Lectinhistochemical demonstration of galactose- and N-acetyl-D-galactosamine residues in cells of the rat anterior pituitary

Lectins are a useful tool for identification of differently glycosylated hypophyseal hormones, prohormones and glycoconjugates without hormone function. Beta-D-galactose and beta-N-acetyl-D-galactosamine (GalNAc) containing glycoconjugates were identified by light microscopy with biotinylated lectins in immunocytochemically localized cells of the anterior pituitary of the rat. Galactose, histochemically detectable by the peanut lectin (PNA), was found at penultimate position of the carbohydrate chain after removal of sialic acid. Galactose containing cells correspond to gonadotrophs and thyrotrophs located mainly in medioanterior regions of the pituitary. The lectins from the soybean (SBA) and horse gram (DBA) both specific for GalNAc residues, are bound to round and also polygonal cells corresponding again to gonadotrophs and thyrotrophs.     

Developmental changes in the structural organization of the lectin discoidin I detected by limited proteolysis

Digestion of discoidin I with several proteolytic enzymes reveals the existence of structural domains in this lectin. Significative differences have been detected in the pattern of fragments generated by V8 protease on discoidin I of various developmental situations. The changes observed can be related to the presence of various types of tetrameric structures in discoidin I. Together with the presence of different types of isoforms in vegetative vs. differentiated cells, the results presented here suggest the involvement of different structural organizations in discoidin I which can be related to the biological functions of this lectin.     

Lectin binding patterns to terminal sugars of rat lung alveolar epithelial cells.

We used post-embedding cytochemical techniques to investigate the lectin binding profiles of rat lung alveolar epithelial cells. Sections from rat lung embedded in the hydrophilic resin Lowicryl K4M were incubated either directly with a lectin-gold complex or with an unlabeled lectin followed by a specific glycoprotein-gold complex. The binding patterns of the five lectins used could be divided into three categories according to their reactivity with alveolar epithelial cells: (a) the Limax flavus lectin and Ricinus communis I lectin bound to both type I and type II cell plasma membranes; (b) the Helix pomatia lectin and Sambucus nigra L. lectin bound to type II but not type I cells; and (c) the Erythrina cristagalli lectin reacted with type I cells but was unreactive with type II cells. The specificity of staining was assessed by control experiments, including pre-absorption of the lectins with various oligosaccharides and enzymatic pre-treatment of sections with highly purified glycosidases to remove specific sugar residues. The results demonstrate that these lectins can be used to distinguish between type I and type II cells and would therefore be useful probes for investigating cell dynamics during lung development and remodeling.     

Generation of recombinant fragments of CD11b expressing the functional beta-glucan-binding lectin site of CR3 (CD11b/CD18).

CR3 (Mac-1; alphaMbeta2 integrin) functions as both a receptor for the opsonic iC3b fragment of C3 triggering phagocytosis or cytotoxicity and an adhesion molecule mediating leukocyte diapedesis. Recent reports have suggested that a CR3 lectin site may be required for both cytotoxic responses and adhesion. Cytotoxic responses require dual recognition of iC3b via the I domain of CD11b and specific microbial surface polysaccharides (e.g., beta-glucan) via a separate lectin site. Likewise, adhesion requires a lectin-dependent membrane complex between CR3 and CD87. To characterize the lectin site further, a recombinant baculovirus (rBv) system was developed that allowed high level expression of rCD11b on membranes and in the cytoplasm of Sf21 insect cells. Six rBv were generated that contained truncated cDNA encoding various CD11b domains. Immunoblotting of rBv-infected Sf21 cells showed that some native epitopes were expressed by five of six rCD11b fragments. Lectin activity of rCD11b proteins was evaluated by both flow cytometry with beta-glucan-FITC and radioactive binding assays with [125I]beta-glucan. Sf21 cells expressing rCD11b that included the C-terminal region, with or without the I-domain, exhibited lectin activity that was inhibited by unlabeled beta-glucan or anti-CR3 mAbs. The smallest rCD11b fragment exhibiting lectin activity included the C-terminus and part of the divalent cation binding region. The beta-glucan binding affinities of the three C-terminal region-containing rCD11bs expressed on Sf21 cell membranes were not significantly different from each other and were similar to that of neutrophil CR3. These data suggest that the lectin site may be located entirely within CD11b, although lectin site-dependent signaling through CD18 probably occurs with the heterodimer.     

