Confocal and fluorescence microscopic study using lectins of the distribution of cortical granules during the maturation and fertilization of pig oocytes

A study was carried out to determine whether pig cortical granules (CGs) could be visualized using fluorescein isothiocyanate (FITC)-labelled lec-tins. Following labelling with FITC-labelled peanut agglutinin (FITC-PNA), fluorescent spots were observed that had a distribution during maturation and fertilization entirely consistent with that observed by electron microscopy. For the first 18 h of in vitro maturation, most of the fluorescent spots of FITC-PNA were distributed throughout the cortical cytoplasm. Thereafter, the CGs underwent centrifugal migration to form a monolayer next to the plasma membrane. Following penetration by sperm, fluorescent spots were extruded into the perivitelline space, where they aggregated forming fluorescent clumps, which subsequently formed a reticulate structure surrounding the egg. Fluorescence was gradually lost such that by 18 h after insemination none could be detected in 70% of the eggs. The results indicate that CGs in pig oocytes contain galactosyl-rich glycoconjugates and that FITC-PNA is a useful probe for their rapid visualization and examination. © 1993 Wiley-Liss, Inc.     

Location of the N-acetyl-d-neuraminic acid binding site in wheat germ agglutinin: A crystallographic study at 2.8 Å resolution

The crystal structure of the non-covalent complex between wheat germ agglutinin (isolectin no. 2) and N-acetyl-d-neuraminic acid, a saccharide widely found at the termini of carbohydrate chains in membrane glycoproteins and known to interact with wheat germ agglutinin, has been determined from an electron density difference map at 2.8 Å resolution. This map exhibits two strong binding sites on the wheat germ agglutinin dimer molecule which are located in corresponding crevices at the protomer/protomer interface. Amino acid sidechains from B and C-type domains of opposite protomers contribute to the binding site. The N-acetylneuraminic acid molecule is oriented such that its acetyl group becomes essentially buried upon binding, whereas the charged carboxylate and the glycerol groups point away from the protein surface, but are also able to make contact with surface side-chains. Model building shows that substituents of the pyranoside ring which had been predicted as essential for binding from solution studies, are situated favorably to allow interactions to be made with main and side-chain atoms of the protein molecule.     

Genetic Recombination — Understanding the Mechanism : by H.L.K. Whitehouse Wiley; Chichester,New York, 1982

Interaction of peanut agglutinin with MeUmbβGalβ(1→3)GalNAc was followed with the stopped-flow technique. The mechanism is a simple bimolecular association with k₊ = 7.1 × 10³ M^?1. s^?1 and k_? = 0.24 s^?1 at 25°C. The very slow dissociation rate of the complex strongly supports earlier conclusions that the combining site of peanut agglutinin is complementary to the Galβ(1→3)GalNac structure.     

Lectin-mediated agglutination of murine lymphoma cells. Cell surface deformability and reversibility of agglutination by saccharides

Agglutination of S49 mouse lymphoma cells by Ricinus communis I agglutinin can be reversed by the competing haptenic saccharide, lactose, soon after agglutination, but after further incubation in the absence of lectin the agglutination reaction could not be reversed by lactose and the cells remained as multicell aggregates. The irreversibility of S49 cell agglutination was time, temperature and lectin concentration dependent and its onset correlated with ultrastructurally observed deformation of adjacent cell surfaces and an increase in the proportion of adjacent cell surface areas in close apposition within multicell aggregates. Pretreatment of S49 cells with cytochalasin B or cytochalasin B plus vinblastine enhanced R. communis I agglutinin-mediated agglutination, while vinblastine alone and fluoride plus azide had essentially no effect. When drug-treated cells were agglutinated and then incubated in lectin-free drug-containing media for various times prior to lactose addition, the drug effects were more pronounced. Cytochalasin B alone or with vinblastine inhibited lactose reversal of S49 cell agglutination compared to the drug-free controls, while fluoride plus azide enhanced hapten reversibility. Electron microscopic analysis revealed that the onset of agglutination irreversibility correlated with cell surface deformation in the drug-treated cells. Cell aggregates that were more readily reversible by lactose (fluoride plus azide) were unchanged or less deformed, while S49 aggregates treated with cytochalasin B plus vinblastine were more deformed compared to controls without drugs. These experiments suggest a role for cell surface deformability as an important secondary effect during lectin-mediated cell agglutination of 849 lymphoma cells.     

