Thank you for visiting nature.com. You are using a browser version with limited support for CSS. To obtain
the best experience, we recommend you use a more up to date browser (or turn off compatibility mode in
Internet Explorer). In the meantime, to ensure continued support, we are displaying the site without styles
and JavaScript.
Jane Liao and Allie C. Obermeyer explore the discovery, modification and applications of green fluorescent protein, best known for its use as a tool to cast light on cellular processes.
Does the pursuit of scientific research based on a well-defined technological outcome hamper our ability to be creative? And does it limit opportunities to explore and develop fundamental areas of science that may ultimately lead to applications we hadn’t even thought of yet?
Water-soluble, cell-permeable, inert fluorescent tags called OregonFluors have been developed to withstand environmental changes while resistant towards non-specific binding with subcellular structures. These tags enable quantitative imaging of drug target availability in cells and tissues, providing a route for the future assessment of personalized therapies.
Therapies that destroy senescent cells could be used to alleviate age-related disease, yet conventional drugs often suffer from low selectivity and unwanted side effects. Now, a photosensitive agent has been developed that is activated in situ in senescent cells, enabling their selective elimination.
Borylated bicyclopentanes and bicyclohexanes are valuable compounds in drug research but are difficult to prepare. Now, an iridium-catalysed method has been developed for the borylation of the bridgehead tertiary C–H bonds in bicyclopentanes and bicyclohexanes, providing access to a variety of highly decorated bicyclic cores.
Californium is difficult to prepare in its divalent state. Now, crystals of a Cf(II) crown–ether complex have been synthesized by reduction of a Cf(III) precursor with an Al/Hg amalgam. They exhibit 5f→6d transitions in the visible region and near-infrared emission that are highly sensitive to changes in the coordination environment.
In contrast to phosphine and arsine oxides, stibine oxides have been challenging to isolate in monomeric forms as they tend to polymerize. Now, such a SbO moiety has been kinetically stabilized using sterically bulky protecting groups, and its reactivity found to be substantially different to that of its lighter pnictogen counterparts.
Quasicrystals are intriguing structures that exhibit long-range positional correlations but no periodicity in real space. Now, T-shaped amphiphilic molecules featuring rigid cores have been found to self-assemble into a columnar liquid quasicrystal with dodecagonal symmetry. The honeycomb structure observed arises from a strictly quasiperiodic tessellation of square, triangular and trapezoidal tiles, rather than from random tiling.
Photochemical reduction of CO2 is a significant challenge and many existing methods use catalysts containing rare metals. Now a metal-free version of this reaction—with high selectivity for formate generation over H2 or CO—has been achieved that features a combination of carbazole photosensitizer and organohydride catalyst.
Charge-transfer emission of any type is extremely rare for coordination complexes of iron. Now, an Fe(iii) complex has been devised that shows two-colour luminescence arising from dual metal-to-ligand and ligand-to-metal charge-transfer emission.
The structural analysis of small crystals has remained challenging. Now, the structure of a small organic molecule, rhodamine-6G, has been resolved from microcrystals using an X-ray free-electron laser and electron diffraction. The former showed better reliability for atomic coordinates, whereas the latter was more sensitive to charges; both techniques accurately determined the position of hydrogen atoms.
Crystals of hexachlorobenzene have now been shown to support the autonomous motion of water and particulate matter over their surface. Parallel microchannels present at the surface of the crystal gradually widen by sublimation, propelling droplets of condensed ambient water that can also transport microscopic amounts of material such as silver microparticles.
Stereogenic sp3-hybridized carbon centres are the principal building blocks of chiral organic molecules. Usually, these centres are configurationally fixed. Now, low-energy pericyclic rearrangements have been used to create rigid cage molecules with fluxional sp3-stereochemistry, influencing chiral information transfer. The sp3-carbon stereochemistry of the cages is inverted through strain-assisted Cope rearrangements.
The molybdenum nitrogenase catalytic cofactor is composed of seven high-spin Fe sites making it difficult to study spectroscopically. Now it has been shown that 57Fe can be incorporated into a single site and that such site-selectively labelled samples provide insights into the cofactor’s electronic structure and the mechanism of biological nitrogen fixation.
Serial rotation electron diffraction (SerialRED) enables rapid and reliable phase analysis and structure determination of complex polycrystalline materials that cannot be routinely characterized using X-ray diffraction. Five zeolite phases were identified in a single synthesis product by automated screening of hundreds of crystals, demonstrating the power of SerialRED for materials development.
The controlled functionalization of multihydrosilanes is challenging. Now, using a hydrogen-atom-transfer photocatalyst based on neutral eosin Y, a method for the diverse functionalization of hydrosilanes has been developed, enabling the stepwise on-demand decoration of silicon atoms. This approach is distinguished by its atom-, step-, redox- and catalyst-economy, metal-free nature, its versatility (>150 examples), modularity, selectivity and scalability.
The alkaloids crocagins are derived from a ribosomal peptide through a series of enzymatic post-translational modifications. A combination of biochemistry and structural biology techniques has now been used to elucidate this biosynthetic pathway, propose a mechanism for the formation of the tetracyclic core structure and enable genome mining for related natural products.
Nanomachines are central to life and are becoming an important part of self-regulated nanotechnologies. Inspired by natural self-assembled nanosystems, it has been shown that artificial nanosystems can evolve and adopt regulatory functions upon fragmentation of their structures into multiple components that reassemble to form the same nanostructure.
