showed some reactivity to all three jelly layers; however, two lectins showed jelly layer selectivity. The lectin Maackia amurensis (MAA) reacted only with J1 and J2, while the lectin Trichosanthes kirilowii (TKA) reacted only with J2 and J3. Some lectins were localized in the jelly coat using confocal microscopy, which revealed substantial heterogeneity in lectin binding site distribution among and within jelly coat layers. Wheat germ agglutinin (WGA) bound only to the outermost region of J3 and produced a thin, but very intense, band of fluorescence at the J1/J2 interface while the remainder of J2 stained lightly. The lectin MAA produced an intense fluorescence-staining pattern only at the J1/J2 interface. Several lectins were also tested for the ability to inhibit fertilization. WGA, MAA, and concanavalin A significantly inhibited fertilization and WGA was found to block fertilization by preventing sperm from penetrating the jelly. Using Western blotting, we identified high-molecular-weight components in J1 and J2 that may be important in fertilization.     

Effects of retinoic acid on the distribution of glycoconjugates during mouse tail bud development

Retinoic acid (RA), a potent teratogen of caudal axial development in rodents, has been shown to alter glycoconjugates in a variety of embryonic tissues and teratocarcinomas. In this study, we examined its effects on the expression of cell surface and extracellular matrix glycoconjugates during tail bud development in mouse embryos by using lectin histochemistry. The lectins WGA, sWGA, and PNA showed striking differences in binding between RA-exposed and control embryos. Computer-assisted densitometry revealed a significant increase in binding of all three lectins to the extracellular material of the luminal and abluminal borders of the secondary neural tube and surrounding the notochord in RA-exposed embryos. RA-treated embryos also showed an increased binding affinity for the lectins sWGA and PNA to the cells of the notochord, while WGA showed increased binding to the neuroepithelial cells of the secondary neural tube. The results suggest that RA affects the expression of lectin binding sites during the early development of RA-induced caudal axial defects.     

A comparison of lectin binding in rat and human peripheral nerve

Eleven different fluorescein- or peroxidase-conjugated lectins with different sugar-binding affinities were employed to analyze and compare glycoconjugates of rat and human peripheral nerves at the light microscopic level. A majority of lectins showed a distinct binding pattern in different structures of the nerve. Lectin binding was similar but not identical in rat and human nerves. Limulus polyhemus agglutinin did not stain any structures in rat or human nerves. In both species, all other lectins bound to the perineurium. Perineurial staining was intense with Canavalia ensiformis (Con A), Triticum vulgaris (WGA), Maclura pomifera (MPA); moderate with Glycine max (SBA), Griffonia simplicifolia-I (GS-I) and GS-II; weak with Ulex europaeus (UEA), Dolichos biflorus (DBA), and Ricinus communis (RCA). In the endoneurium of both species, ConA staining was intense, MPA and WGA moderate, SBA, GS-II, PNA, and RCA weak, and UEA and DBA absent. Interestingly, GS-I stained rat but not human endoneurium. Most lectins bound to blood vessels. GS-I bound to rat but not human, whereas UEA bound to human but not rat vessels. The results show that lectins can be used to reveal heterogeneity in sugar residues of glycoconjugates within neural and vascular components of nerves. They may therefore be potentially useful in detecting changes in glycoconjugates during nerve degeneration and subsequent regeneration after trauma or in pathological states.     

Glycoconjugate profiles of the lancelet (Branchiostoma lanceolatum) ovary: a lectin histochemical study by laser confocal microscopy

The presence and the distribution of carbohydrate moieties in ripe lancelet (Branchiostoma lanceolatum) oocytes (mean diameter 130 microm) was studied by lectin histochemistry in combination with enzyme and chemical treatments. Binding sites for eight lectins with specificities towards different glycan moieties were studied on sections of the whole body of mature female lancelets. Only three of the lectins tested reacted positively. Concanavalin-A (ConA)-binding glycoconjugates were localized in the cytoplasm, namely in yolk granules, whereas Artocarpus integrifolia (AIA) and Ricinus communis (RCA) agglutinins bound strongly to extracellular coats of the oocyte identified as the jelly coat and vitelline layer. No other tissues of the lancelet body were found to be positive to any lectin tested, except gut enterocytes which reacted strongly with AIA. Reactivity to ConA was abolished by pretreatment of sections with N-glycosidase F but not by mild alkaline hydrolysis, confirming that the glycoconjugates were of the N-linked type. On the contrary, chemical removal of O-linked chains by mild alkaline hydrolysis abolished AIA and RCA reactivity but had no effect on ConA positivity.     

