Although omics and multi-omics approaches are the most used methods to create signature arrays for liquid biopsy, the high cost of omics technologies still largely limits their wide applications for point-of-care. Inspired by the bat echolocation mechanism, we propose an “echoes” approach for creating chemiluminescence signatures via screening of a compound library, and serum samples of Alzheimer's disease (AD) were used for our proof-of-concept study. We first demonstrated the discrepancy in physicochemical properties between AD and healthy control serums. On this basis, we developed a simple, cost-effective, and versatile platform termed UNICODE (UNiversal Interaction of Chemiluminescence echOes for Disease Evaluation). The UNICODE platform consists of a “bat” probe, which generates different chemiluminescence intensities upon interacting with various substrates, and a panel/array of “flag” molecules that are selected from library screening. The UNICODE array could enable the reflecting/“echoing” of the signatures of various serum components and intact physicochemical interactions between serum substrates. In this study, we screened a library of over 1,000 small molecules and identified 12 “flag” molecules (top 12) that optimally depict the differences between AD and healthy control serums. Finally, we employed the top 12 array to conduct tests on serum samples and utilized machine learning methods to optimize detection performance. We successfully distinguished AD serums, achieving the highest area under the curve of 90.24% with the random forest method. Our strategy could provide new insights into biofluid abnormality and prototype tools for developing liquid biopsy diagnoses for AD and other diseases.

Isovaleryl-CoA (coenzyme A) dehydrogenase (IVD) plays a pivotal role in the catabolism of leucine, converting isovaleryl-CoA to 3-methylcrotonyl-CoA. Dysfunction of IVD is linked to isovaleric acidemia (IVA), a rare metabolic disorder characterized by the accumulation of toxic metabolites. In this study, we present the cryo-electron microscopy structures of human IVD, resolved both in its apo form and in complex with its substrates, isovaleryl-CoA and butyryl-CoA. Our findings reveal a tetrameric architecture with distinct substrate-binding pockets that facilitate the enzyme's preference for short branched-chain acyl-CoAs. Key residues involved in FAD binding and substrate interaction were identified, elucidating the catalytic mechanism of IVD. Additionally, we investigated the impact of various disease-associated hotspot mutations derived from different regions, demonstrating their effects on enzyme stability and activity. Notably, mutations such as A314V, S281G/F382V, and E411K resulted in substantial loss of function, while others exhibited milder effects, which is consistent with our structural analyses. These insights enhance our understanding of IVD's enzymatic properties and provide a foundation for developing targeted therapies for IVA.

Supplementation with short-chain fatty acids (SCFAs) is a potential therapeutic approach for inflammatory bowel disease (IBD). However, the therapeutic effects and mechanisms of action of isobutyrate in IBD remain unclear. Clinical data indicate that the fecal levels of isobutyrate are markedly lower in patients with Crohn's disease than in healthy controls. Compared with healthy mice and healthy pigs, mice and pigs with colitis presented significantly lower isobutyrate levels. Furthermore, the level of isobutyrate in pigs was significantly negatively correlated with the disease activity index. We speculate that isobutyrate may play a crucial role in regulating host gut homeostasis. We established a model of dextran sulfate sodium-induced colitis in pigs, which have gastrointestinal structure and function similar to those of humans; we performed multiomic analysis to investigate the therapeutic effects and potential mechanisms of isobutyrate on IBD at both the animal and cellular levels and validated the results. Phenotypically, isobutyrate can significantly alleviate diarrhea, bloody stools, weight loss, and colon shortening caused by colitis in pigs. Mechanistically, isobutyrate can increase the relative abundance of Lactobacillus reuteri, thereby increasing the production of indole-3-lactic acid, regulating aryl hydrocarbon receptor expression and downstream signaling pathways, and regulating Foxp3⁺ CD4⁺ T cell recruitment to alleviate colitis. Isobutyrate can directly activate G protein-coupled receptor 109A, promote the expression of Claudin-1, and improve intestinal barrier function. In addition, isobutyrate can increase the production of intestinal SCFAs and 3-hydroxybutyric acid and inhibit the TLR4/MyD88/NF-κB signaling pathway to suppress intestinal inflammation. In conclusion, our findings demonstrate that isobutyrate confers resistance to IBD through host–microbiota interactions, providing a theoretical basis for the use of isobutyrate in alleviating colitis.

