Porous silicon/photosynthetic reaction center hybrid nanostructure
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The purified photosynthetic reaction center protein (RC) from Rhodobacter sphaeroides R-26 purple bacteria was bound to porous silicon microcavities (PSiMc) either through silane-glutaraldehyde (GTA) chemistry or via a noncovalent peptide cross-linker. The characteristic resonance mode in the microcavity reflectivity spectrum red shifted by several nanometers upon RC binding, indicating the protein infiltration into the porous silicon (PSi) photonic structure. Flash photolysis experiments confirmed the photochemical activity of RC after its binding to the solid substrate. The kinetic components of the intraprotein charge recombination were considerably faster (τfast = 14 (±9) ms, τslow = 230 (±28) ms with the RC bound through the GTA cross-linker and only τfast = 27 (±3) ms through peptide coating) than in solution (τfast = 120 (±3) ms, τslow = 1387 (±2) ms), indicating the effect of the PSi surface on the light-induced electron transfer in the protein. The PSi/RC complex was found to oxidize the externally added electron donor, mammalian cytochrome c, and the cytochrome oxidation was blocked by the competitive RC inhibitor, terbutryne. This fact indicates that the specific surface binding sites on the PSi-bound RC are still accessible to external cofactors and an electronic interaction with redox components in the aqueous environment is possible. This new type of biophotonic material is considered to be an excellent model for new generation applications at the interface of silicon-based electronics and biological redox systems designed by nature. © 2012 American Chemical Society.
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Aqueous environment; Bio photonics; Charge recombinations; Cofactors; Crosslinker; Cytochrome c; Electron donors; Electronic interactions; Flash photolysis; Hybrid nanostructures; Light-induced electron transfer; Noncovalent; Peptide coating; Photochemical activity; Photonic structure; Photosynthetic reaction center; Porous silicon microcavities; Purple bacteria; Reaction center; Red-shifted; Redox systems; Reflectivity spectra; Resonance mode; Rhodobacter sphaeroides; Silicon-based electronics; Solid substrates; Specific surface; Aldehydes; Binding sites; Biological materials; Mammals; Microcavities; Peptides; Porous silicon; Redox reactions; Interfaces (materials); nanomaterial; silicon; animal; article; chemistry; electron transport; enzymology; photosynthesis; porosity; Rhodobacter sphaeroides; Animals; Electron Transport; Nanostructures; Photosynthetic Reaction Center Complex Proteins; Porosity; Rhodobacter sphaeroides; Silicon
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