Mechanistic and structural features of protein adsorption onto mesoporous silicates

The adsorption of cytochrome c onto a range of different mesoporous silicates (NIPS) was studied. The materials used, templated using both cationic and nonionic surfactants, have average pore-size diameters in the range from 28 to 130 Angstrom. Cytochrome c was found to bind to all NIPS investigated, with the pore diameter of the material, which was measured by N-2 gas adsorption, being crucial to mesopore penetration. The adsorption of a range of proteins with isoelectric points between 1 and 10 was investigated. For adsorption to occur, the surface charges of the protein and of the NIPS must be complementary, in addition to the requirement that the pore diameter be sufficiently large. Pepsin at pH 6.5, for example, is negatively charged and does not adsorb onto cyano-modified silicate whereas subtilisin, which is of a similar size and bears an overall positive charge, is adsorbed. Using resonance Raman spectroscopy, cytochrome c was observed to occur in both high spin and low spin states, in contrast to that in solution, where the protein is predominantly in the low spin state. The presence of the high spin state may account for the enhanced peroxidative activity of the adsorbed protein.