The interaction between lightly cross-linked poly(acrylic acid) (pAA) microgels (50−150 μm in diameter) and
poly-l-lysine (pLys) was studied as a function of pH, ionic strength, peptide size, and concentration. The swelling
response and distribution of polypeptides within microgel particles was monitored by micromanipulator-assisted light
microscopy and confocal laser scanning microscopy, while binding isotherms of pLys in the microgels were determined
spectrophotometrically. Conformational changes of pLys were investigated by circular dichroism. The molecular
weight of pLys was found to influence the degree of peptide-induced microgel deswelling, largely due to limitation
of peptides larger than the effective network mesh size to penetrate the entire gel. Large peptides were concentrated
within a surface layer of the gel particles, and at low ionic strength this dense surface layer was shown to act as a
largely steric barrier for further penetration of compounds into the gel core. Small peptides, however, distributed evenly
throughout the microgel particles and were able to create large microgel volume reductions. The deswelling of
microgels increased with decreasing pH, while the uptake of pLys was significantly reduced at low pH. The effect
of ionic strength on the interactions of pLys and oppositely charged pAA microgels was moderate and only pronounced
for deswelling of gels at high pH. A significant increase in the α-helix content of pLys interacting with the oppositely
charged microgels was observed for high molecular weight peptides, and the extent of α-helix formation was as
expected more pronounced at high pH, i.e., at high charge density of the microgels but reduced charge density of the
peptides.
Functionalization of biomaterials with biologically active peptides can improve their performance after implantation. By genetic fusion to self-assembling proteins, the functional peptides can easily be presented on different physical formats. Herein, a chemical-free coating method based on self-assembly of the recombinant spider silk protein 4RepCT is described and used to prepare functional coatings on various biomaterial surfaces. The silk assembly was studied in real-time, revealing the occurrence of continuous assembly of silk proteins onto surfaces and the formation of nanofibrillar structures. The adsorbed amounts and viscoelastic properties were evaluated, and the coatings were shown to be stable against wash with hydrogen chloride, sodium hydroxide, and ethanol. Titanium, stainless steel, and hydroxyapatite were coated with silk fused to an antimicrobial peptide or a motif from fibronectin. Human primary cells cultured on the functional silk coatings show good cell viability and proliferation, implying the potential to improve implant performance and acceptance by the body.
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