Template-assisted Flexible-to-rigid Transition of Peptides in Head-to-tail Self-polymerization Enables Sequence-controllable and Post-modifiable Peptide Nanofibers.

ABSTRACT

Peptide-based nanofibers are promising materials for many essential applications and can be generalized into two categories, self-assembling peptide nanofibers (SAPNs) and poly(amino acid) nanofibers (PAANs). Non-covalent SAPNs are sequence-controllable, but poorly stable and not suitable for post-modification. While covalent PAANs are post-modifiable, however, their sequences are either monotonic or undefined. The nanofibers obtained by head-to-tail covalent coupling polymerization of sequence-known peptides, which we call series-connected peptide nanofibers (SCPNs), promise to have the advantages of both SAPNs and PAANs, but they are barely reported. The undesired backbiting effect during the head-to-tail polymerization is one of the possible challenges. Here, we present a template-assisted strategy to trigger the flexible-to-rigid transition of peptide units, which can avoid the backbiting effect and enable consecutive intermolecular polymerization of peptides to produce desired sequence-controlled covalent SCPNs. SCPNs are highly stable and can function as excellent parent materials for various post-processing to create diverse hierarchical materials independent of the peptide sequence. Moreover, SCPNs allow for the display of predetermined functional groups at regular intervals along the nanofibers by pre-modification of the initial peptide sequence. SCPNs represent a new category of peptide-based nanofibers with outstanding performances and vast potential.