Articles

Photochromic materials suffer from degradation when exposed to harsh chemical environments, but this can be overcome by providing chemical shielding via superomniphobicity. Here, the authors show the design rationale and careful materials selection for fabrication of color morphing surfaces that can simultaneously display excellent chemical resistance.

The fast-spinning primary of the Didymos near-earth asteroid binary system was found to have a degraded top shape by the DART (NASA) mission. Here, authors find that these surface features observed in the asteroid are more likely to have been caused by collisional effects than by the YORP effect.

Here, Dillard and Taft-Benz et al. show in a female mouse model how different adjuvants affect inactivated vaccine-mediated protection against homologous SARS-CoV-2 and heterologous SARS-CoV-1-like coronaviruses. They find that an aluminum hydroxide-adjuvanted vaccine can increase risk of adverse outcomes during heterologous infection.

CAR T cell immunotherapy for paediatric solid and brain tumours is constrained by the availability of targetable antigens. Here, the authors investigate the landscape of cancer-specific exons as potential targets by analysing 1,532 RNAseq datasets from 16 types of paediatric solid and brain tumours.

EBV (Epstein-Barr virus)-targeted therapy is limited by efficient agents inducing lytic cycle in cancer cells. Here they report a transcriptional activator incorporated into lipid nanoparticles that could specifically activate endogenous BZLF1 and induce lytic reactivation in EBV-positive cancer cells thereby suppress tumor progression.

Bose-Einstein condensates (BEC) of ultracold atoms serve as low-entropy sources for a multitude of quantum-science applications. Here, the authors realize a non-ground-state caesium BEC with tunable interactions and tunable loss, opening up new possibilities for polaron and impurity physics.

The phase diagram of twisted monolayer-bilayer graphene depends on the electric field direction, exhibiting phases similar to twisted bilayer and double-bilayer graphene. Here the authors study the field dependent electronic structure, in particular flat bands, using nano-ARPES and explain the field-tunability.

Here the authors show that DNA translesion synthesis affects primordial germ cell DNA demethylation and plays a role in the development of embryonic germ cells.

Molecular recognition of proteins is essential for achieving their biological functions but it is challenging to prepare selective protein-binding materials. Here the authors report a method that combines dynamic covalent chemistry and double molecular imprinting to construct protein-recognizing nanoparticles capable of specific inhibition of protein–protein interactions.

Chiral antiferromagnets, such as Mn3Pt, host a variety of transport phenomena arising due to the chiral arrangement of the spins. Herein, the authors find two contributions to the anomalous hall effect in Mn3Pt, and through comparison with other chiral antiferromagnets develop a universal scaling law for the anomalous hall effect in chiral antiferromagnets.

Spin-momentum locking is a fundamental property of condensed matter systems. Here, the authors evidence parallel Weyl spin-momentum locking of multifold fermions in the chiral topological semimetal PtGa.

Electrochemical-mechanical issues bring challenges but create new opportunities to design innovative all-solid-state batteries. Here, the authors propose to use the (de)lithiation-stress-creep synergistic time-dependent evolution to boost the electrochemical performance of all-solid-state batteries.

Indan and tetralin are used as fuel additives and intermediates in the manufacture of many products, including thermal-stable jet fuel. Here the authors report a route for the synthesis of methylindan and tetralin by the hydrogenolysis of xylose or hemicellulose over a non-noble metal catalyst, followed by further reaction over zeolite H-ZSM-5. Reviewer recognition:

Given that entangled states can store more information than unentangled ones, it would be natural to assume that highly-entangled data would always enhance capabilities of quantum machine learning models. Here, the authors show that this is not the case, in particular when the allowed number of measurements to incoherently learn quantum dynamics is low

Caustics, as a unique type of singularity in wave phenomena, occur in diverse physical systems. Here, the authors realize multi-dimensional customization of caustics with 3D-printed metasurfaces. This arbitrary caustic engineering is poised to bring new revolutions to many domains.

SAR11 bacteria and their phages are abundant in the oceans. Here the authors quantify the number of phage-infected SAR11 cells using microscopy techniques and discover phage-infected cells without any detectable ribosomes. They hypothesize that ribosomal RNA may be used for the synthesis of phage genomes.

Insoluble protein expression continues to be a bottleneck for biotechnology. Here, Chilkoti and colleagues report a method for generating and identifying hypersoluble intrinsically disordered protein fusion tags to improve soluble protein expression and rescue protein function.

In this work, the authors unveil a mechanism where the Citron homology domain regulates HPK1’s kinase domain, shedding light on the relationship between HPK1’s structure and function. This enhances our understanding of HPK1, an intracellular target for cancer immunotherapy and provides a direction for immuno-oncology drug discovery.

The amino acid transporter complex LAT1-4F2hc is considered a major drug target for many cancers. Here, the authors apply native mass spectrometry-based approaches to decode a complete LAT1-4F2hc assembly. To do this, they connect post-translational modification and endogenous phospholipid binding to super-dimerization, function and localisation of LAT1-4F2hc.

The widespread use of organoboronic acids has prompted the development of synthetic methodologies to meet the demands on structural diversity and functional group tolerance. Herein, the authors disclose a divergent radical dechloroborylation reaction enabled by dinuclear gold catalysis with visible light irradiation.