Glycosyltransferases (GTs) catalyze the transfer of a sugar moiety from an activated donor sugar onto saccharide and nonsaccharide acceptors. A sequence-based classification spreads GTs in many families thus reflecting the variety of molecules that can be used as acceptors. In contrast, this enzyme family is characterized by a more conserved three-dimensional architecture. Until recently, only two different folds (GT-A and GT-B) have been identified for solved crystal structures. The recent report of a structure for a bacterial sialyltransferase allows the definition of a new fold family. Progress in the elucidation of the structures and mechanisms of GTs are discussed in this review. To accommodate the growing number of crystal structures, we created the 3D-Glycosyltransferase database to gather structural information concerning this class of enzymes.
On the basis of function and sequence similarities, the vertebrate fucosyltransferases can be classified into three groups: alpha-2-, alpha-3-, and alpha-6-fucosyltransferases. Thirty new putative fucosyltransferase genes from invertebrates and bacteria and six conserved peptide motifs have been identified in DNA and protein databanks. Two of these motifs are specific of alpha-3-fucosyltransferases, one is specific of alpha-2-fucosyltransferases, another is specific of alpha-6-fucosyltransferases, and two are shared by both alpha-2- and alpha-6-fucosyltranserases. Based on these data, literature data, and the phylogenetic analysis of the conserved peptide motifs, a model for the evolution offucosyltransferase genes by successive duplications, followed by divergent evolution is proposed, with either two different ancestors, one for the alpha-2/6-fucosyltransferases and one for the alpha-3-fucosyltransferases or a single common ancestor for the two families. The expected properties of such an hypothetical ancestor suggest that the plant or insect alpha-3-fucosyltransferases using chitobiose as acceptor might be the present forms of this ancestor, since fucosyltransferases using chitobiose as acceptor are expected to be of earlier appearance in evolution than enzymes using N -acetyllactosamine. However, an example of convergent evolution of fucosyltransferase genes is suggested for the appearance of the Leaepitopes found in plants and primates.
Helix pomatia agglutinin (HPA) is a N-acetylgalactosamine (GalNAc) binding lectin found in the albumen gland of the roman snail. As a constituent of perivitelline fluid, HPA protects fertilized eggs from bacteria and is part of the innate immunity system of the snail. The peptide sequence deduced from gene cloning demonstrates that HPA belongs to a family of carbohydrate-binding proteins recently identified in several invertebrates. This domain is also present in discoidin from the slime mold Dictyostelium discoideum. Investigation of the lectin specificity was performed with the use of glycan arrays, demonstrating that several GalNAc-containing oligosaccharides are bound and rationalizing the use of this lectin as a cancer marker. Titration microcalorimetry performed on the interaction between HPA and GalNAc indicates an affinity in the 10 ؊4 M range with an enthalpy-driven binding mechanism. The crystal structure of HPA demonstrates the occurrence of a new -sandwich lectin fold. The hexameric quaternary state was never observed previously for a lectin. The high resolution structure complex of HPA with GalNAc characterizes a new carbohydrate binding site and rationalizes the observed preference for ␣GalNAc-containing oligosaccharides.
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