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Photosynthesis starts when light is absorbed and the associated excitation energy is directed to reaction centres by antenna complexes. The principles learned from studying these complexes are described in this Review, and provide the framework from which the authors suggest how to elucidate strategies for designing light-harvesting systems that route the flow of energy in sophisticated ways.
Peptide macrocycles have a number of important applications. Among other things, the reduced conformational freedom of the cyclic structure enables strong binding to the extended contact regions of protein–protein complexes. Here, emerging methods directed towards the synthesis of these valuable molecules are reviewed.
Crystalline networks containing empty cavities can host a variety of molecules but also promote reactions between guests. Through robust crystallinity and a pseudo-solution state (dynamic movements) within their pores, these crystalline molecular flasks enable the direct observation of species — including unstable intermediates — during a reaction by in situ X-ray diffraction.
The programmable and reliable hybridization of DNA strands has enabled the preparation of a wide variety of structures. This Review discusses how, in addition to these static assemblies, the process of displacing — and ultimately replacing — strands also makes possible the construction of dynamic systems such as logic gates or autonomous walkers.