Volume 11 Issue 11, November 2019

Nucleophiles directly substitute alcohols in the Mitsunobu reaction, but the process uses hazardous materials and generates an excessive amount of toxic waste. More than 50 years on from its initial discovery, chemists report a new catalytic version of the reaction, with water as the only by-product.

Although transporting a starship crewmember onto the surface of an alien planet is clearly science fiction, quantum state teleportation is not, and has been observed in various systems over the last few decades. Now, electron-spin teleportation has been observed in a carefully designed molecular system, paving the way for such behaviour to be tailored through molecular engineering.

The in situ, nanoscale positioning of a single molecule below the diffraction limit remains a challenge for chemists. Now, two approaches show how this can be accomplished through a combination of super-resolution microscopy and photo-inducible crosslinking chemistry.

The complete biosynthesis of the fungal indole alkaloid malbrancheamide, which culminates in an intramolecular [4+2] hetero-Diels–Alder cyclization to produce the bicyclo[2.2.2]diazaoctane scaffold, has now been discovered. Chemical synthesis and protein structural analysis were used to provide mechanistic insight into this enzyme-dependent diastereo- and enantioselective cycloaddition.

Quantum teleportation moves the quantum state of a system between physical locations without losing its coherence, an essential criterion for emerging quantum information applications. Now, electron-spin-state teleportation in covalent organic electron donor–acceptor–stable radical molecules is demonstrated using entangled electron spins produced by photo-induced electron transfer.

Stereoselective functionalization of C(sp³)–H bonds could greatly simplify the construction of complex molecular scaffolds. Now, a series of enzyme catalysts derived from a cytochrome P450 have been developed using directed evolution. The catalysts enable the enantioselective amination of primary, secondary and tertiary C(sp³)–H bonds.

It is difficult to prepare 2D polymers that are crystalline over large areas. Now, few-layer 2D polyimides and polyamides with good crystallinity on the micrometre scale have been synthesized on a water surface. A surfactant monolayer is used to organize amine monomers before their polymerization with anhydride moieties.

Super-resolution microscopy has enabled optical imaging of individual biomolecules on the nanometre scale. Now, a new method has been developed that allows active manipulation of single-molecule targets on visualization in a sequential manner. This method, called ‘Action-PAINT’, combines real-time super-resolution microscopy (DNA-PAINT) and photoinducible crosslinking chemistry to deliver a single-molecule cargo with <30 nm selectivity.

The emergence of pristine RNA and DNA on the early Earth would have been hindered by a lack of specificity in their prebiotic syntheses. Now, it has been shown that chimeric sequences—with a mixture of RNA and DNA backbones—mediate the template-directed ligation of oligomers present in mixtures of nucleic acids, enabling the simultaneous appearance of RNA and DNA.

The four-coordinate iron sites of typical iron–sulfur clusters rarely react with small molecules, implicating three-coordinate iron in many catalytic cycles. Now, a [4Fe-3S] cluster featuring three-coordinate iron sulfide that resembles the proposed substrate binding site has been synthesized. This cluster shows biomimetic reactivity with a low-spin electronic configuration.

The electronic structures of the metal cofactors of nitrogenase are key to biological nitrogen fixation; however, the [Fe₈S₇] P-cluster and FeMo cofactor have eluded detailed electronic characterization. Now, the electronic structure of the P-cluster of nitrogenase has been revealed at the many-electron level through exhaustive quantum wavefunction simulations.

Tuning the selectivity for [2+2] photocycloadditions remains challenging. Now, triplet–triplet energy transfer from CdSe quantum dots enables the homo- and heterocouplings of 4-vinylbenzoic acid derivatives via [2+2] photocycloaddition. Preorganization of substrates on the quantum dots reverses intrinsic stereoelectronic preferences to yield cyclobutane products with unprecedented diastereo- and regioselectivity.

Current photodynamic therapy photosensitizers require oxygen; however, tumours are often hypoxic. Now, an organoiridium complex with an unusually high redox potential, which is effective in normoxia and hypoxia, has been developed. The organoiridium complex kills cancer cells by an immunogenic apoptotic mechanism involving efficient photocatalytic oxidation of NADH to NAD radicals, and reduction of cytochrome c.

The UbiD family of reversible decarboxylases interconvert propenoic or aromatic acids with the corresponding alkenes or aromatic compounds, using a transient 1,3-dipolar cycloaddition between the substrate and the prenylated flavin mononucleotide cofactor. Atomic-resolution crystallography shows targeted destabilization of the intermediate covalent adducts, allowing the enzyme to harness 1,3-dipolar cycloaddition as a readily reversible reaction.

Understanding how structural dynamics contribute to protein function is a longstanding challenge in structural biology. Now, time-resolved X-ray solution scattering following an infrared laser-induced temperature jump has been used to probe functional, intramolecular motions in the dynamic enzyme cyclophilin A.