Lectinhistochemical demonstration of galactose- and N-acetyl-d-galactosamine residues in cells of the rat anterior pituitary

Summary Lectins are a useful tool for identification of differently glycosylated hypophyseal hormones, prohormones and glycoconjugates without hormone function. -d-galactose and -N-acetyl-d-galactosamine (GalNAc) containing glycoconjugates were identified by light microscopy with biotinylated lectins in immunocytochemically localized cells of the anterior pituitary of the rat. Galactose, histochemically detectable by the peanut lectin (PNA), was found at penultimate position of the carbohydrate chain after removal of sialic acid. Galactose containing cells correspond to gonadotrophs and thyrotrophs located mainly in medioanterior regions of the pituitary. The lectins from the soybean (SBA) and horse gram (DBA) both specific for GalNAc residues, are bound to round and also polygonal cells corresponding again to gonadotrophs and thyrotrophs.     

The development of the conduction system in the mouse embryo heart: III. The development of sinus muscle and sinoatrial node

The origin and development of the sinus musculature, and the sinoatrial node (SAN), were studied in mouse embryo heart from the 8th day postcoitum (dpc) to the neonate. In the medial wall of the right common cardinal vein (RCCV), the muscle cells clearly derive from the splanchnic epithelium, whereas in the dorsolateral wall of the sinus horns, the loose mesenchymal cells appear to transform into the early sinus muscle. The early sinus muscle is particularly voluminous around the right venous valve (RVV). The 9-dpc heart shows regular contractions, but a morphologically definable SAN is not seen until 11 dpc, located in the medioanterior wall of the RCCV. There is indication that the loose mesenchymal cells play a role in the development of the nodal fibers. The SAN and the atrioventricular conduction system (AVCS) develop simultaneously in the 11-to 12-dpc mouse embryo heart. In the medioanterior wall of the left common cardinal vein (LCCV), a transient node-like structure was found. This, however, integrates into the left atrial wall in the 13-dpc and older embryos. Growth and early differentiation of the sinus muscle proceed distally during embryonic life to the point where it is indistinguishable from the atrial musculature.     

Lectin activity and distribution of chicken lactose lectin I in the extracellular matrix of the chick developing kidney

A lectin activity inhibitable by thiodigalactose, N-acetyllactosamine, lactulose, lactose and by an antibody raised against CLL I (chicken-lactose lectin I) has been investigated in the chick embryo developing kidney. At post-induction stages this activity was found in both mesonephros and metanephros. In immunofluorescence and immunoelectron microscopy, the extracellular distribution of CLL I was similar in the mesonephros and the metanephros. The lectin was never found intracellularly; cultured kidney cells did not express any endogenous lectin but were rich in lectin-receptor sites, which led to the hyphothesis that CLL I is not produced in situ but could be adsorbed on renal cells. Potential physiological roles for embryonic lectins are discussed.     

The macrophage alphaMbeta2 integrin alphaM lectin domain mediates the phagocytosis of chilled platelets

alpha(M)beta(2) integrin receptors on myeloid cells mediate the adhesion or uptake of diverse ligands. Ligand binding occurs in the alpha(M) chain, which is composed of an I domain and a lectin domain. The alpha(M) I domain binds iC3b, fibrinogen, intercellular adhesion molecule-1, and other ligands and mediates the adhesion of neutrophils to platelet glycoprotein Ibalpha (GPIbalpha). alpha(M)beta(2) also recognizes beta-GlcNAc residues on GPIbalpha that are clustered on platelets after cooling. The phagocytosis of chilled platelets could be reconstituted when Chinese hamster ovary cells were transfected with alpha(M)beta(2). Replacement of the I domain or the lectin domain of the alpha(M) chain with the corresponding domain from the alpha(X) chain (p150) revealed that the activity of the alpha(M)beta(2) integrin toward chilled platelets resides within the lectin domain and does not require the I domain. Additional evidences for this conclusion are: 1) Sf9 cells expressing solely the alpha(M) lectin domain bound chilled platelets, and 2) soluble recombinant alpha(M) lectin domain inhibited the phagocytosis of chilled platelets by alpha(M)beta(2)-expressing THP-1 cells, whereas I domain substrates showed no inhibitory effect. Therefore chilled platelets are removed from blood by an interaction between beta-GlcNAc residues on clustered GPIbalpha and the lectin domain of alpha(M) chain of the alpha(M)beta(2) integrin, distinguishing this interaction from those mediated by the alpha(M) I domain.     

