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Understanding and controlling the rate at which electrons are transferred across solid–liquid interfaces is critical to developing efficient processes for the interconversion of electrical and chemical energy. Now, Bediako and colleagues have shown that the interfacial electrochemical kinetics of two stacked layers of graphene can be modified by varying the ‘twist’ angle between them, with the greatest enhancement observed near the ‘magic angle’ (~1.1°). The cover depicts an artistic representation of electron transfer from twisted bilayer graphene to Ru(NH3)63+ — the redox-active molecule used in these studies.
Athina Anastasaki from ETH Zürich talks to Nature Chemistry about her career, her research in polymer chemistry and the challenges she dealt with in her academic pathway.
Miao Hong, based at the Shanghai Institute of Organic Chemistry, tells Nature Chemistry about her work in sustainable polymer design and her thoughts about the future of this field.
Plastics that are developed from renewable resources and can be recycled are highly environmentally desirable alternatives to current petroleum-based non-degradable polymers. Now, an effective and robust industrially relevant strategy towards high-performance biomass-derived degradable poly(γ-thiobutyrolactone)s has been developed.
Combining computational design with directed evolution has the potential to deliver enzymes with new functions, yet so far de novo catalysts have been limited to a handful of model transformations. Now, a primitive computationally designed enzyme has been remodelled into an efficient enantioselective catalyst for the Morita–Baylis–Hillman reaction.
The electronic structure of an electrode can affect the electron transfer rate of electrochemical processes at its surface. Now, it has been shown that varying the ‘twist’ angle between two stacked layers of graphene modifies the bilayer electronic structure and provides a new dimension to control interfacial redox activity.
Peptides are a class of versatile biomolecules that function as hormones, signalling messengers and drugs. Now, two papers report alternative approaches to tailor their chemical properties, which enables the transport of biomacromolecules into cells. These approaches could find use in a wide range of biomedical applications.
Viruses use the cellular machinery of their host organism to reproduce. This Review discusses how [FeS] cluster-containing proteins activate, support and modulate the innate immune response to restrict viral infections as well as highlighting how some of these proteins simultaneously support the replication of viruses.
Controlling the crystallographic registry of layered materials through interlayer twist angles has introduced a distinctive degree of freedom for tuning their electronic behaviour. Now, the interfacial electrochemical kinetics of solution-phase redox complexes at twisted bilayer graphene electrodes have been modulated by the angle-dependent tuning of moiré-derived flat bands.
Coacervate microdroplets formed from pH- and redox-responsive peptides and self-assembled by liquid–liquid phase separation have been shown to quickly recruit macromolecular therapeutics—such as peptides, large proteins and mRNAs—and directly enter the cytosol of cells via a non-endocytic pathway. The subsequent release of therapeutic cargo is mediated by endogenic glutathione.
Reliable intracellular delivery of antibodies is one of the grand challenges in biomedical research, with the potential to address unmet clinical needs or to enable basic research. Now, it has been shown that tricyclic peptide complexes can transport functional antibodies into the cytoplasm and nucleus of cells to specifically target intracellular proteins.
Five-membered lactones are common in nature and are produced in large quantities from biomass, but a lack of ring strain means that ring-opening polymerization is usually thermodynamically unfavourable at ambient conditions. Now, an irreversible ring-opening polymerization of biomass-derived five-membered thionolactones—driven by S/O isomerization—has been developed, enabling their conversion into sustainable polymers at industrially relevant temperatures.
Synthetic approaches that can simultaneously control both polymer sequence and dispersity are difficult to achieve. Now, a switchable RAFT agent that regulates chain transfer activity during controlled radical polymerization has been shown to enable the one-pot synthesis of sequence-controlled multiblocks with on-demand control over dispersity while maintaining high livingness.
Directed evolution of a primitive computationally designed enzyme has produced an efficient and enantioselective biocatalyst for the Morita–Baylis–Hillman reaction. The engineered enzyme uses a designed histidine nucleophile operating in synergy with a catalytic arginine that emerged during evolution and serves as a genetically encoded surrogate of privileged bidentate hydrogen-bonding catalysts.
Decoupling the processes of light harvesting and catalytic hydrogen evolution could be a potentially important step in storing solar energy. This has now been achieved with a single molecular unit: a light-harvesting ruthenium complex–polyoxometalate dyad that absorbs light, separates and stores charge and then generates hydrogen on demand following the addition of a proton donor.
Despite extensive investigations of mixed-valence complexes, molecules with intermediate spin states have remained elusive. Now, selenium- and tellurium-bridged mixed-valent iron dimers have been prepared in which a balance of Heisenberg exchange and double-exchange coupling of the unpaired electron, combined with moderate vibronic contributions, stabilizes S = 3/2 ground spin states.
A method for the selective deuteration of anilines, indoles, phenols and heterocyclic compounds, including natural products and other bioactive molecules, has been developed. The nanostructured iron catalyst that underpins this process is prepared by combining cellulose with iron salts and has been used for the preparation of deuterated compounds on up to a kilogram scale.
Neptunium was the first actinide to be artificially synthesized, yet its chemistry has remained relatively unexplored. Most neptunium chemistry involves the neptunyl di(oxo) motif, and transuranic compounds with only one metal–ligand multiple bond are generally rare. Now, a stable complex of neptunium in the +5 oxidation state has been isolated that features a single terminal Np–O multiple bond.
Threose nucleic acid (TNA) is a potential RNA evolutionary progenitor and a nuclease-resistant synthetic genetic polymer. Now, a TNA catalyst that cleaves RNA has been identified in vitro. The TNA catalyst shows strong sequence selectivity towards a mutant RNA substrate involved in drug resistance, resulting in selective gene silencing in eukaryotic cells.
Jennifer Rudd reflects on how, in recent history, carbon dioxide has been largely vilified for its role in global warming. Yet responsibility for the current climate crisis lies squarely with humans, not a molecule that is crucial for life on Earth.