Chelating Surfaces for Oriented Human Serum Albumin Molecules.

Protein immobilization in a specific conformation or orientation at an interface is influenced by specific interactions with the outer layer of the surface. A strategy to build-up a complex construct which is able to orient protein molecules, based on metal-cation chelation processes, is reported. The proposed methodology implies the formation of a mercaptoundecanoic acid monolayer on a gold surface that is activated to attach covalently the tripeptide glycyl-l-histidyl-l-lysine (GHK) on the surface, whose sites are then employed to chelate copper ions, providing a selective platform for the orientation of human serum albumin (HSA) molecules. The protein adsorption process on GHK and GHK-Cu(II)-complex surfaces was monitored by the in situ quartz crystal microbalance with dissipation monitoring (QCM-D) and force spectroscopy technique. The changes in frequency and dissipation factor as well as the D- f plots from QCM-D measurements help to characterize the changes in the protein conformation and are confirmed by force curve spectroscopy results. An improved kinetic model, based on random sequential adsorption with variable protein footprints, has been developed to predict and simulate the experimentally found HSA average surface coverage onto the GHK and GHK-Cu(II)-complex surfaces.

Surface-driven first-step events of nanoscale self-assembly for molecular peptide fibers: An experimental and theoretical study.

New experimental results are reported on the self-assembling behavior of EAK16-II, the first discovered ionic self-complementary peptide, incubated at ultralow concentration (10-6 M) at neutral pH onto differently charged surfaces. It is found that strongly negatively charged surfaces promote the self-assembly of flat, micrometer-long mono-molecular fibers of side-on assembled sequences, lying onto a continuous monolayer of flat-on EAK16-II molecules. These results suggest that the monomolecular EAK16-II self-assembly is driven by the peculiar matching condition between peptide and surface electrostatic properties. Molecular Mechanics simulations of the basic bimolecular interactions confirmed the experimental inferences, showing that the flat-on state is the most stable arrangement for two interacting EAK16-II sequences onto strongly negatively charged surfaces, where indeed EAK16-II ß-sheet conformation is stabilized, while the weak electrostatic interactions with mildly charged substrates promote an "entangled" EAK16-II geometry. Molecular Dynamics simulations further showed that the mobility and diffusional freedom of the peptides from the surfaces are ruled by the relative strength of peptide-surface electrostatic interactions, so that desorption probability for the peptide sequences is negligible from strongly-charged surfaces and high from mildly-charged surfaces. Furthermore, it has been found that an oligopeptide sequence lying onto two flat-on EAK16-II molecules, gains a remarkable lateral mobility, while remaining weakly bound to the surface, thus allowing the further molecular self-alignment responsible for the micrometer-long fiber formation. The reported results pave the way to the understanding and control of the subtle peptide-surface structural motifs matching enabling the formation of micrometer-long, but nanometer-wide monomolecular fibers.

Selective protein trapping within hybrid nanowells.

Nanostructured surfaces offer a great deal in view of the control of biological processes at subcellular level. An innovative methodology has been developed to fabricate large-scale hexagonally close-packed arrays of polymer/gold nanowells of tunable diameter and depth, ranging between about 70 and 100 nm (diameter) and 15 and 40 nm (depth). Nanowell volumes down to 0.3 attolitres and nanowell densities as high as ∼10(9) wells per cm(2) could also be demonstrated. The present paper investigates the main features of protein trapping processes within the obtained nanowell arrays. Selective protein trapping, also involving orientation and biofunctionality changes, appears to be induced by the nanoconfinement. Nanomorphology measurements and antibody preferential linkages are demonstrated for human serum albumin versus lysozyme, the first being efficiently trapped within the nanocavities and the second being preferentially deposited outside them. The selective protein-dependent trapping/untrapping within the nanowells is discussed in terms of the variation in the out-diffusion coefficients of the biomolecules entering the nanowells, either as a function of the matching/mismatching of the biomolecules and nanocavity dimensions, or, alternatively, owing to the drastic conformational changes due to nanoconfinement. In this case, the trapping of large and soft human serum albumin is privileged with respect to the small and hard lysozyme. Furthermore, the observed peculiar antibody response to the confined proteins is accounted for in terms of the enhancement of their biological response following the modified accessibility of the key epitopes, which in turn suggests drastic conformational changes.

Driving h-osteoblast adhesion and proliferation on titania: peptide hydrogels decorated with growth factors and adhesive conjugates.

Hydrogels from self-assembling ionic complementary peptides have been receiving much interest from the scientific community as mimetics of the extracellular matrix that can offer three-dimensional support for cell growth or become vehicles for the delivery of stem cells or drugs. These scaffolds have also been proposed as bone substitutes for small defects as they promote beneficial effects on human osteoblasts. In order to develop a novel bioactive titanium implant, we propose the introduction of a layer of ionic-complementary self-assembling peptides (EAbuK) on Ti whose surface has been previously sandblasted and acid etched. The peptide layer is anchored to the metal by covalent functionalization of titania with self-assembling sequences. The peptide layer has also been enriched by the insulin-like growth factor-1 incorporated to the layer and/or a conjugate obtained by chemoselective ligation between EAbuK and a sequence of 25 residues containing four GRGDSP motifs per chain. X-ray photoelectron spectroscopy studies confirmed a change in the surface composition in agreement with the proposed decorations. An evaluation of the contact angle showed a substantial change in wettability induced by the peptide layer. The human osteoblast adhesion and proliferation assays showed an increase in adhesion for the surfaces enriched with conjugate at a concentration of 3.8 × 10(-7)m and an enhanced proliferation for samples enriched with insulin-like growth factor-1 at the highest concentration tested (2.1 × 10(-5)m).