Articles in 2022

The hydrohalogenation of alkenes generally forms branched alkyl halides. Now, a palladium-catalysed method has been developed for the remote hydrohalogenation of internal and terminal alkenes, enabling the efficient synthesis of linear alkyl halides. The method uses an engineered Pyox ligand with a hydroxy group, which is essential for accelerating the oxidative halogenation.

Borophene, a two-dimensional boron sheet, can adopt a variety of polymorphic structures that are predicted to possess interesting and potentially useful electronic properties. Micrometre-scale single-crystal borophene domains have now been grown on a square-lattice Cu(100) surface. The resulting boron sheets feature a rectangular unit cell, intrinsic stripe modulations and an unusual electron band structure.

Aryl aminooxetanes are used as amide bioisosteres in drug discovery but there are limited strategies for synthesizing them. Now, an approach has been developed that simplifies the synthesis of these privileged motifs, enabling a broad range of amines to be used.

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.

Sulfonyl fluorides typically react with nucleophiles exclusively at sulfur, leading to the substitution of fluoride, as is the case in SuFEx reactions. Now, an alternative defluorosulfonylative reaction has been developed, coupling 3-aryloxetane sulfonyl fluorides with amines to generate amino-oxetanes. The mild conditions and high functional group tolerance enable the preparation of oxetane analogues of benzamide drugs via oxetane carbocation intermediates.

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.

John Woodland and Kelly Chibale retrace the tumultuous history of quinine from a medicine — used as a tool for colonialism — to a puzzling chemical target, a fluorescence standard and a key ingredient in popular drinks.

Histone H1 binds to nucleosomes with ultrahigh affinity, implying residence times incompatible with efficient biological regulation. Now it has been shown that the disordered regions of H1 retain their large-amplitude dynamics on the nucleosome, which enables a charged disordered histone chaperone to invade the H1–nucleosome complex and vastly accelerate H1 dissociation.

In photosynthesis, photoenergy transfers through chromophore-containing proteins, which exhibit thermal fluctuations that change the positions of the chromophores. Now the ultrafast dynamics in allophycocyanin—a cyanobacterial light-harvesting protein—have been measured using single-molecule pump–probe spectroscopy. The data show that energy transfer precedes protein-induced photophysical heterogeneity, ensuring that light harvesting is robust to the heterogeneity.

It is extremely difficult to design a broad-spectrum inhibitor for metallo-β-lactamases (MBLs) due to the diversity in the active site. Now, indole-2-carboxylates have been developed as broad-spectrum inhibitors for MBLs. These inhibitors take advantage of key elements of both MBL substrates and products and work by locking a hydroxide.

Direct coupling methods, which do not require substrate prefunctionalization, are highly desirable for the construction of complex molecular scaffolds. Now, a photochemical method has been developed for the direct decarboxylative coupling of carboxylic acids with diverse nitrogen, oxygen and carbon nucleophiles, taking advantage of the photochemistry of copper(II) carboxylate complexes assembled in situ.