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Here, the authors show that Intracortical recordings in human motor cortex during attempted multi-finger movements reveal a largely linear code with two violations: magnitude normalization and greater shifts in tuning direction for weakly represented fingers.

The authors introduce a new spectroscopic technique for studying Higgs modes in superconductors and apply it to a cuprate superconductor. The method involves a soft quench of the Mexican-Hat potential, populating Higgs modes of different symmetries, which are then probed by non equilibrium anti-Stokes Raman scattering.

Solving partial differential equations is the cornerstone of scientific and engineering development. Here, authors show a high-performance optical neural engine architecture, combining diffractive optics and optical matrix multipliers, to solve a variety of equations in broad scientific domains.

The authors report the implementation of a bilayer system of 2D ultracold Bose gases with controllable Josephson coupling. This allows characterisation of coupling-induced superfluid phases and their microscopic origin tracing back to vortex binding.

Coupling of ecology and evolution in microbiomes can lead to time-dependent community interactions. Here, the authors introduce Dynamic Covariance Mapping (DCM), an approach to quantify the community matrix and, with high-resolution lineage tracking, show how inter- and intra-species interactions shape the dynamics of mouse gut colonization.

Kinesin-1 utilizes ATP-driven conformational changes to transport vital intracellular cargoes along microtubules. The authors use cryo-EM to reveal a missing structural transition state of the kinesin-1 motor domain during ADP release that is unaffected by its autoinhibitory tail.

The study reveals strikingly different nonlinear Rabi splitting dynamics in MoSe₂ monolayers and (Ga,In)As quantum wells, highlighting the pivotal role of Coulomb interactions in shaping light–matter coupling in two-dimensional semiconductors.

CellSpectra identifies functionally relevant changes in cellular pathways when analyzing single samples in comparison to a reference atlas, here applied to rodent models and patient samples of kidney disease.

The authors analyze rare coding variants in 1990 individuals with congenital kidney anomalies, finding diagnostic variants in 14.1% of cases. They identify two new causal genes, ARID3A and NR6A1, along with 38 candidate genes, providing evidence for shared genetics with other developmental disorders.

This study introduces the Cattle Cell Atlas, a single-cell expression resource including 1,793,854 cells from 59 tissues. Integrative analyses leveraging this atlas provide insights into the biology underlying bovine monogenic and complex traits.

The brain and body are necessarily connected. Here the authors show that brain blood flow and electrical activity are coupled with systemic physiological changes in the body.

CRISPR-associated transposases represent a promising tool for precise, DSB-free genome editing. Here, authors investigate a CAST system active in human cells, improve activity via structure-guided engineering, and develop novel chimeras for improved modularity.

Using well-calibrated statistical methods the authors jointly analyze Undiagnosed Diseases Network genomes, identifying known and novel disease genes. Software is publicly available to support future cross-cohort rare disease discovery efforts.

Combining conformal prediction machine learning with molecular docking, a method to efficiently screen multi-billion-scale libraries is developed, enabling the discovery of a dual-target ligand modulating the A_2A adenosine and D₂ dopamine receptors.

Mitochondrial DNA from horses at the Middle Pleistocene archaeological site of Schöningen reveals insight into the evolutionary history of horses and advances techniques for the analysis of ancient DNA retrieved from highly degraded samples.

The quark structure of the f₀(980) hadron is still unknown after 50 years of its discovery. Here, the CMS Collaboration reports a measurement of the elliptic flow of the f₀(980) state in proton-lead collisions at a nucleon-nucleon centre-of-mass energy of 8.16 TeV, providing strong evidence that the state is an ordinary meson.

Scalable platforms for non-invasive action potential recording are needed. Here, the authors present a reliable method to capture APs with patch-clamp-like fidelity from stem cell-derived cardiomyocytes using an Electrolyte-Gated Polymer Field-Effect Transistors.

Wastewater surveillance can help in pandemic or outbreak response. Here, the authors report an unsupervised learning approach to detect emerging SARS-CoV-2 variants from rural and urban wastewater showing it achieves earlier detection than existing methods and detects new variants without clinical testing data.

Complement proteome engagement is strongly linked to kidney outcomes in diabetes. This translational study leveraged five cohorts of over 4,500 person-years and high-throughput proteomics to enable potential biomarker-guided drug development.

Gollo et al. introduce random ‘mutations’ to the human connectome to study the trade-off between complexity vs. parsimony. The cortical hubs that are most fragile to these perturbations show the strongest loss of gray matter volume in schizophrenia.

Reinforcement learning task-based behavioral and computational measures displayed low test–retest reliability at the individual level. Also in contrast to self-assessed personality measures, behavioral and computational measures were poor predictors of mental health measures, representing a challenge for computational psychiatry.

In this paper, the authors present findings demonstrating that variations of the MET gene are associated with specific structural differences in key language regions in individuals with schizophrenia.

People can track a limited number of moving items in perception, but it is unknown if similar limits apply to the imagination. The authors show the mental simulation of moving objects is a serial process, which advances only one object at a time.

Mathematical models of V1 seek to explain the response properties of V1 neurons, often with more complex models providing more accurate predictions. Here, the authors show that deep neural network models of mouse and monkey V1 can be dramatically simplified to a two-layer “minimodel" while retaining high accuracy.

The neuronal coding principles that underlie inter-individual perceptual similarities remains unclear. Here, the authors compared the stability of relational similarity versus activation patterns across brains and found that relational similarity was preferentially consistent across individuals, potentially underlying shared inter-subject perception.

We report direct measurement of repulsive van der Waals forces on suspended graphene using atomic force microscopy. The strong repulsive forces substantially lower the wettability of suspended graphene.