Glomerular sialoconjugates of developing and mature rat kidneys

The appearance of sialoconjugates in developing rat kidney glomeruli was studied using lectins and neuraminidase-lectin staining sequences. In the early S-shaped bodies, binding of Maclura pomifera (MPA; specific for galactosaminyl residues of glycoconjugates) could be detected in the presumptive podocyte layer at the apex of these cells, but notably no binding of lectins specific for sialic acid could be seen. During further morphologic maturation of the S-shaped bodies, binding of Limax flavus (LFA; specific for sialic acids) and Triticum vulgaris (WGA; specific for sialic acids and N-acetyl glucosaminyl moieties) appeared at the apex of podocytes and extended subsequently along the lateral membranes to the base of these cells. In morphologically mature glomeruli, LFA stained not only the base of podocytes but also glomerular basement membranes. WGA and MPA bound to the capillary endothelia as well as to the structures bound by LFA. The intensity of WGA binding increased considerably after 5 days of postnatal life, seemingly in parallel with the decrease and ultimate disappearance of MPA binding. In addition to showing individual appearance pattern for various lectin binding sites, these studies give evidence of previously unrecognized postnatal completion of the components of glomerular filtration barrier.     

Fluorophore-conjugated lectin labeling of the cell surface of isolated male and female gametes,central cells and synergids before and after fertilization in maize

Three fluorescein isothiocyanate (FITC)-conjugated lectins, Canavalia ensiformis agglutinin (Con A), Triticum vulgaris agglutinin (WGA) and Phaseolus vulgaris erythroagglutinin (PHA-E), were used as probes to localize sugar moieties of glycoconjugates on the cell surface of isolated maize sperm, egg, central, antipodal cells, synergids, and in vitro- and in vivo-fertilized zygotes. Fluorescence signals on the surface of the cells were due to specific binding. Calcium was necessary for WGA and PHA-E binding and enhanced Con A labeling. Differences in glycoconjugate composition of the membranes of gametes and other embryo sac component cells were found. FITC-Con A strongly labeled egg and central cells, but labeled sperm only weakly. FITC-WGA binding sites were detected on egg, but not sperm cells. Con A and WGA binding sites were equally distributed around egg and central cell protoplasts. FITC-PHA-E binding sites were not found on sperm and egg cells before fertilization. Binding sites of these lectins were located on synergids, especially on their filiform apparatus. Interestingly, WGA binding to egg cells was enhanced after fertilization, whereas PHA-E binding to egg cell membranes could only be detected after fertilization. These results suggest the occurrence of fertilization-induced changes in glycoconjugate composition of the maize egg cell membrane. An increase in the number of WGA and PHA-E binding sites was also observed on newly formed cell walls of cultured two-celled embryos derived from in vitro-produced zygotes.     

Surface carbohydrate changes on Onchocerca lienalis larvae as they develop from microfilariae to the infective third-stage in Simulium ornatum

Use was made of seven FITC labelled lectins as tools to investigate the surface of Onchocerca lienalis larvae as they develop through to the infective third-stage in a natural vector, Simulium ornatum. The lectins were derived from Canavalia ensiformis (Con A), Lens culinaris (lentil), Triticum vulgaris (wheat germ), Arachis hypogaea (peanut), Helix pomatia, Phaseolus vulgaris (kidney bean) and Tetragonolobus purpureus (asparagus pea). Between 70 and 100 living parasites were examined for each developmental stage; i.e. skin microfilariae, late first-stages, second-stages, preinfective third-stages and infective third-stages isolated from the mouth parts of the flies. None of the lectins used bound to the surface of the microfilariae. However, progressive binding to the cuticle of the first- and second-stages was observed using Con. A, lentil lectin and wheat germ agglutinin (WGA). Following moulting to the third-stage, binding of these three lectins declined. Furthermore, as these lectins decreased, peanut and Helix pomatia lectins progressively increased in their binding, despite the fact that they showed little or no binding to the first- and second-stages; stages at which Con A, lentil and WGA were at their maximum. Asparagus pea and kidney bean lectins failed completely to bind to any of the larvae examined. Carbohydrate inhibition tests showed that the lectin was indeed binding specifically to glycoconjugates on the parasite surface. WGA binding was not inhibited by prior incubation with N-acetyl-D-glucosamine, even at high concentrations, but neuraminic acid did completely inhibit its binding. Judging from the patterns of binding on the nematodes themselves, the carbohydrates may not be vector in origin, but derive from the worms. The lectin specificities indicate that initially mannose/glucose type derivatives are present on the surface. Following moulting to the third-stage these are progressively replaced, or overlaid with galactosamine type derivatives, also present on the infective third-stage as it enters the bovine host. The availability of these surface glycoconjugates to attack mediated by natural insect lectins may be of importance in the parasite regulatory mechanisms of the blackfly. Variability in these surface carbohydrates, and in the response to them could well be a contributing factor in the cytospecific variation in S. damnosum susceptibility to geographical variants of O. volvulus.     

