<p>FRIL is a legume lectin from the hyacinth bean that has broad-spectrum antiviral activity. A distinctive trait of FRIL among similar mannose/glucose-specific legume lectins is that FRIL shows specificity for complex type N-glycans. We postulate that an extended binding site on FRIL facilitates this ligand selectivity. Here, we show legume lectin carbohydrate recognition domain (CRD) loop B is the main determinant of complex versus high-mannose N-glycan specificity in FRIL and Concanavalin A (ConA), respectively. First, we find that the inactive precursors of recombinant FRIL (rFRIL) and proConA (rproConA) can be activated via deglycosylation. Secondly, the cryo-EM structures of inactive apo rFRIL, active FRIL in complex with Galβ1,4-(Fucα1,3-)GlcNAcβ1,2-Man tetrasaccharide, and active rFRIL in complex with Mannose<sub>9</sub>GlcNAc<sub>2</sub> (Man9) N-glycan are determined, and residues H102 and Y101 on loop B are identified as crucial for complex glycan recognition. Finally, we swapped loop B residues 101 and 102 alongside loop C residue 145 on FRIL to their structural equivalent on ConA, resulting in a FRIL mutant that binds exclusively to high mannose N-glycans. Taken together, we have established a process of activating recombinant FRIL and related lectins through deglycosylation, and demonstrated the crucial role that loop B residues play in establishing oligosaccharide specificity.</p>

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Altering the carbohydrate-binding specificity of the legume lectin FRIL through structure-guided engineering

  • Yo-Min Liu,
  • Hong Thuy Vy Nguyen,
  • Xiaorui Chen,
  • Md. Shahed-Al-Mahmud,
  • Ting-Hua Chen,
  • Kuo-Shiang Liao,
  • Jennifer M. Lo,
  • Tzu-Chun Kan,
  • Chien-Tai Ren,
  • Che Ma

摘要

FRIL is a legume lectin from the hyacinth bean that has broad-spectrum antiviral activity. A distinctive trait of FRIL among similar mannose/glucose-specific legume lectins is that FRIL shows specificity for complex type N-glycans. We postulate that an extended binding site on FRIL facilitates this ligand selectivity. Here, we show legume lectin carbohydrate recognition domain (CRD) loop B is the main determinant of complex versus high-mannose N-glycan specificity in FRIL and Concanavalin A (ConA), respectively. First, we find that the inactive precursors of recombinant FRIL (rFRIL) and proConA (rproConA) can be activated via deglycosylation. Secondly, the cryo-EM structures of inactive apo rFRIL, active FRIL in complex with Galβ1,4-(Fucα1,3-)GlcNAcβ1,2-Man tetrasaccharide, and active rFRIL in complex with Mannose9GlcNAc2 (Man9) N-glycan are determined, and residues H102 and Y101 on loop B are identified as crucial for complex glycan recognition. Finally, we swapped loop B residues 101 and 102 alongside loop C residue 145 on FRIL to their structural equivalent on ConA, resulting in a FRIL mutant that binds exclusively to high mannose N-glycans. Taken together, we have established a process of activating recombinant FRIL and related lectins through deglycosylation, and demonstrated the crucial role that loop B residues play in establishing oligosaccharide specificity.