Closing a Calix[6]arene-Based Funnel Zn2+ Complex at Its Large Rim Entrance: Consequences on Metal Ion Affinity and Host-Guest Properties

A molecular capsule based on a calix[6]arene core closed at the small rim by a three-point coordinated metal ion and at the large rim by a three-point covalent capping is described. It is derived from a trisimidazole funnel complex capped by a trenamide unit that prevents in/ out exchange of guest molecules through the large rim. A detailed comparative study with three different calixarenes provides a unique opportunity for (i) comparing the binding ability of two different coordination sites in well three-dimensional (3D)-structured macrocyclic receptors and (ii) evaluating the impact of a covalent closing of one rim of a funnel receptor while the other rim is closed by weaker coordination bonds. Indeed, this study allowed for highlighting various interesting new features. It is first shown that the trenamide site can bind a metal ion such as Zn2+ by itself. This involves a 1:1 coordination of the metal ion to the three carbonyl groups of the amide functions, which undergo trans-to-cis isomerization and are partially embedded in the calix core. When the trisimidazole core is present, the Zn2+ ion preferentially binds at the small rim, thus closing the cavity. Guest ligand exchange must then occur through a decoordination/recoordination process of the metal ion. The modification and rigidification of the calixarene conformation induced by the large rim capping strengthen the metal ion coordination at the small rim. This also leads to a selective metallo-receptor that readily binds EtNH2 under conditions where PrNH2 is not recognized at all. The increased rigidity of the receptor, however, weakens the host-guest interactions, precluding important induced-fit behaviors that are at work in the parent, large rim opened, funnel complex.

Automated summary

The study on a molecular capsule based on a calix[6]arene core reveals unique coordination modes to prevent guest molecule exchange and evaluates the impact of different closing mechanisms on binding ability. The selective binding of different ligands through metal ion coordination highlights the importance of rigidification of receptor conformation. However, increased rigidity may weaken host-guest interactions, affecting the induced-fit behaviors observed in the parent compound.