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Protein translation is the ultimate paradigm for sequence-defined polymer synthesis. To introduce non-canonical monomers into the genetic code of living organisms, pairs of biomolecules known as aminoacyl-tRNA synthetases (aaRSs) and transfer RNAs (tRNAs) are required. The discovery and engineering of five such pairs, that do not interfere with each other or the aaRS–tRNA pairs of a bacterial host, sets the stage for highly modified genetically encoded biopolymers.
Low-coordinate lanthanide complexes with strong magnetic anisotropy could afford high-performance single-molecule magnets (SMMs) but are challenging to synthesize. Now, through ligand design, a near-linear pseudo-two-coordinate Yb(iii) complex that exhibits slow magnetic relaxation is reported. The complex has a large total splitting of the ground-state manifold, arising from the crystal field imposed by the ligands.
The atomically precise assembly of metal nanoparticles offers vast possibilities for materials chemistry. Ring-shaped polyoxometalates have now served to stabilize Ag30 nanoparticles with exposed surfaces.
Bioresponsive hyperpolarized probes contain magnetic resonance signals that can be many orders of magnitude larger than those of common, thermally polarized probes. This Perspective discusses how bioresponsive hyperpolarized probes can be directly linked to biological events to give functional information, enabling the mapping of physiological processes and diseases in real time using magnetic resonance.
Complexity is a hallmark of biological systems, but scientific experiments are typically conducted in simplified conditions. Now, diverse polymers that mimic the local environments of complex biological mixtures have been shown to improve protein folding, stability and function.
Constructing aptamers with desired target-binding affinities may lead to new applications but is challenging. Now, a new method using a high-dimensional microfluidic approach enables quantitative isolation of aptamers with programable binding affinities.
From humans designing machines, to machines designing biology, deep learning is turning the tables for assisted exploration of biologically active and diverse protein designs. Now, a deep-learning-based strategy has been used to design artificial enzymes that catalyse a light-emitting reaction.
Colloidal clathrate crystals self-assembled from hard polyhedral shapes in computer simulations are stabilized by entropy compartmentalization, whereby hosts and guests contribute unequally to the entropy. This creative solution to satisfying the laws of thermodynamics suggests new ways to make colloidal crystals with open cages and hierarchical host–guest structures.
Dipolar cycloadditions are excellent processes for generating heterocyclic systems from simple starting materials, but arenes as dipolarophiles have not been extensively explored. Now, the intramolecular dipolar cycloaddition of aromatic rings has been achieved using in situ generated diazoalkenes to produce bicyclic or tricyclic heterocycles.
Catenanes that are chiral owing to the relative orientation of their rings have always been referred to as ‘topologically chiral’. It is now shown that although in specific cases the stereochemistry is a topological property of the structure, the underlying stereogenic unit itself is not inherently topological in nature.
The ability to detect and quantify a given analyte at the molecular level is a long-lasting goal for analytical and bioanalytical chemistry. This Review highlights how single-molecule junctions (SMJs) have been used for analytical purposes, from the detection of isomers and reaction intermediates to the detection of proteins and nucleic acids. Different SMJ approaches are discussed, along with their advantages and limitations over bulk analytical techniques.
The chemistry of polynitrogens has been enriched by a new isomer of N6 through the synthesis, in a laser-heated diamond anvil cell, of a charged aromatic [N6]4– ring that is recoverable at ambient temperature under high pressure.
Monomeric stibine oxide has remained elusive due to the large antimony orbitals coupled with a high electronegativity difference with oxygen. Now, a free tris(2,6-diisopropylphenyl)stibine oxide has been isolated that can act as oxo-transfer reagent.
Systems that feature long-range order but no translational periodicity are intriguing. Now, a T-shaped molecule consisting of three non-miscible components has been devised that self-assembles into a columnar liquid quasicrystal.
Enantioenriched β-amino acid derivatives are attractive synthetic targets, considering the significance of these motifs in medicinal and material chemistry. Now, using ambiphilic ynamides as two-carbon synthons in a four-component reaction, three classes of β-amino amides with well-defined stereocentres can be accessed.
Plasmonic heating by nanoparticles has been used to promote a range of chemical reactions. Now, thermoplasmonic activation has been applied to latent ruthenium catalysts, enabling olefin metathesis initiated by visible and infrared light.
Therapies that destroy senescent cells could be used to alleviate age-related disease, yet conventional drugs often suffer from low selectivity and unwanted side effects. Now, a photosensitive agent has been developed that is activated in situ in senescent cells, enabling their selective elimination.
Charge-transfer emission of any type is extremely rare for coordination complexes of iron. Now, an Fe(iii) complex has been devised that shows two-colour luminescence arising from dual metal-to-ligand and ligand-to-metal charge-transfer emission.