Glycobiology. The beginning of a sweet tale

Glycobiology of reproductive processes in marine animals: the state of the art

Glycobiology is the study of complex carbohydrates in biological systems and represents a developing field of science that has made huge advances in the last half century. In fact, it combines all branches of biomedical research, revealing the vast and diverse forms of carbohydrate structures that exist in nature. Advances in structure determination have enabled scientists to study the function of complex carbohydrates in more depth and to determine the role that they play in a wide range of biological processes. Glycobiology research in marine systems has primarily focused on reproduction, in particular for what concern the chemical communication between the gametes. The current status of marine glycobiology is primarily descriptive, devoted to characterizing marine glycoconjugates with potential biomedical and biotechnological applications. In this review, we describe the current status of the glycobiology in the reproductive processes from gametogenesis to fertilization and embryo development of marine animals.

Clinical management of male infertility in assisted reproduction: ICSI and beyond

The advent of in vitro fertilization and its augmentation with intracytoplasmic sperm injection (ICSI) has allowed a large number of couples suffering from moderate to severe male infertility, and also presenting with female pathologies, to achieve their reproductive dreams. Notwithstanding the existence of fundamental questions about the pathophysiological mechanisms leading to sperm dysfunction, and still unanswered concerns about health risks following ICSI, it appears that overall ICSI is safe and here to stay. Although on one hand ICSI possibly hampered advances of the knowledge in some areas of gamete biology and interaction, on the other it definitely gave impulse to studies designed to unveil the sperm contributions during and beyond fertilization, including the normalcy of the DNA/chromatin as well as molecular mechanisms of genetic/epigenetic control and nuclear organization status. In all, almost entering the fourth decade of assisted reproductive technologies, we should continue monitoring the safety of the technique and long-term development of offspring, whereas at the same time prioritizing areas of research addressing these fundamental questions.

Innate immunity and its evasion and suppression by hymenopteran endoparasitoids

Recent studies suggest that insects use pattern recognition molecules to distinguish prokaryotic pathogens and fungi from "self" structures. Less understood is how the innate immune system of insects recognizes endoparasitic Hymenoptera and other eukaryotic invaders as foreign. Here we discuss candidate recognition factors and the strategies used by parasitoids to overcome host defense responses. We suggest that host-parasitoid systems are important experimental models for studying how the innate immune system of insects recognizes foreign invaders that are phylogenetically more closely related to their hosts. The strategies used by parasitoids suggest that insects may employ "hidden-self" recognition molecules for attacking foreign objects intruding the open circulatory system. BioEssays 23:344-351, 2001.

The level of cell surface beta1,4-galactosyltransferase I influences the invasive potential of murine melanoma cells

Beta1,4-Galactosyltransferase I (GalT I) is localized on the leading lamellipodia of migrating cells, where it associates with the cytoskeleton and facilitates cell spreading and migration on basal lamina matrices. It has previously been reported that a variety of highly metastatic murine and human cell lines are characterized by elevated levels of cell surface GalT I, although the intracellular biosynthetic pool is similar between cells of high and low metastatic potential. In this study, we examined whether the elevated expression of surface GalT I characteristic of metastatic cells is instructive or incidental to their metastatic behavior by altering the expression of surface GalT I and by the use of GalT I-specific perturbants. Surface GalT I levels were positively and negatively altered on murine melanoma cells by either overexpressing full-length GalT I or by homologous recombination, respectively. The consequences of altered surface GalT I expression on cell invasion in vitro and lung colonization in vivo were determined. Increasing surface GalT I expression on cells of low metastatic potential to levels characteristic of highly metastatic cells recapitulated the highly invasive phenotype in vitro. Alternatively, decreasing surface GalT I expression on highly metastatic cells to levels characteristic of low metastatic cells reduced their invasive behavior in vitro and metastatic activity in vivo. Within the physiological range of surface GalT I expression, the invasive potential of each clonal cell line correlated strongly with the level of surface GalT I expressed. As an independent means to assess the involvement of surface GalT I in metastatic behavior, cells were pretreated with two different classes of surface GalT I perturbants, a competitive oligosaccharide substrate and a substrate modifier protein. Both perturbants inhibited metastatic colonization of the lung, whereas control reagents did not. Finally, as reported by others, surface GalT I on metastatic cells selectively interacted with one glycoprotein substrate, or ligand, of approximately 100 kDa, the identity of which remains obscure. These results show that the elevated expression of surface GalT I characteristic of highly metastatic cells contributes to their invasive phenotype in vitro and to their metastatic phenotype in vivo.

