Supramolecular Self‐Assembly of Nucleotide‐Metal Coordination Complexes: From Simple Molecules to Nanomaterials

Abstract Nucleotides are essential components of DNA and RNA, and their functions depend mainly on the participation of metal ions. Thus, research into nucleotide–metal coordination complexes, including the affinities of different coordination donors for metal ions, molecular and crystal structures, supramolecular assembly, and functional nanoparticles, will contribute to the interdisciplinary field of chemistry, biology, and materials. Numerous achievements have been reported in this area but few comprehensive reviews have considered nucleotide–metal complexes from the viewpoints of crystallography and supramolecular chemistry, or aspects of their chirality and chirality delivery. In this review, we describe the coordination ability of nucleotide ligands, the structures and properties of nucleotide–metal coordination complexes, and supramolecular assemblies. We review mononuclear complexes, multinuclear complexes, 1D and 2D coordination polymers, and 3D supramolecular assemblies in terms of their structures, mainly based on their X-ray single crystal diffraction data. In particular, we highlight the chirality of nucleotide–metal complex, including their molecular chirality, supramolecular helical chirality, and extended axial chirality. Furthermore, we summarize the functional properties of nucleotide–metal nanomaterials, such as their luminescence, magnetism, and adaptive inclusion properties. We discuss the future challenges and opportunities of research into nucleotide–metal complex.