Localization of soluble endogenous lectins and their ligands at specific extracellular sites

Soluble lectins of chicken, rat, frog, and the cellular slime mold, Dictyostelium discoideum, were purified and specific antibodies raised against these proteins were used to immunohistochemically localize the lectins in and around the tissues in which they were synthesized. Within cells, some of these soluble lectins (chicken-lactose-lectin-II in intestinal goblet cells, discoidin II in prespore cells) appear to be concentrated within vesicles whereas others (e.g., rat beta-galactoside lectin in pulmonary alveolar and smooth muscle cells) appear to be free in the cytoplasm. All of these lectins are eventually secreted to extracellular sites in developing or adult tissues. The sites include mucin (chicken-lactose-lectin-II in intestine); developing extracellular matrix (chicken-lactose-lectin-I in muscle; Xenopus laevis lectin in blastula stage embryos); slime (discoidin I); developing spore coat (discoidin II); and a specialized extracellular matrix, elastic fibers (rat beta-galactoside lectin in lung). In cases where this has been studied in detail (discoidin I, discoidin II, and chicken-lactose-lectin-II), the lectin is associated with a complementary extracellular ligand, at least transiently. Lectin-ligand interactions presumably confer specialized properties in these particular extracellular domains.     

Aggregation of sponge cells. Function of a lectin in its homologous biological system.

For the first time, the biological role of a lectin in the process of reaggregation of single cells from the same species (marine sponge: Geodia cydonium Jam.) is described. The galactose-specific lectin does not promote aggregation, but prevents the antiaggregation receptor from disaggregating cell clumps. Competition experiments showed that the lectin inactivates the antiaggregation receptor by binding to it, most likely via its terminal galactose residues. The lectin converts reversibly aggregation-deficient cells (carrying functional cell membrane-bound antiaggregation receptor molecules) to aggregation-susceptible cells.     

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 sperm-oocyte interaction.     

Isolation and characterization of a lectin from the snail Biomphalaria glabrata and a study of its combining site

The hemagglutinins from the spawn of the water snail Biomphalaria glabrata were isolated by affinity chromatography on hog gastric mucin coupled to Sepharose 4B. The N-acetyl-D-glucosamine eluate (0.1 M) was fractionated further on Bio-Gel P-300, yielding two fractions. Fraction 1 had an Mr of 350 000 and displayed one band in immunoelectrophoresis, but was heterogeneous in discontinuous electrophoresis. It agglutinated human red blood cells with A1 and B specificity at concentrations of 12 and 72 micrograms nitrogen/ml, respectively. Fraction 2 had an Mr on gel filtration of 67 000 and was homogeneous in immuno- and polyacrylamide electrophoresis, and in isoelectrofocusing. It is composed of three subunits with Mr of 17 000 and one smaller subunit of 15 000. This fraction (lectin I) is a glycoprotein containing 6% hexoses and 2.5% hexosamines. For minimal agglutination of human A1 and B red blood cells 2.4 and 72.0 micrograms nitrogen/ml, respectively, of lectin I were required. O red blood cells were not agglutinated. Lectin I precipitated well with a human blood group substance of A1 specificity, moderately with a B- and poorly with an H-substance. Precipitin-inhibition studies revealed that among other sugars N-acetylneuraminic acid was the most potent inhibitor. Immunofluorescence studies confirmed the good interaction of lectin I with receptors of A1 and B erythrocytes and the failure of lectin I to attach to O-erythrocytes. Since N-acetylneuraminic acid is present on the cell surface of all human erythrocytes, it cannot be the dominant part of the receptor for the B. glabrata lectin I, despite its effectiveness as an inhibitor.     

