"Click" Immobilization on Alkylated Silicon Substrates: Model for the Study of Surface Bound Antimicrobial Peptides

We describe an effective approach for the covalent immobilization of antimicrobial peptides (AMPs) to bioinert substrates via CuI‐catalyzed azide–alkyne cycloaddition (CuAAC). The bioinert substrates were prepared by surface hydrosilylation of oligo(ethylene glycol) (OEG) terminated alkenes on hydrogen‐terminated silicon surfaces. To render the OEG monolayers “clickable”, mixed monolayers were prepared using OEG‐alkenes with and without a terminal alkyne protected by a trimethylgermanyl (TMG) group. The mixed monolayers were characterized by X‐ray photoelectron spectroscopy (XPS), elliposometry and contact angle measurement. The TMG protecting group can be readily removed to yield a free terminal alkyne by catalytic amounts of CuI in an aqueous media. This step can then be combined with the subsequent CuAAC reaction. Thus, the immobilization of an azide modified AMP (N3‐IG‐25) was achieved in a one‐pot deprotection/coupling reaction. Varying the ratio of the two alkenes in the deposition mixture allowed for control over the density of the alkynyl groups in the mixed monolayer, and subsequently the coverage of the AMPs on the monolayer. These samples allowed for study of the dependence of antimicrobial activities on the AMP density. The results show that a relative low coverage of AMPs (∼1.6×1013 molecule per cm2) is sufficient to significantly suppress the viability of Pseudomonas aeruginosa, while the surface presenting the highest density of AMPs (∼2.8×1013 molecule per cm2) is still cyto‐compatible. The remarkable antibacterial activity is attributed to the long and flexible linker and the site‐specific “click” immobilization, which may facilitate the covalently attached peptides to interact with and disrupt the bacterial membranes. Clicky peptides: Through a combined deprotection/“click” reaction, azido‐labeled antimicrobial peptides were site‐specifically tethered onto bioinert monolayer platforms presenting various densities of trimethylgermanyl‐protected alkynyl groups. The immobilized peptides (see figure) exhibited a remarkable antibacterial activity when their density was above ≈1.6×1013 cm2, while remaining cyto‐compatible to mammalian cells.