High-resolution polyacrylamide gel electrophoresis of carbohydrates derivatized with a visible dye

A technique for carbohydrate analysis that is both inexpensive and easily performed is currently unavailable. In this communication we address the problem and have outlined a method for labeling saccharides with a visible dye, 4-amino-1,1'-azobenzene-3, 4'-disulfonic acid, which has an absorption maximum of 489 nm and an extinction coefficient of 37,615, to facilitate visible detection at low levels. The visible dye was coupled by a reductive amination to different sugars. The sugar-dye adducts were then separated by electrophoresis on alkaline polyacrylamide gels. The gels were scanned with a densitometer, and visible sugar-dye adducts were qualitatively analyzed by identifying them according to their mobilities. The sugar-dye adducts were quantified by determining their densitometric volume. The kinetics of the reductive amination reactions, performed at 37 degrees C, were different for each of three saccharides tested. The rate constants for glucose and fucose were 1.31 times greater and 1.8 times greater, respectively, than that of maltotriose. The reductive amination reactions were essentially complete after approximately 16 h under the given experimental conditions. A linear dose-response relationship was observed between the amount of sugar (monosaccharide, trisaccharide, or heptasaccharide) in the reductive amination reaction. The quantity of saccharide-dye adduct that could be visually detected for glucose, maltotriose, and maltoheptaose, was 25, 25, and 50 nmol, respectively. Sugar-dye adducts were separated from one another by varying the acrylamide concentration in the polyacrylamide gels. Sugar-dye adducts of monosaccharides, disaccharides, trisaccharides, and heptasaccharides were separated on alkaline 30% polyacrylamide gels with mobilities of 0.778, 0.667, 0.639, and 0.375. Adducts of glucose, fucose, galactose, and mannose were separated with mobilities of 0.844, 0.833, 0.820, and 0.810, respectively, on a 30 to 40% gradient polyacrylamide gel. Adducts of glucose and glucose derivatives were separated on a 35% polyacrylamide gel. This technique provides an inexpensive and easily performed method of carbohydrate analysis to laboratories that do not have the highly trained personnel nor the expensive equipment needed for other methods of carbohydrate analysis. The method is most applicable to research problems where sensitivity (20 pmol) is not a problem. The simplicity of the method also makes it easily incorporated into teaching laboratories.

Lex glycosphingolipids-mediated cell aggregation

Glycoconjugates bearing oligosaccharide Lex, Galbeta1-->4(Fucalpha1-->3)GlcNAcbeta1-->3R, are found on the surface of several cell types. Although recent studies have indicated that Lexon both glycosphingolipids (GSL) and polylactosaminoglycans can mediate under certain experimental conditions Lex-Lexinteractions, cell-cell interactions based exclusively on LexGSLs have not been demonstrated. In this study we show that preincubation of nonaggregating rat basophilic leukemia (RBL) cells with purified LexGSLs resulted in incorporation of the GSLs into plasma membrane, as determined by immunostaining, and formation of aggregates in the presence of Ca2+; no aggregates were formed after preincubation of the cells with globoside or sphingomyelin. Lex-mediated aggregation was inhibited by removal of Ca2+or by addition of lactofucopentaose III but not by lactose or lacto-N-fucopentaose II. In a mixture of Lex-positive and Lex-negative RBL cells most of the aggregates were composed exclusively of Lex-positive cells. The combined data suggest that interactions between LexGSL on opposite cell surfaces are strong enough to allow formation of stable cell-cell contacts.

