Fluorescence emission and polarization analyses for evaluating binding of ruthenium metalloglycoclusters to lectins and tetanus toxin C-fragment

We develop a fluorescent ruthenium metalloglycocluster for use as a powerful molecular probe in evaluating the binding between carbohydrates and lectins by fluorescence emission (FE) and fluorescence polarization (FP) analyses. Changes in the FE and FP of these metalloglycoclusters are measured following the addition of lectin [peanut agglutinin (PNA), Ricinus communis agglutinin 120, Concanavalin A (ConA), or wheat germ agglutinin] or tetanus toxin c-fragment (TCF). After the addition of PNA, the FE spectrum of [Ru(bpy-2Gal)3] shows a new emission peak and the FP value of [Ru(bpy-2Gal)3] increases. Similarly, the FE spectrum of [Ru(bpy-2Glc)3] shows a new emission peak and the FP value increases on addition of ConA. Because other combinations of metalloglycoclusters and lectins show little change, specific binding of galactose to PNA and that of glucose to ConA are confirmed by the FE and FP measurements. Resulting dissociation constants (Kd) prove that the metalloglycoclusters with highly clustered carbohydrates show higher affinity for the respective lectins than those with less clustered carbohydrates. Furthermore, specific binding of [Ru(bpy-2Gal)3] to TCF was confirmed by the FP measurement

Switchable Binding Affinity of Mannose Tethered to Collagen Peptide by Temperature-Dependent Triple-Helix Formation

Novel glycopeptides were created with a view to regulate the bindings of carbohydrates to lectins as a means of controlling biological function. We synthesized glycopeptides containing mannose (Man) tethered to a collagen peptide moiety (MPOG10: −(Pro-Hyp-Gly)₁₀– or MGPP10: −(Gly-Pro-Pro)₁₀−). Circular dichroism spectra showed formation of a triple helical structure for MPOG10, and the melting temperature indicates that MPOG10 forms a more stable triple helical structure than MGPP10 in phosphate buffered saline (PBS). At 25 °C, fluorescence polarization (FP) values of MPOG10 and MGPP10 increased following the addition of <i>concanavalin A</i> (ConA), and the addition of α-methyl-mannose (MeMan) to a mixed solution of each glycopeptide with ConA resulted in a decrease in FP values. These results confirm that the previous increase in FP values observed was caused by ConA binding to Man on MPOG10 or MGPP10. The binding affinity of MPOG10 was higher than that of MGPP10, and the dissociation constant of MPOG10 to ConA was 1.9 × 10^–5 (mol/L). The observed binding of MPOG10 to ConA at 25 °C was reduced at higher temperature (50 °C). Therefore, the enhanced binding affinity of MPOG10 to ConA could be accounted for by formation of a clustered Man moiety triggered by the formation of a more stable triple helical structure of MPOG10 compared with MGPP10