Binding of a series of synthetic multivalent carbohydrate analogs to the Man/Glc-specific lectins concanavalin A and Dioclea grandiflora lectin was investigated by isothermal titration microcalorimetry. Dimeric analogs possessing terminal ␣-D-mannopyranoside residues, and di-, tri-, and tetrameric analogs possessing terminal 3,6-di-O-(␣-D-mannopyranosyl)-␣-D-mannopyranoside residues, which is the core trimannoside of asparaginelinked carbohydrates, were selected in order to compare the effects of low and high affinity analogs, respectively. Experimental conditions were found that prevented precipitation of the carbohydrate-lectin cross-linked complexes during the isothermal titration microcalorimetry experiments. The results show that the value of n, the number of binding sites on each monomer of the lectins, is inversely proportional to the number of binding epitopes (valency) of each carbohydrate. Hence, n values close to 1.0, 0.50, and 0.25 were observed for the binding of mono-, di-, and tetravalent sugars, respectively, to the two lectins. Importantly, differences in the functional valency of a triantennary analog for concanavalin A and D. grandiflora lectin are observed. The enthalpy of binding, ⌬H, is observed to be directly proportional to the number of binding epitopes in the higher affinity analogs. For example, ⌬H of a tetravalent trimannoside analog is nearly four times greater than that of the corresponding monovalent analog. Increases in K a values of the multivalent carbohydrates relative to monovalent analogs, known as the "multivalency effect," are shown to be due to more positive entropy (T⌬S) contributions to binding of the former sugars. A general thermodynamic model for distinguishing binding of multivalent ligands to a single receptor with multiple, equal subsites versus binding to separate receptor molecules is given.Carbohydrate-protein interactions are involved in a wide variety of biological functions including cellular growth, recognition, adhesion, cancer metastasis, bacterial and viral infections, and inflammation (1, 2). The specificity of these interactions has been an active area of research due, in part, to efforts at designing therapeutic analogs of carbohydrates (3, 4). However, attempts to design high affinity analogs for specific carbohydrate-binding proteins (lectins) have been difficult due to the intrinsic low affinity of carbohydrates in many cases (5, 6). For example, the affinity constants (K a ) for the binding of simple mono-and oligosaccharides to most lectins are between 10 3 and 10 6 M Ϫ1 (7,8). This range of K a values is too low for effective drug design. However, many naturally occurring carbohydrates and glycoconjugates including glycoproteins and glycolipids are multivalent (2) which results in their increased avidity for lectins (9). As a consequence, there has been considerable interest in designing multivalent or "clustered" carbohydrate analogs for high affinity binding to target lectin receptors (10, 11). Thus, it is important to understand the thermodyna...