三叶半夏和掌叶半夏凝集素原核表达及特性研究

通过原核表达获得大量具有生物活性的三叶半夏和掌叶半夏凝集素,比较分析两种半夏凝集素的异同,并深入探讨半夏凝集素和亚基之间凝集活性的差异。结果表明,掌叶半夏凝集素的凝集活力为三叶半夏凝集素的4倍,凝集素第三个活性位点两个氨基酸的差异可能是引起三叶半夏和掌叶半夏凝集素凝集活性不同甚至药理作用不同的主要原因。原核表达系统获得的凝集素亚基不能凝集兔血红细胞。该研究为深入探讨两种半夏凝集素的区别,及半夏凝集素和亚基之间凝集活性的差异打下了基础,也为解决半夏资源紧缺提供了一个可能的方法。     

Fluorescein-Conjugated Bandeiraea simplicifolia Lectin as a Marker of Endodermal, Yolk Sac, and Trophoblastic Differentiation in the Mouse Embryo

Abstract. The Bandeiraea simplicifolia lectin I (BSA-I) conjugated to fluorescein isothiocyanate was used as a histochemical reagent to study the mouse embryos from fertilization to early somitogenesis. No lectin binding could be detected on the embryonic cells in the preimplantation embryo. Lectin labeled intensely the zona pellucida. In the implanting embryos lectin binding was detected along the subtrophectodermal and Reichert's membrane, in the cytoplasm of the parietal and visceral endoderm, and the trophoblastic giant cells, but not in the ectodermal cells. Studies on explanted blastocyts cultured in vitro disclosed that the cytoplasmic BSA-I binding sites in trophoblastic cells develop gradually. In the 9-day somitic embryo BSA-I reacted with epithelial cells of the yolk sac, but not with the mesenchymal cells. A continuity between the lectin-reactive endoderm and the foregut epithelium could be demonstrated. These data indicated that BSA-I lectin can be used as a histochemical probe for endodermal (yolk sac) and trophoblastic differentiation in the peri-implantational mouse embryo.     

Kluyveromyces bulgaricus yeast lectins. Isolation of two galactose-specific lectin forms from the yeast cell wall

Incubation of galactose treated Kluyveromyces bulgaricus yeast cells in EDTA/phosphate-buffered saline led to an extract possessing hemagglutinating and yeast flocculating properties. Purification of this extract by affinity chromatography and gel filtration gave two lectin forms, Kb-CWL I and Kb-CWL II, with an apparent molecular mass of 38,000 and 150,000 Da, respectively. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed that Kb-CWL I and Kb-CWL II were dimeric and octameric of a subunit of 18,900 Da. At high concentration, purified Kb-CWL I associated to give Kb-CWL II. This association seemed to be independent on pH. The two lectin forms were glycoproteins, the peptide counterpart was very rich in Lys, Glu, and Gly, and the carbohydrate part represented 1% of the whole molecule and was composed of Glc, Man, and Ara. The two lectin forms (KB-CWL I and Kb-CWL II) agglutinated human red blood cells and flocculated EDTA-treated K. bulgaricus yeast cells. The activity of both lectin forms required Ca2+ ions, while Sr2+ showed some competitive inhibition. Optimal activity was obtained within a pH range of 4-6.5 for both forms. Temperatures of 80-90 degrees C for 20 min, or proteolytic treatment reduced irreversibly the activity of Kb-CWL I and Kb-CWL II. The role of the cell wall phosphopeptidomannan as a ligand and a potential physiological receptor of these lectin forms was demonstrated.     

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.     