Protein-sugar interactions: Environmental effect on the fluorescence of O-(4-methylumbelliferyl)-glycosides

We have investigated the effect of 12 solvents and several amino acids on the fluorescence of O-(4-methylumbelliferyl)-glycosides. We showed that: i) the fluorescence quenching is not related to the dielectric constant of the solvents: the fluorescence intensity was maximal in water (d=80) and in acetic acid (d=6.2) and was at least ten times lower in acetone (d=21) and in dioxane (d=2.2); ii) the fluorescence of O-(4-methylumbelliferyl)-N-acetyl-β-glucosaminide is not quenched in the presence of various amino acids including arginine, asparagine, aspartate, histidine, leucine, phenylalanine and proline; iii) the fluorescence of O-(4-methylumbelliferyl)-glycoside is quenched by sulfur, phenol and indole amino acids or derivatives containing sulfur, phenol or indole groups. The changes in fluorescence intensities of O-(4-methylumbelliferyl)-glycosides upon binding to concanavalin A, wheat germ agglutinin and lysozyme are discussed with regard to the amino acid content of their binding sites.     

Tracing the history of Galα1–4Gal on glycoproteins in modern birds

Galα1–4Gal is typically found in mammalian glycolipids in small quantities, and recognized by some pathogens, such as uropathogenic Escherichia coli. In contrast, glycoproteins containing Galα1–4Gal were rarely found in vertebrates except in a few species of birds and amphibians until recently. However, we had previously reported that pigeon (Columba livia) egg white and serum glycoproteins are rich in N-glycans with Galα1–4Gal at non-reducing termini. Our investigation with egg white glycoproteins from 181 avian species also revealed that the distribution of (Galα1–4Gal)-containing glycoproteins was not rare among avians, and is correlated with the phylogeny of birds. The differentiated expression was most likely emerged at earlier stage of diversification of modern birds, but some birds might have lost the facility for the expression relatively recently.     

Inhibition of Pair Formation by Concanavalin A and Concanavalin A-Binding Glycoconjugates in Euplotes octocarinatus

ABSTRACT. Concanavalin A (≥ 50 μg/ml) inhibits pair formation in both of the two complementary mating types of Euplotes octocarinatus studied in this investigation. This effect can be reversed by methyl-α- d -mannose. Concanavalin A is accessible for methyl-α- d -mannose until pairs are formed. Methyl-α- d -mannose as well as methyl-α- d -glucose and 2-acetamido-2-deoxy- d -glucose alone do not inhibit pair formation unless applied in concentrations ≥ 60 mM. The Concanavalin A-sensitive phase of preconjugant interaction starts 2 h after cells are induced to conjugate. Based on these observations we suggest that Concanavalin A might exhibit its action by binding to carbohydrate moieties of preconjugation-specific adhesion molecules and thereby might allosterically block interactions with their counterparts. To identify preconjugation-specific alterations in number or localization of Concanavalin A-binding glycoconjugates, we probed western blots of total cell proteins or fixed cells, respectively, with digoxigenin-labeled Concanavalin A. On Concanavalin A blots 20 different Concanavalin A-binding glycoconjugates were identified in mating-competent cells. Localization of Concanavalin A-binding sites on mating-competent cells by light microscopy resulted in predominant labeling of a comma-shaped structure near the paroral membranelle. During the preconjugation period no changes in number or localization of Con A-binding glycoconjugates were detected. Possible reasons are discussed.     

The secretion of two sperm maturation-related glycoproteins in BALB/c mouse epididymis

Summary A well-developed Golgi apparatus and rough and smooth endoplasmic reticulum in the principal cells of the mouse epididymis indicate active protein synthesis. Studies have shown that epididymal secretions are essential for sperm maturation. In a previous study, two wheat-germ agglutinin (WGA)-binding glycoproteins, GP-49 and GP-83, were identified on the surface of mature mouse sperm. In this study, synthesis and secretion of these two glycoproteins were investigated. Apparent WGA-binding was found on the stereocilia and in the apical region of principal cells in the corpus and cauda of epididymis. Post-fixation and pre-embedding cytochemical localization revealed that WGA-binding sites were situated in the Golgi apparatus, multivesicular bodies and stereocilia of principal cells. GP-49 and GP-83 were identified in the Nonidet P-40 homogenates of corpus and cauda epididymidis. In the epididymides of which ductuli efferentes had been ligated for more than 4 weeks, no sperm were found in the lumina of epididymal tubules. WGA-binding sites were present in the corpus and cauda; GP-49 and GP-83 were identified in tissue homogenates of the corpus and cauda as well. These findings suggest that GP-49 and GP-83 of mature sperm may be secreted by the principal cells of the corpus and cauda. These two molecules apparently conjugate to sperm whilst sperm transit through the epididymis.