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X-ray diffraction analysis typically affords the static 3D structures of given compounds or materials, but to understand chemical processes, the visualization of fast structural changes is desirable. Time-resolved femtosecond crystallography has now been used to monitor the structural dynamics of a photoactive metal–organic framework.
The precision synthesis of cyclic polymers with ultrahigh molar mass (UHMM) and circularity is challenging. Now, a method that involves superbase-mediated living linear-chain growth followed by macromolecular cyclization triggered by protic quenching enables the on-demand production of UHMM cyclic polymers with a narrow dispersity and closed-loop chemical recyclability.
Chlorine-containing waste streams pose potential risks to human health and the environment, so their remediation represents a significant challenge. Now, chlorinated wastes have been successfully repurposed as chlorinating reagents for use in the preparation of organic chemicals and pharmaceutical ingredients.
Understanding the ways by which metal-containing catalysts carry out a reaction is a chemical puzzle. Now, investigations of a multi-metallic molecular system uncover how the self-assembly of molecular catalysts facilitates cooperation between active species and improves the conversion of water to hydrogen gas.
Natural protein folding takes place in aqueous cell environments. Now, it has been found that proteins in a water-free environment undergo faster and more efficient folding.
A non-radical proximity labelling platform — BAP-seq — is presented that uses subcellular-localized BS2 esterase to convert unreactive enol-based probes into highly reactive acid chlorides in situ to label nearby RNAs. When paired with click-handle-mediated enrichment and sequencing, this chemistry enables high-resolution spatial mapping of RNAs across subcellular compartments.
Surface heterogeneities lead to friction between droplets and solid surfaces, limiting the performance of the latter in a number of applications. A combination of friction force measurements and atomistic molecular dynamics simulations now sheds light on the influence of molecular scale heterogeneities on droplet friction.
Ether-based electrolytes are desired for lithium metal batteries owing to their low reduction potentials; however, they suffer from low anodic stability. Strategic methylation of ether solvents is shown to extend their electrochemical stability and facilitate the formation of LiF-rich interphases, enabling high-voltage lithium metal batteries while avoiding the use of fluorinated solvents.
Biological and synthetic catalysts often utilize iron in high oxidation states (+IV and greater) to perform challenging molecular transformations. A coordination complex featuring an Fe(VII) ion has now been synthesized through sequential oxidations of nonheme iron–nitrido precursors.
Lack of standardization, transparency and interaction creates information gaps in scientific publications. Through strategies such as voluntary information management, standardization of reaction set-ups, and smart screening approaches, this Perspective gives guidelines on how to improve data management in publications reporting chemical reactions, focusing on reproducibility, standardization and evaluation of synthetic transformations.
Chiral amines possessing a stereogenic carbon atom bearing three carbon substituents and one nitrogen substituent are challenging structural motifs to prepare enantioselectively. Now, such motifs have been accessed in high enantiopurities by asymmetric Cu-catalysed propargylic amination using sterically confined ligands.
Expansion of the genetic code can enable precise manipulation of proteins through selective functionalization of specific residues. Now, control of tryptophan interactions in proteins can be established by encoding of a vinyl-caged tryptophan analogue that can be selectively decaged to rescue protein activity.
We developed a high-throughput, unbiased strategy for the identification of endogenous biomolecular condensates by merging cell volume compression, sucrose density gradient centrifugation and quantitative mass spectrometry. We demonstrated the performance of this strategy by identifying both global condensate proteins and those responding to specific biological processes on a proteome-wide scale.
Nanopore label-free sequencing of DNA and RNA at the single-molecule level offers rapid readout, high accuracy, low cost and portability. This Review surveys technologies underpinning commercial and academic nanopore sequencing, and examines how underlying biochemical advances can fuel future developments in nanopore-based protein sequencing.
Single-particle cryo-electron microscopy and all-atom molecular dynamics simulations provide atomic details of ATP hydrolysis in the multimeric enzyme p97.
Although generally perceived as an old-fashioned and unselective tool to build molecules, the photochemistry community is now re-discovering the power of UV light and is using key mechanistic information to develop new catalytic processes driven by visible light. This Perspective discusses the progress and impact of UV light in organic synthesis.
Electrocatalytic transformations often involve the concerted transfer of electrons and protons at electrode interfaces; however, these processes are not well understood. Now, experiments on an electrode that features well-defined molecular sites deepen fundamental understanding of such transfers to pave the way for future catalysts.
A method for carbon isotope exchange involving a metal-catalysed metathesis reaction of in situ formed acyl chlorides is demonstrated. The platform provides access to 13C- or 14C-enriched carboxylic acids, including natural products and pharmaceuticals, without the need for radioactive gases, using a single carboxylic acid carbon donor.
Replicating the ability of enzymes and transport proteins to effectively bind anions is a considerable challenge for supramolecular chemists. A neutral organic cage has now been developed that selectively binds sulfate anions in water.
Covalent protein conjugation facilitates the study of biological processes and the synthesis of therapeutic biomacromolecules. A method that uses vinyl thianthrenium reagents for the site-selective formation of highly reactive episulfonium species on proteins is demonstrated. These in situ-formed intermediates react with diverse nucleophiles, providing access to protein conjugates in one step without purification.