info:eu-repo/semantics/article
Crystal structures of peanut lectin in the presence of synthetic β-N- And β-S-galactosides disclose evidence for the recognition of different glycomimetic ligands
Fecha
2020-11Registro en:
Cagnoni, Alejandro; Primo, Emiliano David; Klinke, Sebastian; Cano, María Emilia; Giordano, Walter Fabian; et al.; Crystal structures of peanut lectin in the presence of synthetic β-N- And β-S-galactosides disclose evidence for the recognition of different glycomimetic ligands; International Union of Crystallography; Acta Crystallographica Section D: Structural Biology; 76; 11-2020; 1080-1091
2059-7983
2059-7983
CONICET Digital
CONICET
Autor
Cagnoni, Alejandro
Primo, Emiliano David
Klinke, Sebastian
Cano, María Emilia
Giordano, Walter Fabian
Mariño, Karina Valeria
Kovensky, José
Goldbaum, Fernando Alberto
Uhrig, Maria Laura
Otero, Lisandro Horacio
Resumen
Carbohydrate-lectin interactions are involved in important cellular recognition processes, including viral and bacterial infections, inflammation and tumor metastasis. Hence, structural studies of lectin-synthetic glycan complexes are essential for understanding lectin-recognition processes and for the further design of promising chemotherapeutics that interfere with sugar-lectin interactions. Plant lectins are excellent models for the study of the molecular-recognition process. Among them, peanut lectin (PNA) is highly relevant in the field of glycobiology because of its specificity for β-galactosides, showing high affinity towards the Thomsen-Friedenreich antigen, a well known tumor-associated carbohydrate antigen. Given this specificity, PNA is one of the most frequently used molecular probes for the recognition of tumor cell-surface O-glycans. Thus, it has been extensively used in glycobiology for inhibition studies with a variety of β-galactoside and β-lactoside ligands. Here, crystal structures of PNA are reported in complex with six novel synthetic hydrolytically stable β-N- and β-S-galactosides. These complexes disclosed key molecular-binding interactions of the different sugars with PNA at the atomic level, revealing the roles of specific water molecules in protein-ligand recognition. Furthermore, binding-affinity studies by isothermal titration calorimetry showed dissociation-constant values in the micromolar range, as well as a positive multivalency effect in terms of affinity in the case of the divalent compounds. Taken together, this work provides a qualitative structural rationale for the upcoming synthesis of optimized glycoclusters designed for the study of lectin-mediated biological processes. The understanding of the recognition of β-N- and β-S-galactosides by PNA represents a benchmark in protein-carbohydrate interactions since they are novel synthetic ligands that do not belong to the family of O-linked glycosides.