posted on 2020-09-29, 09:29authored byKai Tao, Bin Xue, Shuyi Han, Ruth Aizen, Linda J. W. Shimon, Zhengyu Xu, Yi Cao, Deqing Mei, Wei Wang, Ehud Gazit
Framework
materials have shown promising potential in various biological
applications. However, the state-of-the-art components show low biocompatibility
or mechanical instability, or cannot integrate both optics and electronics,
thus severely limiting their extensive applications in biological
systems. Herein, we demonstrate that amide-based bioorganic building
blocks, including dipeptides and dipeptide nucleic acids, can self-assemble
into hydrogen-bonded suprahelix architectures of controllable handedness,
which then form suprahelical frameworks with diverse cavities. Especially,
the cavities can be tuned to be hydrophilic or hydrophobic, and the
shortest diagonal distance can be modulated from 0.5 to 1.8 nm, with
the volume proportion in the unit cell changing from 5 to 60%. Furthermore,
the hydrogen bonding networks result in high mechanical rigidity and
semiconductively optoelectronic properties, which allow the utilization
of the suprahelical frameworks as supramolecular scaffolds for artificial
photosynthesis. Our findings reveal amide-based suprahelix architectures
acting as bioinspired supramolecular frameworks, thus extending the
constituents portfolio and increasing the feasibility of using framework
materials for biological applications.