Production and characterization of a monoclonal antibody against the seed lectin of the Dolichos biflorus plant

Spleen cells from mice immunized with the Dolichos biflorus seed lectin were fused with cells from the mouse myeloma Sp2/O-Ag14 cell line to form hybridomas. Those hybridomas producing antibodies against the seed lectin were cloned at least four times and the monoclonal antibodies from clone C11/64-56.28 were characterized and found to be specific for Subunit I of the lectin; they do not react with the structurally similar Subunit II. In previous studies, we have shown that although these two subunits appear to differ only at their COOH-terminal ends, only Subunit I has carbohydrate binding activity. Using a solid phase enzyme immunoassay, the antigenic determinant fr the monoclonal antibody was found to be located on the COOH-terminal cyanogen bromide fragment of this subunit. The monoclonal antibody inhibits the ability of the lectin to agglutinate erythrocytes and N-acetyl-D-galactosamine, the specific hapten for the lectin, inhibits the ability of the antibody to combine with the lectin. These results suggest that the monoclonal antibody recognizes a determinant that is located either at or near the active site of the lectin or that is conformationally interdependent with the active site.     

Glycoconjugate cytochemistry of the rat fundic gland using lectin/colloidal-gold conjugates and Lowicryl K4M. Helix pomatia lectin is a specific marker for mucous neck cells in fundic glands of the rat gastric mucosa

The fundic gland of the rat stomach was studied using the low-temperature embedding resin Lowicryl K4M and postembedding staining with lectin/colloidal-gold (CG) conjugates. Intense labeling with Ricinus communis agglutinin I was observed not only in mucous-producing cells but also in parietal cells. In contrast, Helix pomatia agglutinin (HPA) only labeled mucous neck cells and intermediate cells between mucous neck cells and chief cells. The other epithelial cells present in the rat fundic gland showed virtually no reaction with this lectin. Our results indicate that HPA might be a marker lectin of mucous neck cells and their derivatives. The combination of embedding in the hydrophilic resin Lowicryl K4M and postembedding staining with lectin-CG conjugates provided satisfactory staining results, and made it possible to visualize the precise distribution of terminal glycoconjugates in intracellular components as well as on the plasma membrane.     

Patterns of expression of a 15K beta-D-galactoside-specific lectin during early development of the avian embryo

We have determined, by immunohistochemical and biochemical techniques, the distribution of an endogenous beta-D-galactoside-binding lectin between the early primitive streak stage and the 5th day of embryonic development of the chick.The lectin, which was purified from the pectoral muscle of 16-day-old chick embryos, migrates on SDS-PAGE as a single polypeptide of relative molecular mass 15 x 10(3). Antibodies to this pure lectin interact with the 15K (K = 10(3) M(r)) polypeptide as well as with a 6.5K polypeptide; this second component appears to be antigenically related to the 15K lectin, as antibodies affinity purified on the 15K band recognize both polypeptides. In early stages of development, lectin immunoreactivity was present in most cells of the epiblast and hypoblast in the region of the primitive streak, while towards the edge of the area pellucida the epiblast was stained less intensely. During gastrulation, strong immunoreactivity was present also in migrating cells and in the mesoblast, while at the margin of the area pellucida the epiblast was negative. Up to the 10-somite stage, lectin immunoreactivity was present in the somites, neural tube and presumptive cardiac region; the non-neural ectoderm and the extracellular matrix were not labeled; the predominant immunoreactive component at this stage of development was the 6.5K polypeptide. Later in development, the lectin immunoreactivity gradually disappeared from the dermamyotome and nervous system to reappear conspicuously as soon as a differentiated myotome could be detected. Immunoreactivity was very high in the myotome, skeletal and cardiac muscles and transient in smooth muscles. The only region of the nervous system that continued to express the lectin throughout development was the trigeminal (semilunar) ganglion; in all regions of the nervous system, the lectin immunoreactivity disappeared early in development to be re-expressed only much later. The lining epithelium of the digestive tract and other endodermal derivatives expressed the lectin transiently. In the extraembryonic membranes, immunoreactivity to the lectin was observed in the yolk sac and in both layers of the amnion. The striking regulation of the expression of this endogenous lectin suggests that its functions are linked to cell proliferation and/or to the selective expression of a developmentally-timed cell phenotype.