The development of clean and efficient renewable energy is of great strategic importance to realize green energy conversion and low-carbon growth. Hydrogen energy, as a renewable energy with “zero carbon emission”, can be efficiently converted into hydrogen energy and electric energy by electrolysis of water to hydrogen technology. Anion-exchange membrane water electrolysis (AEMWE), substantially advanced by nonprecious metal electrocatalysts, is among the most cost-effective and promising water electrolysis technologies, combining the advantages of proton exchange membranes with the proven technology of traditional alkaline water electrolysis and potentially eliminating the disadvantages of both. In this paper, the latest results of AEMWE research in recent years are summarized, including the AEMWE mechanism study and the hot issues of low-cost transition metal hydrogen evolution reaction and oxygen evolution reaction electrocatalyst design in recent years. The key factors affecting the performance of AEMWE are pointed out, and further challenges and opportunities encountered in large-scale industrialization are discussed. Finally, this review provides strong guidance for advancing AEMWE.

The development of biodegradable mulch film is an effective means to address plastic pollution and promote modern green agriculture. In this work, with compounding sodium carboxymethyl cellulose (CMC) and quaternized lignin (QL), a biodegradable liquid mulch film (PVA@CMC/QL) was constructed by introducing polyvinyl alcohol (PVA) and a selenium-containing cross-linking agent through electrostatic interaction. The effect of sodium carboxymethyl cellulose and QL on different liquid mulch films was examined. PVA@CMC/QL had exceptional spray-film-forming properties of liquid mulch film and was capable of generating a dense mulch film above the soil/on top of the soil under natural conditions. PVA@CMC/QL exhibited excellent oxygen transmission rate (60.2 cm³·m⁻²·d⁻¹·Pa⁻¹) and water vapor transmission rate (753.4 g·m⁻²·d⁻¹). Soil temperature and humidity increased by 0.4 to 2.1 °C and 0.5% to 2.8%, respectively, in the soil covered with PVA@CMC/QL compared to those in other controls, thereby confirming its exceptional moisture retention and insulation capabilities. PVA@CMC/QL combined remarkable weed suppression with only 13.3% weed germination under the mulch. Optimal rhizome growth of pak choi seedlings was observed under the PVA@CMC/QL cover, as demonstrated by the planting of both pak choi seedlings and weeds. Roots and stems increased by 3.8 ± 0.3 and 1.2 ± 0.3 cm, respectively. The weed suppression mechanism of PVA@CMC/QL was explained through the lens of density functional theory. In addition, the selenium content of pak choi seedlings under PVA@CMC/QL cover could reach 28.5 μg/kg, making the mulch film both degradable and highly reusable. This work not only improved the value-added utilization of bamboo residues but also gave new insight into the research on multifunctional bamboo–plastic mulch film.

Type 2 diabetes mellitus (T2DM), a prevalent metabolic disorder marked by insulin resistance and hyperglycemia, has been linked to volumetric changes in subcortical regions, yet the genetic basis of this relationship remains unclear. We analyzed genome-wide association study summary data for T2DM and 14 subcortical volumetric traits, using MiXeR to quantify shared genetic architecture and applying conditional/conjunctional false discovery rate analyses to detect novel and shared genomic loci. Enrichment and gene expression analyses were subsequently performed to explore the biological functions and mechanisms of genes associated with these loci. We observed a substantial proportion of trait-influencing variants shared between T2DM and subcortical structures, with Dice coefficients ranging from 22.4% to 49.6%. Additionally, 70 distinct loci were identified as being jointly associated with T2DM and subcortical volumes, 5 and 22 of which were novel for T2DM and subcortical volumes, respectively. The 769 protein-coding genes mapped to these shared loci are enriched in metabolic and neurodevelopmental pathways and exhibit specific developmental trajectories, with 117 genes showing expression levels linked to both T2DM and subcortical structures. This study uncovered polygenic overlap between T2DM and subcortical structures, deepening our comprehension of the genetic factors linking metabolic disorders and brain health.

