Sabine André scite author profile

Galectin-3 is unique among the galectin family of animal lectins in its biological activities and structure. Most members of the galectin family including galectin-1 possess apoptotic activities, whereas galectin-3 possesses anti-apoptotic activity. Galectin-3 is also the only chimera type galectin and consists of a nonlectin N-terminal domain and a C-terminal carbohydrate-binding domain. Recent sedimentation equilibrium and velocity studies show that murine galectin-3 is a monomer in the absence and presence of LacNAc, a monovalent sugar. However, quantitative precipitation studies in the present report indicate that galectin-3 precipitates as a pentamer with a series of divalent pentasaccharides with terminal LacNAc residues. Furthermore, the kinetics of precipitation are fast, on the order of seconds. This indicates that although the majority of galectin-3 in solution is a monomer, a rapid equilibrium exists between the monomer and a small percentage of pentamer. The latter, in turn, precipitates with the divalent oligosaccharides, resulting in rapid conversion of monomer to pentamer by mass action equilibria. Mixed quantitative precipitation experiments and electron microscopy suggest that galectin-3 forms heterogenous, disorganized cross-linking complexes with the multivalent carbohydrates. This contrasts with galectin-1 and many plant lectins that form homogeneous, organized cross-linked complexes. The results are discussed in terms of the biological properties of galectin-3.

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Chemical Biology of the Sugar Code

Gabius

et al. 2004

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A high-density coding system is essential to allow cells to communicate efficiently and swiftly through complex surface interactions. All the structural requirements for forming a wide array of signals with a system of minimal size are met by oligomers of carbohydrates. These molecules surpass amino acids and nucleotides by far in information-storing capacity and serve as ligands in biorecognition processes for the transfer of information. The results of work aiming to reveal the intricate ways in which oligosaccharide determinants of cellular glycoconjugates interact with tissue lectins and thereby trigger multifarious cellular responses (e.g. in adhesion or growth regulation) are teaching amazing lessons about the range of finely tuned activities involved. The ability of enzymes to generate an enormous diversity of biochemical signals is matched by receptor proteins (lectins), which are equally elaborate. The multiformity of lectins ensures accurate signal decoding and transmission. The exquisite refinement of both sides of the protein-carbohydrate recognition system turns the structural complexity of glycans--a demanding but essentially mastered problem for analytical chemistry--into a biochemical virtue. The emerging medical importance of protein-carbohydrate recognition, for example in combating infection and the spread of tumors or in targeting drugs, also explains why this interaction system is no longer below industrial radarscopes. Our review sketches the concept of the sugar code, with a solid description of the historical background. We also place emphasis on a distinctive feature of the code, that is, the potential of a carbohydrate ligand to adopt various defined shapes, each with its own particular ligand properties (differential conformer selection). Proper consideration of the structure and shape of the ligand enables us to envision the chemical design of potent binding partners for a target (in lectin-mediated drug delivery) or ways to block lectins of medical importance (in infection, tumor spread, or inflammation).

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Growth-regulatory Human Galectin-1: Crystallographic Characterisation of the Structural Changes Induced by Single-site Mutations and their Impact on the Thermodynamics of Ligand Binding

López-Lucendo

Solı́s

André

et al. 2004

Journal of Molecular Biology

277

290

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From lectin structure to functional glycomics: principles of the sugar code

Gabius¹,

André²,

Jiménez‐Barbero³

et al. 2011

Trends in Biochemical Sciences

456

293

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Galectin-5 is bound onto the surface of rat reticulocyte exosomes and modulates vesicle uptake by macrophages

et al. 2010

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Reticulocytes release small membrane vesicles termed exosomes during their maturation into erythrocytes. Exosomes are intraluminal vesicles of multivesicular endosomes released into the extracellular medium by fusion of these endosomal compartments with the plasma membrane. This secretion pathway contributes to reticulocyte plasma membrane remodeling by eliminating certain membrane glycoproteins. We show in this study that galectin-5, although mainly cytosolic, is also present on the cell surface of rat reticulocytes and erythrocytes. In addition, in reticulocytes, it resides in the endosomal compartment. We document galectin-5 translocation from the cytosol into the endosome lumen, leading to its secretion in association with exosomes. Galectin-5 bound onto the vesicle surface may function in sorting galactosebearing glycoconjugates. Fittingly, we found that Lamp2, a major cellular glycoprotein presenting galectin-reactive poly-N-acetylactosamine chains, is lost during reticulocyte maturation. It is associated with released exosomes, suggestive of binding to galectin-5. Finally, we reveal that the uptake of rat reticulocyte exosomes by macrophages is dependent on temperature and the mechanoenzyme dynamin and that exosome uptake is decreased by adding galectin-5. These data imply galectin-5 functionality in the exosomal sorting pathway during rat reticulocyte maturation. (Blood. 2010;115: 696-705) IntroductionExosomes are membrane vesicles secreted by various cells and represent intraluminal vesicles of multivesicular endosomes (MVEs) released into the extracellular medium upon fusion of MVE with the plasma membrane. 1 Exosomal release during reticulocyte maturation is part of a cellular program resulting in remodeling of the plasma membrane by removal of a distinct set of (glyco)proteins. 2 We have previously shown that exosomal segregation of internalized membrane (glyco)proteins can occur by different routes, such as a natural enrichment in membrane domains (eg, lipid rafts), 3 antibody-or lectin-induced clustering on the cell surface, 4 or via the endosomal sorting complex required for transport (ie, ESCRT) cytosolic machinery. 5 During an earlier stage of mammalian erythroid differentiation, ie, when the erythroblast expels its nucleus, some components of the erythroblast plasma membrane are already specifically sorted to either the nascent reticulocyte or the expelled nucleus. For example, it has been shown by the use of mouse erythroblasts that proteins such as erythroblast-macrophage protein and ␤1-integrin partitioned predominantly to the plasma membrane surrounding the expelled nucleus, whereas glycophorin A localized to the plasma membrane of the nascent reticulocyte. 6 Both erythroblastmacrophage protein and ␤1-integrin have been identified as adhesion molecules involved in erythroblast retention by central macrophages within erythroblastic islands. [7][8][9] Thus, it has been suggested that their segregation to expelled nuclei favors their engulfment by macrophages while enabling reticulocytes to de...

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Sabine André

Galectin-3 Precipitates as a Pentamer with Synthetic Multivalent Carbohydrates and Forms Heterogeneous Cross-linked Complexes

Chemical Biology of the Sugar Code

Growth-regulatory Human Galectin-1: Crystallographic Characterisation of the Structural Changes Induced by Single-site Mutations and their Impact on the Thermodynamics of Ligand Binding

From lectin structure to functional glycomics: principles of the sugar code

Galectin-5 is bound onto the surface of rat reticulocyte exosomes and modulates vesicle uptake by macrophages

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