The structure of concanavalin A in complex with the trimannoside methyl-3,6-di-O-(␣-D-mannopyranosyl)-␣-Dmannopyranoside has been determined in a novel space group. In three of the four subunits of the concanavalin A tetramer, the interactions between the protein and the bound saccharide are essentially identical to those reported previously by other authors (Naismith, J. H., and Field, R. A. (1996) J. Biol. Chem. 271, 972-976). In the fourth subunit, however, the ␣133 linkage has a different conformation, resulting in a different part of the ␣133-linked mannose interacting with essentially the same surface of the protein. Furthermore, significant differences are observed in the quaternary associations of the subunits compared with the saccharide-free structures and other carbohydrate complexes, suggesting that the concanavalin A tetramer is a rather flexible entity.Concanavalin A was the first legume lectin to be isolated (1), sequenced (2-4), and to have its three-dimensional structure determined by x-ray crystallography (5, 6). Concanavalin A belongs to the glucose/mannose-specific lectins (7) and was shown to have its highest binding affinity for methyl-3, Nevertheless, the first view of a carbohydrate bound to concanavalin A in a specific manner was obtained only in 1989, when the structure of a concanavalin A-methyl-␣-D-mannopyranoside complex was presented (12). Today, the details of the trimannose 1 binding to concanavalin A have been unravelled by Naismith and Field (13) in a crystal form with a unit cell different from the structure discussed by us. The structure of concanavalin A complexed with methyl-␣-D-glucopyranoside in a cubic crystal has been solved (14) and co-crystallization with methyl-␣-D-arabinofuranoside (15) has been reported. Also, the structures of a number of other legume lectins and their carbohydrate complexes have been determined (16 -19). On the other hand the thermodynamics of concanavalin A-carbohydrate interactions have been addressed in several recent studies and have been the subject of considerable debate (20 -23). A refined structure of concanavalin A in complex with the specific trisaccharide methyl-3,6-di-O-(␣-D-mannopyranosyl)-␣-D-mannopyranoside is here compared with the recently published structure of Naismith and Field (13).
EXPERIMENTAL PROCEDURES Purification of concanavalin A, crystallization of its complex with the methyl-3,6-di-O-(␣-D-mannopyranosyl)-␣-D-mannopyranoside, cryocooling and data collection have been reported elsewhere (24). Crystals belong to space group P2 1 , unit cell parameters a ϭ 59.83 Å, b ϭ 62.84 Å, c ϭ 125.92 Å,  ϭ 93.87°and contain a complete concanavalin A tetramer in the asymmetric unit. Data within 15.0 and 2.3 Å were collected at 100 K from a single crystal with a FAST area detector on an Enraf-Nonius rotating anode source operated at 40 kV and 90 mA. Due to technical problems, the data collection had to be abandoned prematurely, resulting in a data set that is 71.3% complete between the resolution limits of 10 and 2.35 Å. Further attem...
