ROS-Responsive Methionine-Containing Amphiphilic Peptides Impart Enzyme-Triggered Phase Transition and Antioxidant Cell Protection.

Reactive oxygen species (ROS) are produced by cellular activities, such as metabolism and immune response, and play important roles in cell signaling and homeostasis. However, overproduced ROS causes irreversible damage to nucleic acids and membrane lipids, supporting genetic mutations and enhancing the effects of aging. Cells defend themselves against ROS using antioxidant systems based on redox-active sulfur and transition metals. Inspired by such biological redox-responsive systems, we developed methionine-containing self-assembling peptides. The Met-containing peptides formed hydrogels that underwent a gel-to-sol phase transition upon oxidation by H2O2, and the sensitivity of the peptides to the oxidant increased as the number of Met residues increased. The peptide containing three Met residues, the largest number of Met residues in our series of designed peptides, showed the highest sensitivity to oxidation and detoxification to protect cells from ROS damage. In addition, this peptide underwent a phase transition in response to H2O2 produced by an oxidizing enzyme. This study demonstrates the design of a supramolecular biomaterial that is responsive to enzymatically generated ROS and can protect cells against oxidative stress.

ROS-Triggered Gel-Sol Transition and Kinetics-Controlled Cargo Release by Methionine-Containing Peptides.

The gel-sol transition of self-assembling peptides is a useful switch for environment-dependent drug release. For their applications, kinetics control of the responses is important for matching the velocity of release to the target biological events. Here we demonstrate the chemical control of redox-triggered gel-sol transition kinetics of self-assembling peptides by altering the amino acid sequence. Amphiphilic peptides were developed in which a methionine residue was located in the middle (JigSAP-IMI) or near the N terminus (JigSAP-MII). Both peptides formed hydrogels under physiological conditions-forming ß-sheet-based supramolecular nanofibers. In contrast, the oxidized forms remained in the solution state under identical conditions-adopting α-helix-rich secondary structures. Upon oxidation with H2 O2 , a reactive oxygen species, JigSAP-MII showed a faster gel-to-sol transition and cargo-releasing than JigSAP-IMI, thus indicating that the phase-transition and releasing kinetics of self-assembling peptides can be rationally controlled by the position of the reactive amino acid residue.