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Auxilliary Activity Family 5 (AA5) comprises mononuclear copper radical oxidases with catalytic diversity that is not well characterised. Here, structural, phylogenetic and biochemical analyses advance our understanding of the potential biological and biotechnology functions of these proteins.

One intriguing question about antimatter that is yet to be directly answered is whether or not it behaves exactly the same as matter under gravity. Here, a direct experimental method is presented to measure the ratio of inertial to gravitational mass for antihydrogen under free-fall conditions.

Genetic variants might exert their functional effects via influencing molecular interaction. Here, the authors present a resource featuring almost 28,000 annotations describing the effect of small sequence changes on physical protein interactions, curated by IMEx Consortium curators.

Water electrolysis provides a potential means to large-scale renewable fuel generation, although sluggish oxygen evolution kinetics challenges progress. Here, authors report on Ruddlesden–Popper oxides as active oxygen evolution electrocatalysts that provide impetus for overcoming kinetic barriers.

The impact of nitrogen availability on carbon sequestration in terrestrial ecosystems under climate change is understudied. Here the authors project that increases in N availability over the 21st century associated with warmer soils and the legacy of past N fertiliser use on abandoned croplands will be the primary drivers of a 21st century net carbon sink in Northern Eurasia.

In BaFe₂As₂, the lattice couples strongly to the magnetic and electronic degrees of freedom, providing a way to control them. Here, by means of time-resolved X-ray scattering, the authors measure rapid lattice oscillations, which can induce changes in the material’s electronic and magnetic properties.

Quantum communication requires quantum correlations between the information processing units and the information carrying units. Here, the authors use time-bin encoding and frequency downconversion to telecom wavelengths to achieve kilometre-scale spin-photon correlations.

Peptides have been known to be important therapeutics; however, minimizing purification steps, reagent expense, and reaction times in modern peptide coupling methods remains challenging. Here, the authors use sulfur(IV) fluorides as a coupling reagent, demonstrating the formation and capture of key acyl fluorosulfite intermediates for rapid peptide couplings, without epimerization or column chromatography for purification, achieving 40–94% yields for dipeptides and 24–57% yields for oligopeptide formation.

Animal experiments to study the detrimental health effects of sugar usually involve far higher doses than those consumed by humans. Here, Ruff et al.show that house mice consuming comparatively low amounts of added sugar are impaired in their ability to compete for territories, reproduce and survive in a seminatural environment.

Ice nucleating particles impact the global climate by altering cloud formation and properties, but the sources of these emissions are not completely characterized. Here, the authors show that secondary organic aerosols formed from the oxidation of organic gases in the atmosphere can be a source of ice nucleating particles.

It is unclear whether plant trait relationships found at the global scale extend to climatic extremes. Here the authors analyse six major aboveground traits to show that known plant trait relationships extend to the tundra biomes and exhibit the same two dimensions of variation detected at the global scale.

Determining—and defining—the size of an atomic nucleus is far from easy. First-principles calculations now provide accurate information on the neutron distribution of the neutron-rich ⁴⁸Ca nucleus—and constraints on the size of a neutron star.

Little is known about developmental set points of immune responses, especially in humans. Here the authors show that the metabolic state of monocytes isolated from prematurely born infants underlies attenuated responsiveness to fungal infection via selective control of protein translation.

Generating organized kidney tissues from human pluripotent stem cell is a major challenge. Here, Freedman et al. describe a differentiation system forming spheroids and tubular structures, characteristic of these kidney structures, and using CRISPR/Cas9, delete PKD1/2, to model polycystic kidney disease.

The ryanodine receptor (RyR) is a large multi-domain ion channel that functions to release calcium from the endoplasmic or sarcoplasmic reticulum. Here the authors present crystal structures of the SPRY1 and tandem repeat domains of RyR, allowing precise positioning of the domains and linking disease mutations to RyR function.

The magnitudes of replenishment and priming, two important but opposing fluxes in soil organic carbon (SOC) dynamics, have not been compared. Here the authors show that the magnitude of replenishment is greater than that of priming, resulting in a net SOC accumulation after additional carbon input to soils.

Extreme weather, rising seas and degraded coastal ecosystems all play a part in escalating the risks that coastal regions are exposed to. Now research into hazards facing the contiguous USA indicates that the likelihood and magnitude of losses can be reduced by intact reefs and coastal vegetation.

