posted on 2019-09-27, 18:44authored byQiao Song, Jie Yang, Stephen C. L. Hall, Pratik Gurnani, Sébastien Perrier
Cyclic peptide–polymer
conjugates are capable of self-assembling
into supramolecular polymeric nanotubes driven by the strong multiple
hydrogen bonding interactions between the cyclic peptides. In this
study, we have engineered responsive nanotubes by introducing a cleavable
bond that responds to a reductant utilizing pyridyl disulfide reaction
chemistry. Reactions between a cysteine containing cyclic peptide
(CP-SH) and pyridyl disulfide containing polymers were initially studied,
leading to the quantitative formation of cyclic peptide–polymer
conjugates. An asymmetric cyclic peptide–polymer conjugate
(PEG-CP-S-S-pPEGA) was then synthesized via orthogonal
pyridyl disulfide reaction chemistry and NHS coupling chemistry. The
disulfide linker formed by the pyridyl disulfide reaction chemistry
was then selectively reduced to thiols in the presence of a reductant,
enabling the transition of the conjugates from nonassembling unimers
to self-assembled supramolecular polymeric nanotubes. It is anticipated
that the pyridyl disulfide reaction chemistry will not only enrich
the methodology toward the synthesis of cyclic peptide–polymer
conjugates, but also lead to the construction of a new family of redox-responsive
cyclic peptide–polymer conjugates and supramolecular polymeric
nanotubes with tailored structures and functionalities.