Polarized distribution of binding sites for concanavalin A and wheat-germ agglutinin in the zona pellucida of goodeid oocytes (teleostei)

Zonae pellucidae of the viviparous goodeid teleosts Girardinichthys viviparus, Xenoophorus captivus, and Xenotoca eiseni were investigated ultrastructurally, and binding sites for ConA and WGA were localized on cross-sections using a colloidal gold technique. In late stages of development, the oocytes are surrounded by a three-zonated acellular matrix multiply perforated by pore canals allowing long microvilli of the oocyte to penetrate interstices of the follicle epithelium. Together, the surface of the microvilli and zona pellucida is coated by a thin layer of homogeneous slightly electron-dense material. In early oogenesis, the thin acellular layer is entirely packed with binding sites for WGA, whereas those for ConA occur only sparsely. Three-zonated zonae pellucidae amply contain both WGA and ConA receptors. The asymmetric labelling pattern obtained with both lectin protein gold preparations indicates a polarized organization of the different glycoconjugates. WGA receptors are concentrated within the outer region of the zona pellucida. Labelling with ConA-HRP-Au complexes produced heavy deposits of marker beads within the inner two thirds of the zona pellucida and weak labelling of the superficial coat. After prolonged digestion with neuraminidase, WGA binding sites were no longer detectable.     

Glycoconjugate pattern of membranes in the acinar cell of the rat pancreas

Lectin-binding studies were performed at the ultrastructural level to characterize glycoconjugate patterns on membrane systems in pancreatic acinar cells of the rat. Five lectins reacting with different sugar moieties were applied to ultrathin frozen sections: concanavalin A (ConA): glucose, mannose; wheat-germ agglutinin (WGA): N-acetylglucosamine, sialic acid; Ricinus communis agglutinin I (RCA I): galactose; Ulex europaeus agglutinin I (UEA I): L-fucose; soybean agglutinin (SBA): N-acetylgalactosamine). Binding sites of lectins were visualized either by direct conjugation to colloidal gold or by the use of a three-step procedure involving additional immune reactions. The rough endoplasmic reticulum and the nuclear envelope of acinar cells was selectively labelled for ConA. The membranes of the Golgi apparatus bound all lectins applied with an increasing intensity proceeding from the cis- to the trans-Golgi area for SBA, UEA I and WGA. In contrast RCA I selectively labelled the trans-Golgi cisternae. The membranes of condensing vacuoles and zymogen granules were labelled for all lectins used although the density of the label differed between the lectins. In contrast the content of zymogen granules failed to bind SBA and WGA. Lysosomal bodies (membranes and content) revealed binding sites for all lectins used. The plasma membranes were heavily labelled by all lectins except for SBA which showed only a weak binding to the lateral and the apical plasma membrane. These results are in accordance to current biochemical knowledge of the successive steps in the glycosylation of membrane proteins. It could be demonstrated, that the cryo-section technique is suitable for the fine structural localisation of surface glycoconjugates of plasma membranes and internal membranes in pancreatic acinar cells using plant lectins.     

Lectin binding pattern and band 3 localization in toad skin epithelium and the effect of salt acclimation

Seven lectins were employed to localize glycoconjugates in the skin of a toad (Bufo viridis). Each of the lectins exhibited a particular, specific and selective binding pattern. Peanut lectin (PNA) and WGA bound to mitochondria-rich (MR) cells, but WGA bound also abundantly, in the dermis. Band 3-like protein, as indicated by the reaction with polyclonal anti band 3 antibody, was localized exclusively in MR cells. Ionic acclimation (200 mmol/L NaCl, or 50 mmol/L KCl) affected profoundly the binding pattern of the lectins. High NaCl acclimation resulted also in diminishing anti band 3 antibody binding, whereas in skins of KCl-acclimated toads the staining remained similar to the control. The binding of WGA but not PNA, corresponded with the same cells that stained with anti band 3 antibody. PNA in concentration of < 10 μg/mL reduced reversibly, both the resting and activated Cl^? conductance by 25–30%. Based on differential binding of band 3, WGA and PNA, these observations provide conclusive verification of the presence of at least two populations of MR cells in the toad skin epithelium. It is suggested that the PNA positive MR cells may correspond to a β-type MR cell. The information can be used to study molecular mechanisms that are involved in ionic acclimation.     

