Inorganic–Organic Nanotube Composites from Template Mineralization of Tobacco Mosaic Virus

The use of biological molecules, assemblies and systems in the development of inorganic materials synthesis continues to offer new and exciting alternatives to conventional synthetic strategies. Biological templates, such as protein cages, viroid capsules, bacterial rhapidosomes, S-layers, multicellular superstructures, biolipid cylinders, and DNA, have been utilized to direct the deposition, assembly, and patterning of inorganic nanoparticles and microstructures. In this paper, we report a new approach to the template-directed synthesis of inorganic±organic nanotubes using tobacco mosaic virus (TMV). TMV is a remarkably stable virion, remaining intact at temperatures up to 60 C and at pH values between 2 and 10. Each viral particle consists of 2130 identical protein subunits arranged in a helical motif around a single strand of RNA to produce a hollow protein tube, 300 18 nm in size, with a 4 nm-wide central channel. The internal and external surfaces of the protein consist of repeated patterns of charged amino acid residues, such as glutamate, aspartate, arginine, and lysine. In principle, these functionalities should offer a wide variety of nucleation sites for surface-controlled inorganic deposition, which, in association with the high thermal and pH stability, could be exploited in the synthesis of unusual materials such as high-aspect-ratio composites and protein-confined inorganic nanowires. Here we show that TMV is a suitable template for reactions such as co-crystallization (CdS and PbS), oxidative hydrolysis (iron oxides), and sol-gel condensation (SiO2) (Fig. 1).