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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.
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.
Single-atom alloys have emerged as highly active and selective catalysts that do not follow the traditional models of heterogeneous catalysis. Now it has been shown that the binding of adsorbates at their surface abides by a simple 10-electron count rule, which can identify promising catalysts for various applications.
Metal-mediated self-assembly of organic building blocks is a powerful strategy to generate complex supramolecular objects. The non-statistical combination of multiple different components, however, has been a major challenge. Now integrative self-sorting of low-symmetry multicomponent cages has been achieved by combining shape complementarity and selective backbone interactions under thermodynamic control.
The stereochemical control and bifunctional manipulation of chiral sulfur functional groups is a long-standing challenge. Now, an enantiopure bench-stable S(VI) fluoride exchange reagent enables the asymmetric synthesis of sulfoximines, sulfonimidamides and sulfonimidoyl fluorides. The bifunctional nature of this reagent provides a practical method for the introduction of S(VI) functionality.
Skeletal editing enables diversification of compounds not possible by applying peripheral editing strategies. Now, a catalyst-free atom-pair swap strategy for pyridine editing has been developed via one-pot sequential dearomatization, cycloaddition and rearomative retrocyclization. Benzenes and naphthalenes with precisely installed functional groups are produced, and the mild conditions enable late-stage skeletal diversification of pyridine cores.
The lack of effective methods for mirror-image (d-) protein sequencing hampers the development of mirror-image biology systems and related applications. Now, total chemical synthesis of mirror-image trypsin enables the sequencing of long d-peptides and d-proteins, which may facilitate applications of d-peptides and d-proteins as potential therapeutic and informational tools.
Photon-driven dinitrogen reduction to ammonia is a promising but challenging reaction. Now it has been shown that lithium hydride undergoes photolysis upon ultraviolet illumination to yield long-lived photon-generated electrons residing in hydrogen vacancies, favouring the activation of the N≡N bond and achieving photocatalytic ammonia synthesis.
Although interfacial proton-coupled electron transfers are critical reaction steps in chemical and biological processes, studies investigating these reactions are complicated by surface heterogeneity. Now, interfacial proton-coupled electron transfer kinetics are studied and modelled at isolated, well-defined active sites to provide a foundation for understanding complex reactions involved in energy conversion and catalysis.
Single-electron-mediated difunctionalizations of internal olefins allow the simultaneous formation of two contiguous Csp3-stereocentres. Here, we describe enantioenriched arylsulfinylamides as all-in-one reagents for the efficient asymmetric, intermolecular aminoarylation of alkenes. Mechanistic studies revealed an interesting dichotomy in the initiation of the reaction depending on the olefin redox potential.
Single-step addition of an aryl ring and a protected amine across an alkene is a succinct route to valuable phenethylamine products, but existing methods suffer from limited scope. Now a family of compounds containing a sulfinamide functional group have been developed to react via electrophilic radicals to yield phenethylamines through an aryl migration with precise stereochemical control.
The synthesis, structure and reactivity of room-temperature-stable [Cp(C6F5)5]+[Sb3F16]− is presented. Coordination of the cyclopentadienyl cation by [Sb3F16]− or C6F6 stabilizes the antiaromatic singlet state in the solid state. Calculated hydride and fluoride ion affinities of the [Cp(C6F5)5]+ cation are higher than those of the tritylium cation [C(C6F5)3]+.
Photoinduced electron transfer forms the basis for photosynthesis and DNA repair. Ultrafast structural changes recorded for a DNA-repairing photolyase now reveal specific and directed protein motions accompanying the electron transfer.
The organization of electrolytes at the air/water interface affects the structure of interfacial water and therefore numerous natural processes. It has now been demonstrated that the surface of an electrolyte solution is stratified and consists of an ion-depleted outer surface and an ion-enriched subsurface layer, jointly determining the water interfacial structure.
The activation of dioxygen at metal centres, and subsequent functionalization of unactivated C‒H bonds, requires the generation of high-energy radical intermediates that often result in undesirable side reactions. Now an elusive oxygen-derived reactive iron(II)–radical intermediate is spectroscopically characterized as part of a strategy to stabilize phenoxyl radical cofactors during substrate oxidation reactions.
Selectivity of photochemical reactions is notoriously difficult to model. Now it has been shown that by employing an analogy to ground-state reactions with post-transition-state bifurcations, selectivity for a complex photochemical denitrogenation reaction can be captured and rationalized, and its dynamical origins understood.
Natural products discovery remains an ongoing challenge. Now, halide depletion offers a complementary approach to discover natural products whose biosynthesis requires halides, including products of cryptic halogenation. Halide depletion reveals that nostochlorosides, the products of an orphan biosynthetic gene cluster in Nostoc punctiforme, are polymerized by a halide-displacing etherifying enzyme.
Enantioselective transformations based on tetracoordinate borons are elusive. Now, an enantioselective nickel-catalysed strategy for the construction of axially chiral alkenes has been reported, via a 1,3-metallate shift of alkynyl tetracoordinate boron species. The reaction uses readily accessible starting materials and a cheap transition-metal catalyst, and the chemoselectivity, regioselectivity and atroposelectivity could be well controlled.