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Synthesis of peptidyl-tRNAs is challenging because there are no enzymes that can directly attach the desired peptide to tRNA. Now it has been shown that a chemoenzymatic approach based on native chemical ligation can be used for the semi-synthesis of peptidyl-tRNAs for structural/biochemical studies of arrested and non-arrested ribosome complexes.
Peptide design remains a challenge owing to the large library of amino acids. Rational design approaches, although successful, result in a peptide design bias. Now it has been shown that AI techniques can be used to overcome such bias and discover unusual peptides as efficiently as humans.
Sit back and settle in for a tour of the chemical analysis instruments aboard the James Webb Space Telescope and the techniques being used to explore the planets beyond our Solar System.
Governments worldwide are committing more funding for scientific research in the face of the ongoing pandemic and climate crises. However, the funding process must be restructured to remove the barriers arising from conscious and unconscious biases experienced by minoritized groups, including women, and particularly women of colour.
Inverse vulcanization (IV) generates sulfur-rich functional polymers from elemental sulfur and organic crosslinkers, but the harsh reaction conditions required limit the scope of suitable crosslinkers. Now, a photoinduced IV has been shown to proceed at ambient temperatures, enabling the use of volatile and gaseous alkenes and alkynes as crosslinkers and broadening the range of products.
Hydrogen, which possesses the highest gravimetric energy density of any energy carrier, is attractive for both mobile and stationary power, but its low volumetric energy density poses major storage and transport challenges. This Perspective delineates potential use cases and defines the challenges facing the development of materials for efficient hydrogen storage.
The properties of chiral conjugated molecules, such as the absorption and/or emission of circularly polarized light or electron transport, are highly anisotropic. Now it has been shown that templating layers can control the orientation and anisotropic properties of small chiral molecules in bulk thin films useful for a range of emerging technologies.
Photoelectrochemical cells are hampered by electron–hole recombination. Now, supramolecular machinery has enabled the docking of macrocyclic electron-accepting redox mediators to a dye through pseudorotaxane formation. Upon electron transfer from the dye, the anionic redox-mediator rings are launched away from the surface, reducing charge recombination, establishing charge separation and improving the efficiency of the solar cells in which they feature.
Room-temperature phosphorescence in organic solids is attractive for practical applications but remains rare. Now, highly phosphorescent boroxine-linked covalent organic frameworks have been prepared by covalent doping with halogen atoms through the use of halogenated precursors. The resulting porous COFs exhibited oxygen-sensing capabilities with millisecond response time over a wide range of partial oxygen pressures.
Polymerization methods that control the cis/trans stereochemistry of repeating alkenes in polyalkenamers remain scarce. Now, an acyclic diene metathesis process has been developed that enables control over the stereochemistry of the polymer backbone. The method harnesses the reactivity of dithiolate Ru carbenes, in combination with cis,cis-diene monomers, to access several classes of polymers with tailored properties.
Quantum nanomagnets, which display collective quantum behaviours, serve as important components in modern quantum technologies, but their fabrication has remained challenging. Quantum nanomagnets have now been constructed spin by spin in metal-free porphyrin chains, using on-surface synthesis and hydrogen manipulation using a scanning tunnelling microscope, and their collective quantum behaviours have been clearly resolved.
Creating hierarchical synthetic materials that can modulate microbial communities remains a great challenge due to the complex interactions between microbiota and their colonized environments. Now, a soil-inspired chemical system that responds to chemical, optical and mechanical stimuli has been developed. The soil-inspired chemical system can enhance microbial cultures and biofuel production, enrich gut bacterial diversity and alleviate ulcerative colitis symptoms.
The rapid assembly of complex scaffolds in a single step from simple precursors would be an ideal reaction in terms of efficiency and sustainability. Now, the single-step construction of alkaloid-like frameworks from three dynamically assembled precursors has been reported. Using a dual-catalytic system, the transformation involves a hydride shuttle process initiated by a hydride donation event.
Meso–meso linked porphyrin arrays have been described as rod-like photonic wires. Now it has been shown that they can be bent into rings using template-directed synthesis. These rings of porphyrins mimic the light-harvesting arrays of chlorophyll molecules responsible for photosynthesis.
DNA nanotechnology and synthetic biology both aim to expand the range of dynamic behaviours exhibited by rationally programmed biomolecules. Now, the programmability of synthetic transcriptional circuits has been improved to enable synthesis of dynamic biomolecular circuits with unmatched complexity.
Sterically demanding 2′-modified nucleotides used in antisense therapeutics have thus far been challenging to synthesise enzymatically. Now, it has been shown that mutation of two gatekeeper residues in an archaeal DNA polymerase unlocks efficient synthesis of the modified nucleic acid oligomers 2′-O-methyl-RNA and 2′-O-(2-methoxyethyl)-RNA and enables the evolution of 2′-O-methyl-RNA enzymes.
Protein–carbohydrate interactions remain challenging to study due to their low binding affinity and non-covalent nature. Now, a genetically encoded bioreactive unnatural amino acid containing sulfonyl fluoride has been shown to crosslink a protein with its bound glycan, offering a solution to probe and exploit protein–carbohydrate interactions.
Technologies for profiling biological environments with high spatiotemporal resolution are in demand to enable the discovery of new targets for addressing unmet clinical needs. Now, a deep red light-mediated photocatalytic strategy for the targeted activation of aryl azides has been developed. This platform enables mapping of protein microenvironments in physiologically relevant systems.
