Diatoms are single cell microalgae with a silica shell (frustule), which possess a micro/nanoporous pattern of unparalleled diversity far beyond the possibilities of current micro- and nanofabrication techniques. To explore diatoms as natural three-dimensional nanostructured supports in sensing and biosensing devices, a simple, rapid and stable method to immobilize diatoms via gold electrodeposition is described. In this process, gold microstructures are formed, immobilizing diatoms by entrapment or crossing their nanopores. Varying the applied potential, time and HAuCl4 concentration, gold deposits of different morphologies and roughness are obtained, thereby determining the diatom immobilization process. Optical and scanning electron microscopy have been used to characterize diatom immobilization yields, the morphology of the gold microstructures, and the morphological integrity of diatoms. Cyclic voltammetry has been performed to characterize the gold deposits and to demonstrate the enhanced electrocatalytic activity of the gold-diatom electrodes. Electro-addressed immobilization of different diatoms on specific bands of interdigitated electrode arrays has been achieved, highlighting the potential application of diatoms for site-specific immobilization on microarrays. The feasibility to combine tailored immobilization with diatom biofunctionalization has also been demonstrated. Antibody-functionalized diatoms were immobilized on electrodes retaining their ability to detect its cognate antigen. The reported method exploits the natural three-dimensional nanostructures of diatoms together with their easy modification with biomolecules and the simplicity of gold electrodeposition to produce micro/nanostructured and highly electrocatalytic electrodes, providing low-cost and eco-friendly platforms and arrays with potential application in biosensing devices.