This multiomic study, including single-nucleus DNA methylation and chromatin conformation matched with single-nuclei RNA sequencing, provides insights into the epigenomic landscape of human subcutaneous adipose tissue.

Bacterial mechanosensitive channel YnaI opens at near-lytic membrane tension. Here, authors show that YnaI remains open to a much lower membrane tension than required for its activation and evolved to respond to slow changes in membrane tension.

Analysis of a deeply phenotyped, longitudinal cohort of 249 participants elucidates the network of concurrent molecular and macroscopic patterns related to insurgence and course of ME/CFS.

Here, the authors compare HP1 from fission yeast, fly and mouse, and find that the propensity of HP1 to phase-separate and to cluster heterochromatin decrease in this order, suggesting an evolutionary adaptation of HP1 function.

Sex differences in traits and disease risk are pervasive and begin before birth. Here, the authors report sex-dependent human placental epigenetic and transcriptomic regulation and highlight its connection with neonatal and adult disease and health.

Optical access to the brain is limited by light scattering in the skull. Here, the authors present SeeThrough, a rationally designed skull clearing technique that enables simple, minimally-invasive, high-resolution, mesoscale, and longitudinal imaging of the brain parenchyma and brain-skull interface without skull removal.

This study presents a design for fabricating a terahertz chiral photonic-crystal cavity with broken time-reversal symmetry. By combining density functional theory with a microscopic model, the cavity-induced gap in graphene was estimated, showing enhanced light–matter coupling at the Dirac nodes.

This study presents a programming strategy for the two-dimensional folding of a robotic sheet into an unbounded set of hinge configurations post-deployment, enabling in situ multi-purpose tasks with applications in dexterous grasping and adaptive locomotion.

Peripherally restricted CB1 inhibitors retain the weight loss benefits of this drug class while sparing the negative psychiatric side effects. The authors here elucidate cryo-EM structures of CB1 bound to peripherally restricted inhibitors to explain these drugs’ molecular mechanism of action.

The fibrinolytic system promotes the progression of solid tumors. Here, the authors show that the fibrinolytic agent plasmin supports B-cell acute lymphoblastic leukemia (B-ALL) progression via remodeling of the extracellular matrix, and the inhibition of plasmin activation with ε-aminocaproic acid prolongs survival in B-ALL mouse models.

Neel domain walls are typically stabilized by an interfacial Dzyaloshinskii-Moriya interaction, with a chirality that is fixed by the sample materials. Here, Song, Huang and coauthors demonstrate the existence of two bistable Néel domain wall states with opposite chiralities, and the switching between these via magnetic field pulses

Understanding the growth dynamics of GBMs can help expand therapeutic options. Here, authors use a cross-species computational approach to compare GBM cells to healthy neural stem cells, identifying predictors and modulators of tumour growth, including the Wnt antagonist, SFRP1, which stalls growth in preclinical xenograft models.

Patients with Huntington’s disease carrying the FAN1 R507H mutation have earlier than predicted onset of motoric symptoms. This study provides mechanistic insight into the interactions that may promote CAG repeat expansion. FAN1 R507 interacts with PCNA D232 and this interaction is impaired for FAN1 R507H, resulting in reduced FAN1 activity.

Lineage switching (LS) facilitates acute myeloid leukemia (AML) escaping CD19 targeted immunotherapy, but the underlying mechanism are not well understood. The authors here analyze patients’ single-cell mass cytometry and single-cell transcriptomics data, and identify an LS AML with the MDSC-like phenotype which is associated with LS in AML with KMT2A rearrangement.

Madar et al. report that behavioral timescale synaptic plasticity (BTSP), not spike-timing-dependent plasticity, explains heterogeneous place fields shifting in the hippocampus. The probability of BTSP induction follows patterned dynamics, is higher in new contexts and lower in CA3 than CA1.

Serino et al. show that seeing an infectious avatar approach the body in virtual reality triggers an immune response, indicating that the brain prepares the body to fight infections even for perceived, but not real, threats.

Multiplexed assays of variant effect can resolve clinical variants but are incompatible with secreted proteins. Here Popp et al. develop MultiSTEP, a generalizable surface-tethering method to assess variant effects in secreted proteins at scale.

A comprehensive understanding of how urban nature affects mental health at a global scale remains essential. This study addresses that need through a systematic review and meta-analysis, revealing the effects of exposure to various urban nature types on 12 distinct mental health outcomes.

Pressure overload in the heart, such as from aortic stenosis, triggers early molecular changes before visible damage occurs. Here, the authors show that combining proteomics, transcriptomics, and genetic data reveals key drivers of heart failure, highlighting potential targets for treatment.

Quantum field theories, particularly within the framework of the Standard Model, have been instrumental in understanding fundamental forces, but quantum chromodynamics presents challenges in the low-energy regime, necessitating non-perturbative methods like lattice gauge theory. The authors explore a hybrid approach combining quantum and classical methods to compute the running coupling, focusing on a proof-of-concept in pure gauge theory

Due to their small size, atomic-scale Josephson junctions are vulnerable to thermal fluctuations. Escribano et al. show that introducing a delayed feedback element, a common method to mitigate thermal noise, induces spontaneous oscillations that enhance capabilities of Josephson microscopy.

The transcription factor ATF6 causes an enrichment in long-chain fatty acids in the colonic epithelium, which leads to changes in the gut microbiota and contributes to the development of colorectal cancer in humans and mice, thereby linking endoplasmic reticulum stress responses to lipid metabolism and tumorigenesis.

DNA polymerase beta (Pol β) is the primary enzyme responsible for processing 1-nt gaps in chromatin during DNA repair. Here, the authors determine the kinetic and structural basis of gap-filling DNA synthesis in the nucleosome by Pol β, providing fundamental insight into DNA repair in chromatin.