A Series of Tripodal Cysteine Derivatives as Water-Soluble Chelators that are Highly Selective for Copper(I)

Abstract

A series of tripodal ligands derived from nitrilotriacetic acid and extended by three converging, metal‐binding, cysteine chains was synthesised. Their ability to bind soft metal ions thanks to their three thiolate functions was investigated by means of complementary analytical and spectroscopic methods. Three ligands that differ by the nature of the carbonyl group next to the coordinating thiolate functions were studied: L^1^ (ester), L^2^ (amide) and L^3^ (carboxylate). The negatively charged derivative L^3^, which bears three carboxylate functions close to the metal binding site, gives polynuclear copper(I) complexes of low stability. In contrast, the ester and amide derivatives L^1^ and L^2^ are efficient Cu^I^ chelators with very high affinities, close to that reported for the metal‐sequestering metallothioneins (log K≈19). Interestingly, these two ligands form mononuclear copper complexes with a unique MS~3~ coordination in water solution. An intramolecular hydrogen‐bond network involving the amide functions in the upper cavity of the tripodal ligands stabilises these mononuclear complexes and was evidenced by the very low chemical‐shift temperature coefficient of the secondary amide protons. Moreover, L^1^ and L^2^ display large selectivities for the targeted metal ion that is, Cu^I^, with respect to bioavailable Zn^II^. Therefore the two sulfur‐based tripods L^1^ and L^2^ are of potential interest for intracellular copper detoxication in vivo, without altering the homeostasis of the essential metal ion Zn^II^.