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Although surface-bound molecular catalysts offer well-defined active sites on heterogeneous supports, it is challenging to identify key radical intermediates in the reaction mechanism. Now, a characterization method has been developed that combines film electrochemistry and EPR spectroscopy to track radical intermediates in real time, exemplified by alcohol oxidation with a surface-immobilized nitroxide.
The mechanism for the oxidative addition of aryl halides to nickel(0)–phosphine complexes was proposed over four decades ago. Now, this elementary reaction, which occurs during common cross-coupling reactions, has been re-examined. Both one- and two-electron pathways occur, and their relative contribution depends on the electronic properties of the reaction partners.
Chirality is an intrinsic property in unsymmetric three-dimensional molecular assembly, contributing to the utility of the corresponding process and the resulting scaffolds. Now, on the sulfur(VI) hub, a three-step sequential ligand-exchange method has been established with precise stereocontrol, enabling the enantioselective synthesis of optically active S(VI) functional molecules.
The use of biocatalysis to support early-stage drug discovery campaigns remains largely untapped. Here, engineered biocatalysts enable the synthesis of sp3-rich polycyclic compounds through an intramolecular cyclopropanation of benzothiophenes, affording a class of complex scaffolds potentially useful for fragment-based drug discovery campaigns.
Very few charge-neutral synthetic anion receptors can function in water, and those known typically select weakly hydrated anions such as iodide. Now a neutral molecular cage capable of donating 12 hydrogen bonds has been synthesized and found to bind highly hydrated sulfate in water with a strong selectivity over weakly hydrated anions.
A protein-templated selection approach has been developed for the discovery of full ligands from dual-pharmacophore DNA-encoded libraries by incorporating fragment linking into the selection process. The performance of this method was demonstrated with selections against protein–protein interaction and protein–DNA interaction targets, through which potent and selective inhibitors were identified.
Achieving selectivity control in allylic arylations is a long-standing challenge in catalysis. Now a rhodium-catalysed system demonstrates chemo-, regio- and enantioselectivity, enabling Suzuki–Miyaura-type arylation with racemic, non-symmetrical, acyclic allylic systems; chelation is speculated to facilitate oxidative addition and enable both enantiomers of the starting material to converge onto a single product.
Switching the magnetic state of a polycyclic conjugated hydrocarbon in a reversible and controlled manner is challenging. Now, by means of single-molecule scanning probe microscopy, an indenofluorene isomer on ultrathin NaCl films has been shown to adopt both open- and closed-shell states. Furthermore, bidirectional switching between the two states is achieved by changing the adsorption site of the molecule.
The design of highly oxidizing Earth-abundant transition metal complexes for photochemical applications is desirable, but progress in this area remains limited. Now a manganese(IV) diguanidylpyridine complex has been shown to photooxidize naphthalene, benzene and acetonitrile to their radical cations after excitation with near-infrared light. Experimental and theoretical studies indicate the presence of two distinct ligand-to-metal charge transfer excited states.
Dual-pharmacophore DNA-encoded chemical libraries enable the identification of two synergistic binders for a biological target, but subsequent linking of this pair is required to obtain a full ligand, which can be challenging. Here we report a protein-templated selection of DNA-encoded dynamic library that can identify full ligands from fragment libraries without the need for subsequent fragment linking.
The human ATP-hydrolysing enzyme p97 populates a metastable reaction intermediate, the ADP·Pi state, which is poised between hydrolysis and product release. Now, molecular motions at the active site in the temporal window immediately before and after ATP hydrolysis have been elucidated by merging cryo-EM, NMR spectroscopy and molecular dynamics simulations.
Thomas Kruse and Søren Østergaard reflect on the development of the GLP-1 analogue, semaglutide, which is reshaping peptide therapeutics in type 2 diabetes, weight management, and beyond.
Although hydrogen gas could serve as a promising future fuel, its high-capacity storage is a challenge. Now, a nanoporous magnesium borohydride framework is shown to store hydrogen as densely packed penta-dihydrogen clusters having well-defined orientations and directional interactions with the framework.
Chromophore supramolecular assemblies have long been studied for their exotic photophysical properties arising from their local geometry and long-range sensitive excitonic couplings. Now a high-resolution structure of a model nanotubular system has revealed a uniform brick-layer molecular arrangement and a non-biological supramolecular motif—interlocking sulfonates—enabling clear understanding of supramolecular structure–excitonic property relationships.
Cells spatially organize biochemical reactions within membrane-bound and membraneless compartments. The extent to which intrinsically disordered proteins themselves can form discrete compartments or condensed phases is poorly understood. Now a pair of model IDRs that display orthogonality in condensation and the chain features governing selective assembly have been identified.
Light-induced ultrafast switching between the molecular isomers norbornadiene and quadricyclane can reversibly store and release a substantial amount of chemical energy. Two competing pathways have now been identified by which electronically excited quadricyclane molecules relax to the electronic ground state, facilitating interconversion between the two isomers on different timescales.
Dinitrogen (N2) fixation to ammonia (NH3) is typically challenging under mild conditions. Now, lithium hydride (LiH) is shown to mediate photodriven N2 fixation under ambient conditions. Under ultraviolet illumination, LiH is photolysed to release H2, leaving electrons residing in surface hydrogen vacancies, which facilitate N2 activation and photocatalytic NH3 synthesis.
Complexes of iron in high oxidation states play a pivotal role as active intermediates in numerous catalytic processes. Now, using a multimethod approach on a single molecular system, it has been shown that a stable high-valent Fe(VI) nitride can be converted to a reactive, superoxidized, heptavalent Fe(VII) nitride.
While saturated N-heterocycles are widespread motifs in drug discovery, the seven-membered ring azepane is highly underrepresented. Now nitroarenes have been validated as competent substrates for azepane synthesis through conversion into singlet nitrenes for ring enlargement via N insertion and hydrogenolysis. This enables a highly versatile access towards polysubstituted azepanes in just two steps.