Oxalate-induced crystalline kidney injury is a common form of crystal nephropathy. The accumulation of calcium oxalate (CaOx) crystal could lead to renal epithelium injury and inflammation. The underlying cellular events in kidney after CaOx crystal formation are largely unknown. This study was aimed to gain a better understanding of mouse kidney function in the development of renal CaOx formation. The study utilized a mouse CaOx model to analyze the cellular response at 5 time points using single-cell RNA sequencing and investigate the interaction of different cells during renal CaOx crystal formation. Additionally, the study investigated the communication between these cells and macrophages, as well as the role of chemokines in recruiting infiltrating macrophages. RNA velocity analysis uncovered an alternative differentiation pathway for injured and S1 proximal tubule cells, which mainly communicate with macrophages through the SPP1–CD44 pair, along with the expression of proinflammatory factors and stone matrix genes during renal CaOx crystal formation. Furthermore, resident Fn1 macrophages were found to express chemokines, such as CCL2, which recruited infiltrating macrophages. The CCL2 secretion was mediated by the CD44–AKT pathway. Blocking CCL2 decreased the expression of injury markers in the kidney, including CLU, LCN2, and KIM-1, and inhibited CaOx crystal deposition. The study identified potential cell types and target genes involved in renal tubule injury in oxalate-related crystal nephropathy. The findings shed light on the cellular processes that contribute to the formation and damage caused by CaOx crystals within the kidney, which could lead to the development of potential cell types and target genes for treating this condition.

Discrete-modulated coherent-state continuous-variable quantum key distribution (DMCS-CVQKD) is of great value for its simple implementation. However, the traditional DMCS-CVQKD scheme cannot tolerate the high channel excess noise and channel loss, compared to the Gaussian-modulated scheme, and its error correction is still difficult. In this paper, we propose a discrete-modulated coherent-state basis-encoding quantum key distribution (DMCS-BE-QKD) protocol, where the secret keys are encoded in the random choice of 2 measurement bases, i.e., the conjugate quadratures X and P of discrete-modulated coherent states, and it only needs simple binary sequence error correction. We analyze the secret key rate of DMCS-BE-QKD protocol under individual and collective attacks in the linear Gaussian channel. The results show that DMCS-BE-QKD can greatly enhance the ability to tolerate the channel loss and excess noise compared to the original DMCS-CVQKD protocol, which can tolerate approximately 40 dB more channel loss compared to the original DMCS-CVQKD for the realistic value of noise. Finally, a proof-of-principle experiment is conducted under a 50.5-km optical fiber to verify the feasibility of DMCS-BE-QKD. It is based on the consistent physical procedures of the traditional DMCS-CVQKD, which makes it perfectly compatible to deployed terminals and can serve as a multiplier for the practical secure quantum cryptography communication in harsh environments.

Gastric cancer (GC) is one of the most common cancers worldwide particularly in Asian populations, and certain diets have been associated with increased risk of GC. Recent advances in microbial profiling technology have facilitated investigations on microbes residing on the gastric mucosa and increasing evidence has revealed the critical roles of non-Helicobacter pylori gastric microbes in gastric tumorigenesis. On the other hand, diets can affect microbial communities, causing compositional and functional shift of the microbiota. In this review, we summarize the influence of various diets including processed meat, salt-preserved food, high-fat diet, and alcohol on the development and progression of GC. We also explore microbial metabolites and host–microbe interactions in gastric tumorigenesis, alongside dietary interventions targeting the microbiota for the prevention and management against GC.