Glycoconjugates in normal human kidney. A histochemical study using 13 biotinylated lectins

The avidin-biotin-peroxidase complex technique was used with 13 lectins to study the glycoconjugates of normal human renal tissue. The evaluated lectins included Triticum vulgaris (WGA), Concanavalin ensiformis (ConA), Phaseolus vulgaris leukoagglutinin and erythroagglutinin (PHA-L and PHA-E), Lens culinaris (LCA), Pisum sativum (PSA), Dolichos biflorus (DBA), Glycine max (SBA), Arachis hypogaea (PNA), Sophora japonica (SJA), Bandeiraea simplicifolia I (BSL-I), Ulex europaeus I (UEA-I) and Ricinus communis I (RCA-I). Characteristic and reproducible staining patterns were observed. WGA and ConA stained all tubules; PHA-L, PHA-E, LCA, PSA stained predominantly proximal tubules; DBA, SBA, PNA, SJA and BSL-I stained predominantly distal portions of nephrons. In glomeruli, WGA and PHA-L stained predominantly visceral epithelial cells; ConA stained predominantly basement membranes and UEA-I stained exclusively endothelial cells. UEA-I also stained endothelial cells of other blood vessels and medullary collecting ducts. Sialidase treatment before staining caused marked changes of the binding patterns of several lectins including a focal loss of glomerular and tubular staining by WGA; an acquired staining of endothelium by PNA and SBA; and of glomeruli by PNA, SBA, PHA-E, LCA, PSA and RCA-I. The known saccharide specificities and binding patterns of the lectins employed in this study allowed some conclusions about the nature and the distribution of the sugar residues in the oligosaccharide chains of renal glycoconjugates. The technique used in this report may be applicable to other studies such as evaluation of normal renal maturation, classification of renal cysts and pathogenesis of nephrotic syndrome. The observations herein reported may serve as a reference for these studies.     

Polarized distribution of binding sites for concanavalin A and wheat-germ agglutinin in the zona pellucida of goodeid oocytes (teleostei)

Summary Zonae pellucidae of the viviparous goodeid teleosts Girardinichthys viviparus, Xenoophorus captivus, and Xenotoca eiseni were investigated ultrastructurally, and binding sites for ConA and WGA were localized on cross-sections using a colloidal gold technique. In late stages of development, the oocytes are surrounded by a three-zonated acellular matrix multiply perforated by pore canals allowing long microvilli of the oocyte to penetrate interstices of the follicle epithelium. Together, the surface of the microvilli and zona pellucida is coated by a thin layer of homogeneous slightly electron-dense material. In early oogenesis, the thin acellular layer is entirely packed with binding sites for WGA, whereas those for ConA occur only sparsely. Three-zonated zonae pellucidae amply contain both WGA and ConA receptors. The asymmetric labelling pattern obtained with both lectin protein gold preparations indicates a polarized organization of the different glycoconjugates. WGA receptors are concentrated within the outer region of the zona pellucida. Labelling with ConA-HRP-Au complexes produced heavy deposits of marker beads within the inner two thirds of the zona pellucida and weak labelling of the superficial coat. After prolonged digestion with neuraminidase, WGA binding sites were no longer detectable.Supported by the Deutsche Forschungsgemeinschaft (Schi 268/1-1)     

Inhibition of the activation reaction of Xenopus laevis eggs by the lectins WGA and SBA

Ionophore A23187 and electrical activation of dejellied mature eggs of Xenopus laevis are both prevented by the lectins wheat germ agglutinin (WGA) and soya bean agglutinin (SBA). However, this inhibition is not total since one of the events associated with egg activation, the activation potential, still occurs under lectin treatment. After 10 min of incubation in 50 μg/ml WGA or 100 μg/ml SBA, the cortical reaction, cortical contraction, and second polar body emission are totally impaired, whereas the activation potential, although different from the normal one, still proceeds. At the ultrastructural level, the lectin binding sites are localized on the vitelline envelope and on the plasma membrane. The inhibitory effects of these lectins are not detected in jellied eggs. Also, spermatozoa are strongly agglutinated by WGA at concentrations as low as 2.5 μg/ml, but not by SBA. This suggests that inhibition of fertilization in WGA-treated eggs is due to an effect of the lectin on the sperm.     

