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.
The practical application of aqueous alkaline battery is confined by limited choice of anode. Here, the authors demonstrate an oxygen-rich interface induced reversible Sb stripping/plating chemistry that provides a promising Sb metal anode with fast reaction kinetics and favourable stability.
TARM1 is a LILR family member that drives cell signalling via interactions with FcRγ. Here the authors show that TARM1 binds collagens to activate dendritic cells and thereby is an effector of inflammatory arthritis, plus provide a soluble TARM-Fc fusion protein that can limit collagen-induced arthritis in mice.
Non-resonant lasers have many advantages since the allow for a diverse set of architectures and gain media, but their application is limited due to their low directionality and efficiency. Here, the authors present a scattering cavity laser with a single hole to achieve efficient and directional emission.
The pachytene piRNA loci are transcribed by RNA polymerase II in the male germline of placental mammals. Here the authors show that a long first exon or a long unspliced transcript correlates with germline-specific production of piRNA precursor transcripts and mature piRNAs.
Multi-emulsion droplets may lead to improved designs of soft materials or drug formulations. Tiribocchi et al. show that in typical situations expected during microfluidic post-processing, the dynamical distribution of emulsified droplets is dictated by the internal vortices of the host droplet.
Designing efficient light-emitting components without utilizing intricate back-end circuits remains a challenge. Here the authors present three-phase electric power driven electroluminescent devices capable to realize pixel units, interactive rewritable displays and to drive organic light-emitting devices with red, green and blue-emitting pixels.
Chemical interaction between metal and oxide supports is an important molecular-level factor that influences the catalytic selectivity of a desirable reaction. Here, using Pt nanowires/TiO2 catalytic nanodiodes, the authors investigate an enhancement of both selectivity and hot electron generation on metal-oxide interfacial sites.
Four-dimensional (4D) printing of shape memory polymer (SMP) imparts time responsive properties to 3D structures. Here, the authors explore 4D printing of a SMP in the submicron length scale, extending its applications to nanophononics.
Liquid-liquid phase separation of p62/SQSTM1 has been previously described, although the significance in vivo remains unclear. Here the authors show p62 droplets contain ubiquitin, autophagy-related proteins and Keap1 to serve as platform of not only autophagosome formation but also Nrf2 activation.
Covalent organic frameworks (COFs) are promising materials for separation membranes, but their wide pores prevent selective gas separation through molecular sieving. Here, the authors demonstrate a Metal-organic framework (MOF)-in-COF membrane with a significant enhancement of separation selectivity of hydrogen over other gases.
Here, the authors profile the oral phageome of 4 healthy individuals via longread shotgun metagenomics using PromethION, a recently developed highthroughput nanopore sequencer, and uncover potential new candidate phages with enhanced scaffolding and their interaction with host bacteria.
The emergent excitation dynamics of an ultracold gas of Rydberg atoms exhibits features analogous to epidemic spreading on networks. Wintermantel et al. propose a controllable experimental system for studying network dynamics at the interface of mathematical models and real-world complex systems.
COPA regulates Golgi to ER transport, and mutations lead to autoinflammation and disease through poorly understood mechanisms. Here, the authors show that disease-causing COPA variants prevent STING transport from the Golgi to the ER, leading to cGAS-independent activation of the STING pathway.
Autophagy is known to promote cellular survival upon starvation, although how recycled components fit into cellular metabolism has not been well established. Here, the authors show in yeast that autophagy tunes cellular metabolism based on nitrogen availability via glutamate and aspartate synthesis.
A theoretical framework to optimize photonic structure designs for upconversion enhancement is lacking. Here, the authors present a comprehensive theoretical model and confirm the model’s predictions by experimental realisation of 1D-photonic upconverter devices with large statistics and parameter scans.
Efficient and stable perovskite solar cells with simple active layers are desirable for manufacturing, yet formation of a two-dimensional component in the perovskite film compromises the performance. Here, the authors report low temperature fabrication of highly efficient and stable inverted solar cells by adding a fluorinated lead salt.
Unlike RORα, which has been thought to be somewhat redundant, RORγt has been well characterized in its function and contribution to the development of Th17 cells. Here the authors show that RORα is important in Th17 differentiation and that RORα deletion or a small molecule inhibitor of RORα can reduce disease in EAE and colitis mouse models.
High resolution imaging of large biological volumes typically takes a long time from hours to days. Here the authors use a Bessel light-sheet approach combined with a content-aware compressed sensing computational pipeline to image whole mouse organs at subcellular resolution in a few minutes.
Yersiania YopJ protein has been shown to drive caspase-8-mediated pyroptosis. Here the authors show a precise mechanism of this non-canonical cell death pathway that is controlled by a TRIF-dependent complex of FADD, RIPK1, caspase-8 and ZBP1.
Nanopore sequencing technologies applied to transcriptome analysis suffer from high error rates, limiting them largely to reference-based analyses. Here, the authors develop a computational error correction method for transcriptome analysis that reduces the median error rate from ~7% to ~1%.