Previous work has identified several genes where mutations lead to breast cancer, but other genetic and environmental factors must still be accounted for. A large study of genetic association with breast cancer points to four novel genes and many more genetic markers that should be pursued for their link to cancer susceptibility.

Type 2 diabetes (T2D) is a heterogeneous disorder characterized by insulin resistance and impaired insulin secretion. Here Axelssonet al. show that Sox5, which is reduced in diabetes, regulates a set of differentially expressed genes in T2D and its genetic and pharmacological induction improves insulin secretion by diabetic islets.

Speciation reversal is known mainly from recently diverged lineages that have come into secondary contact following anthropogenic disturbance. Here, Kearns et al. use genomic and phylogenomic analyses to show that the Common Raven (Corvus corax) was formed by the ancient fusion of two non-sister lineages of ravens.

DNA is a useful molecule with which to construct nanomaterials with controllable functionalities. Here, the authors fabricate photonic wires by appending dye molecules at set positions along DNA structures, and show how FRET performance can be tuned by modifying dye separation.

In most unconventional superconductors, the superconducting phase is adjacent to a phase with some type of magnetic order. However, this is not a universal feature. For example, no magnetic order has so far been observed in Sr₂RuO₄. Now, low-energy muon relaxation experiments show the presence of a static magnetic order for this material, suggesting that this feature may in fact be universal.

In vivo existence of guanine-rich four-stranded RNA structures (G4-RNAs) has been a matter of debate. Here the authors developed a protocol, G4RP-seq, to capture and identify transcriptome-wide G4-RNA, providing insights into the formation of transient G4-RNA in live human cells.

Peridotite carbonation plays an important role in the carbon cycle. Here, the authors present a geophysical characterization of serpentinite carbonation from km to mm scale and confirm that the abundance of magnetic minerals provides a strong correlation with the overall carbonation reaction process.

The brain exists in a state of constant activity but little is known about very low frequency forms of activity. Here, the authors use high-speed, wide-field, voltage-sensitive dye imaging to investigate the presence and functional structure of infraslow spontaneous activity in anaesthetized and awake mouse cortex.

X-ray free-electron lasers, important light sources for materials research, suffer from shot-to-shot fluctuations that necessitate complex diagnostics. Here, the authors apply machine learning to accurately predict pulse properties, using parameters that can be acquired at high-repetition rates.

Understanding the interaction between nanoparticles and biomolecules is crucial for improving current drug-delivery systems. Here, the authors shed light on the essential role of the surface and other physicochemical properties of a library of nanoparticles on their in vivo pharmacokinetics.

Fundamental theories do not predict a difference between the properties of matter and antimatter, but experimental tests of this are still in their infancy. To this end, this study analyses the effects of electric fields on antihydrogen atoms in the ALPHA trap to place a bound on the charge of antihydrogen.

Doubly magic atomic nuclei — having a magic number of both protons and neutrons — are very stable. Now, experiments revealing unexpectedly large charge radii for a series of Ca isotopes put the doubly magic nature of the ⁵²Ca nucleus into question.

The marine nitrogen cycle was altered during the transition from glacial to interglacial conditions. An analysis of δ¹⁵N records throughout the world’s oceans suggests that rates of denitrification in the water column accelerated during the last deglaciation.

Diagnosis of lung cancer through manual histopathology evaluation is insufficient to predict patient survival. Here, the authors use computerized image processing to identify diagnostically relevant image features and use these features to distinguish lung cancer patients with different prognoses.

Many photo-induced processes such as photosynthesis occur in organic molecules, but their femtosecond excited-state dynamics are difficult to track. Here, the authors exploit the element and site selectivity of soft X-ray absorption to sensitively follow the ultrafast ππ*/nπ* electronic relaxation of hetero-organic molecules.

Understanding the location and nature of the catalytic active site is critical for controlling a catalyst’s activity and selectivity. Here, the authors separate the metal from the support by a controlled distance while maintaining the ability to promote defects via the use of carbon nanotube hydrogen highways.

An analysis of mutations from over 7,000 cancers of diverse origins reveals the diversity of mutational processes underlying the development of cancer; more than 20 distinct mutational signatures are described, some of which are present in many cancer types, notably a signature attributed to the APOBEC family of cytidine deaminases, whereas others are specific to individual tumour types.

Antihydrogen has been created, trapped and stored for 1,000 s. The improved holding time means that we now have access to the ground state of antimatter—long enough to test whether matter and antimatter obey the same physical laws.