Effect of thyroid hormones on the histotopography of lectin receptors in the rat salivary gland

Using lectin-peroxidase technique, the influence of hypo- and hyperthyroidism on histotopography of glycoconjugates has been investigated in rat submandibular gland. The following lectins were used: peanut agglutinin (PNA), wheat germ agglutinin (WGA), Laburnum anagyroides lectin (LAL) and concanavalin A (con A). It has been demonstrated that hyperthyroidism is accompanied by the loss of con A, WGA and LAL receptor sites. Hypothyrodism enhanced con A binding to granular duct cells with a parallel reduction in WGA and LAL binding to these or other duct cells. Hypothyroidism as well as hyperthyroidism markedly enhanced PNA binding to duct epitheliocytes with redistribution of these lectin binding sites from the luminal surface of salivary ducts into the cytoplasm of duct cells. Possible interpretations of the observed phenomena are discussed.     

Guinea pig peritoneal macrophages. Differential effects of lectins on interaction with IgG immunoglobulins

Guinea pig peritoneal macrophages have on their surface two receptors, one (Fcγ₁/γ₂R) binding both guinea pig IgG1 and IgG2 and the second (Fcγ₂R) binding only IgG2 immunoglobulins. We have previously shown that treatment of macrophages with neuraminidase or glycosylation inhibitors affects, in a different way, the binding of guinea pig IgG1, IgG2, and rabbit IgG. In the present study we have shown that pretreatment of guinea pig macrophages with lectins (Con A, WGA, and PNA) also has a different effect on the interaction of the cells with IgG. The lectins increased the binding of guinea pig IgG1, whereas rabbit IgG and guinea pig IgG2 were bound with a lower efficiency than in the case of control cells. Since sialic acid residues seem to modulate the activity of receptors and WGA interacts with sialylated oligosaccharides, we determined the IgG-binding characteristics for WGA-pretreated macrophages. We found that the increase in IgG1-binding ability was caused by an increase in the value of K_app, but the number of IgG-binding sites was lower than in the control cells. In the case of rabbit IgG and guinea pig IgG2 we observed a decrease of both the value of K_app and the number of IgG-binding sites. WGA did not interact directly with the Fcγ receptor. The results of our former papers and the different effects of lectins of various specificities described in this paper suggest different positions of Fcγ₁/γ₂ and Fcγ₂R in the plane of the plane of the macrophage membrane in respect to various membrane glycoconjugates. Interaction of IgG with macrophage Fcγ receptors depends in a different way on glycoconjugates on the surface of the macrophage. Our results suggest that changes in glycosylation of macrophage surface glycoconjugates may be used by the cell for regulating the binding activities of the macrophage Fcγ receptors.     

Distribution of glycoconjugates on the plasma membrane and on membranes of the open-canalicular system in human platelets. A cytochemical study

Distribution of carbohydrate moieties in the membrane system of the human blood platelet was studied by electron microscopy employing lectins as a probe. Glutaraldehyde-fixed platelets were treated with biotinylated-lectins (ConA, RCA, WGA, PNA, SBA, DBA and UEA-1) and labeled with horseradish peroxidase-conjugated avidin. Among the lectins used, ConA bound uniformly to the plasma membrane as well as to the membrane of the open-canalicular system (OCS). Other lectins showed more or less reduced binding on the OCS membrane compared with that on the plasma membrane, indicating that there exist regional differences in the distribution pattern of glycoconjugates in the membrane system of the platelet. The relationship of the distribution pattern of the glycoconjugates with the distribution of the major platelet glycoproteins GPIb and GPIIbIIIa is discussed.     

Binding of lectins to "young" and "old" human erythrocytes

"Old" human erythrocytes showed a 21.2% decrease in cell surface area and a 2% decrease in the number of WGA receptor sites, but a 27% increase in the distribution density of the WGA (lectin) receptor site, when compared with "young" human erythrocytes. For a list of lectin abbreviations, see Materials and methods). Both "young" and "old" erythrocytes exhibited very weak binding activity for 125I-labeled PNA, but there was no difference in binding activity for PNA between "young" erythrocytes and "old" ones. Compared with "young" erythrocytes, decreases in the number and distribution density of receptor sites for five lectins including LPA, Con A, RCA-II, SBA and BPA on the cell surface were observed in aged erythrocytes. "Old" erythrocytes also showed a decrease in the number of PHA-E receptor sites, while the distribution density of the same receptor site remained unchanged. In view of these and other observations, it is thought that human erythrocyte aging is accompanied by elimination of some glycoconjugates which have affinity for six lectins, LPA, Con A, RCA-II, PHA-E, SBA and BPA, whereas no WGA receptor-containing glycoconjugates are released from erythrocyte membranes. Elimination of the glycoconjugates results in shrinkage of erythrocytes to reduce their cell surface areas.