muramidase and octadecyltrichlorosilane

We have employed in situ X-ray reflectivity (IXRR) to study the adsorption of a variety of proteins (lysozyme, cytochrome c, myoglobin, hemoglobin, serum albumin, and immunoglobulin G) on model hydrophilic (silicon oxide) and hydrophobic surfaces (octadecyltrichlorosilane self-assembled monolayers), evaluating this recently developed technique for its applicability in the area of biomolecular studies. We report herein the highest resolution depiction of adsorbed protein films, greatly improving on the precision of previous neutron reflectivity (NR) results and previous IXRR studies. We were able to perform complete scans in 5 min or less with the maximum momentum transfer of at least 0.52 Å(-1), allowing for some time-resolved information about the evolution of the protein film structure. The three smallest proteins (lysozyme, cytochrome c, and myoglobin) were seen to deposit as fully hydrated, nondenatured molecules onto hydrophilic surfaces, with indications of particular preferential orientations. Time evolution was observed for both lysozyme and myoglobin films. The larger proteins were not observed to deposit on the hydrophilic substrates, perhaps because of contrast limitations. On hydrophobic surfaces, all proteins were seen to denature extensively in a qualitatively similar way but with a rough trend that the larger proteins resulted in lower coverage. We have generated high-resolution electron density profiles of these denatured films, including capturing the growth of a lysozyme film. Because the solution interface of these denatured films is diffuse, IXRR cannot unambiguously determine the film extent and coverage, a drawback compared to NR. X-ray radiation damage was systematically evaluated, including the controlled exposure of protein films to high-intensity X-rays and exposure of the hydrophobic surface to X-rays before adsorption. Our analysis showed that standard measuring procedures used for XRR studies may lead to altered protein films; therefore, we used modified procedures to limit the influence of X-ray damage.

Topics: Adsorption; Cytochromes c; Hemoglobins; Hydrophobic and Hydrophilic Interactions; Immunoglobulin G; Muramidase; Myoglobin; Serum Albumin; Silanes; Silicon Dioxide; Surface Properties; X-Rays

Lysozyme was immobilized on a prefabricated carboxylic acid terminated chemical template, forming a tightly packed, one monolayer thick lysozyme pattern. Polyclonal anti-lysozyme antibodies can bind to the immobilized lysozyme pattern. Atomic force microscope (AFM) observation reveals that the antibodies bind to the lysozyme molecules on the pattern edge before they bind to the lysozyme molecules in the pattern interior. Better spatial accessibility and flexibility of the lysozyme molecules on the pattern edge are used to explain the observed antibody binding preference. The topographies of the lysozyme pattern also affect the antibody binding. The antibodies bind to the edge lysozyme from the top if the lysozyme pattern is half-buried in a 10 A deep channel, whereas the antibodies bind to the edge lysozyme from the side if the lysozyme pattern is immobilized on a protruding terrace. The observed "edge effect" suggests that, for the same protein coverage, reducing the protein pattern feature to the nanoscale will improve the overall binding activity of the immobilized protein toward the antibody.

Topics: Animals; Antibodies; Antigen-Antibody Complex; Carboxylic Acids; Chickens; Egg White; Hydrogen-Ion Concentration; Microscopy, Atomic Force; Muramidase; Protein Binding; Proteins; Silanes; Spectrophotometry, Infrared; Surface Properties