Molecular cloning and characterization of ConBr, the lectin of Canavalia brasiliensis seeds

ConBr, a lectin isolated from Canavalia brasiliensis seeds, shares with other legume plant lectins from the genus Canavalia (Diocleinae subtribe) primary carbohydrate recognition specificity for D-mannose and D-glucose. However, ConBr exerts different biological effects than concanavalin A, the lectin of Canavalia ensiformis seeds, regarding induction of rat paw edema, peritoneal macrophage spreading in mouse, and in vitro human lymphocyte stimulation. The primary structure of ConBr was established by cDNA cloning, amino acid sequencing, and mass spectrometry. The 237-amino-acid sequence of ConBr displays Ser/Thr heterogeneity at position 96, indicating the existence of two isoforms. The mature Canavalia brasiliensis lectin monomer consists of a mixture of predominantly full-length polypeptide (alpha-chain) and a small proportion of fragments 1-118 (beta-chain) and 119-237 (gamma-chain). Although ConBr isolectins and concanavalin A differ only in residues at positions 58, 70, and 96, ConBr monomers associate into dimers and tetramers in a different pH-dependent manner than those of concanavalin A. The occurrence of glycine at position 58 does not allow formation of the hydrogen bond that in the concanavalin A tetramer exists between Asp58 of subunit A and Ser62 of subunit C. The consequence is that the alpha carbons of the corresponding residues in ConBr are 1.5 A closer that in concanavalin A, and ConBr adopts a more open quaternary structure than concanavalin A. Our data support the hypothesis that substitution of amino acids located at the subunit interface of structurally related lectins of the same protein family can lead to different quaternary conformations that may account for their different biological activities.

Embryoglycans regulate FGF-2-mediated mesoderm induction in the rabbit embryo

Several peptide growth factors, including members of the fibroblast growth factor (FGF) superfamily, are potential inducers of mesoderm in vertebrates. Receptor binding of basic FGF (FGF-2) is promoted by cell surface or extracellular matrix proteoglycans. The substantial biosynthesis of proteoglycans by embryonic cells (called embryoglycans) and their potential role as ligands for growth factor receptors led us to examine the role of embryoglycans that carry the developmentally regulated oligosaccharide epitope TEC 1, in the binding of FGF-2 to cultured rabbit inner cell masses (ICMs). Culture of isolated ICMs in the presence of FGF-2 gave rise to well delimited colonies with migrating cells at the periphery. In these cells, TEC 1 staining shifts from a punctate pattern over the entire membrane, to an apical, finely granular distribution with some internalization. This shift occurs after 96 hours in culture. Here we show that: (1) migrating cells are mesoderm-like in phenotype; (2) antibodies against TEC 1 blocked FGF-2 mediated differentiation in vitro; (3) antibodies against TEC 1 selectively blocked binding of FGF-2 to ectodermal receptors and, vice versa, the binding of TEC 1-specific antibodies to ectodermal cells can be competed by excess FGF-2; (4) the same switch in TEC 1 staining patterns was observed in vivo, between the day 7 and the day 9 rabbit embryo. These data suggest the involvement of defined species of embryonic cell surface epitopes in the regulation of FGF-2 receptor binding. Moreover, this proposed binding activity is temporally restricted to ectodermal cells and disappears early during differentiation. Thus, the apical TEC 1 redistribution can be considered as the earliest indicator of mesoderm formation.

Chicken B cells undergo discrete developmental changes in surface carbohydrate structure that appear to play a role in directing lymphocyte migration during embryogenesis

The migration of progenitor cells to specific microenvironments is essential for the development of complex organisms. Avian species possess a unique primary lymphoid organ, the bursa of Fabricius, that plays a central role in the development of B cells. B cell progenitors, however, arise outside the bursa of Fabricius and, during embryonic development, must migrate through the vasculature to the bursa of Fabricius. In this report, we demonstrate that these progenitor B cells express the sialyl Lewis × carbohydrate structure previously shown to be a ligand for the selectin family of vascular adhesion receptors. Soon after migration to the bursa of Fabricius, B cell progenitors are induced to undergo a developmental switch and terminate the expression of sialyl Lewis × in a temporal pattern that correlates with the developmental decline in the ability of these cells to home to the bursa of Fabricius upon transplantation. The induction of the developmental switch in the glycosylation pattern of developing B cells requires the bursal environment. In addition, sialyl Lewis × carbohydrate determinants or structurally similar determinants on the surface of immortalized bursal lymphoid stem cells participate in the adherence of these cells to the vascular regions of the bursal microenvironment. These data demonstrate that the carbohydrate structure sialyl Lewis × is developmentally regulated during chicken B cell development and may facilitate the migration of B cell progenitors to the bursal microenvironment by serving as a ligand for a lectin-like adhesion receptor.