Mechanical overload is a critical contributor to cartilage degeneration in osteoarthritis (OA) pathogenesis. Circular RNA (circRNA) is expected to provide a long-lasting therapy for OA. However, the involvement of the circRNA-associated competitive endogenous RNA network in chondrocyte senescence induced by mechanical overloading remains unestablished. A mechanical overloading-induced chondrocyte senescence model in human primary chondrocytes is constructed, and differences in the expression of circRNAs and miRNAs were analyzed. The biological roles of circKIAA0586/miR-335-5p in chondrocyte senescence and OA progression under mechanical overloading and its downstream targets were determined using gain- and loss-of-function experiments in various biochemical assays in human chondrocytes. The in vivo effects of circKIAA0586 overexpression were also determined in destabilization of the medial meniscus (DMM) OA mice and aged spontaneous OA mice. The mechanical overloading-induced chondrocyte senescence was aggravated by miR-335-5p or circKIAA0586 knockdown. Accumulated DNA damage response was observed following mechanical overloading, which reduced after miR-335-5p inhibition or circKIAA0586 supplementation. MiR-335-5p was regulated by circKIA0586 adsorption. HELLS was prominently down-regulated following mechanical overloading treatment. Moreover, miR-335-5p bound to lymphoid-specific helicase (HELLS) mRNA during mechanical overloading was demonstrated to mediate the nonhomologous end joining (NHEJ) pathway, thereby inducing DNA damage and senescence. In addition, the senescence delaying and cartilage protective functions of circKIAA0586 and HELLS were validated in DMM OA mice and aged spontaneous OA mice. Our findings suggest that miR-335-5p, which escapes circKIAA0586 adsorption, facilitates mechanical overloading-induced chondrocyte senescence and OA progression by impairing the NHEJ pathway through HELLS inhibition. Overall, targeting circKIAA0586/miR-335-5p/HELLS signaling provides a novel therapeutic approach for OA.

Although equivalent in the infinite-momentum limit, large-momentum effective theory (LaMET) and short-distance operator product expansion (SDE) are 2 very different approaches to obtain parton distribution functions (PDFs) from coordinate-space correlation functions computed in a large-momentum proton through lattice quantum chromodynamics (QCD). LaMET implements a momentum-space expansion in {\mathrm{\Lambda }}_{\mathrm{QCD}} / \left[x\left(1-x\right)P^z\right] to directly calculate PDFs f \left(x\right) in a middle region of Bjorken x \in \left[x_{\min }\sim {\mathrm{\Lambda }}_{\mathrm{QCD}}/{\mathit{xP}}^z,x_{\max }\sim 1-x_{\min }\right]. SDE applies perturbative QCD at small Euclidean distances z to extract a range \left[0,{\lambda }_{\max }\right] of leading-twist correlations, h \left(\lambda ={\mathit{zP}}^z\right), corresponding to the Fourier transformation of PDFs. An incomplete leading-twist correlation from SDE cannot be readily converted to a momentum-space distribution, and solving its constraints on the PDFs (or the so-called “inverse problem”) involves phenomenological modeling of the missing information beyond {\lambda }_{\max } and has no systematic control of errors. I argue that the best use of short-distance correlations is to constrain the PDFs in the LaMET-complementary regions: x \in \left[0,x_{\min }\right] and \left[x_{\max },1\right] through expected end-point asymptotics, and use the results of the pion valence quark distribution from the ANL/BNL collaboration to demonstrate how this can be done.

Arsenic trioxide (ATO) is able to selectively target and degrade the disease-causing PML::RARα (P/R) oncoprotein in acute promyelocytic leukemia (APL) for curing the disease. However, some relapsed patients develop resistance to ATO due to mutations in the promyelocytic leukemia (PML) part of the PML::RARα fusion gene. A relapsed APL patient had shown resistance to ATO and chemotherapy and was identified to harbor a point mutation (A216V) in the unrearranged PML allele rather than the PML::RARα fusion gene. Here, we report that mutations in the unrearranged PML allele impede the ATO-induced destabilization and degradation of the wild-type P/R oncoprotein. Deletion of the coiled-coil domain in a PML mutant completely reversed wild-type P/R protein resistance to ATO by abolishing the interaction between PML and P/R proteins. Collectively, our findings reveal that a point mutation in the unrearranged PML allele can confer ATO resistance through a protein–protein interaction. Therefore, the unrearranged PML allele should also be screened for drug-resistant mutations in relapsed APL patients.

Cuproptosis represents a novel mechanism of cellular demise characterized by the intracellular buildup of copper ions. Unlike other cell death mechanisms, its distinct process has drawn considerable interest for its promising applications in managing inflammatory bowel disease (IBD) and colorectal cancer (CRC). Emerging evidence indicates that copper metabolism and cuproptosis may exert dual regulatory effects within pathological cellular environments, specifically modulating oxidative stress responses, metabolic reprogramming, and immunotherapeutic efficacy. An appropriate level of copper may promote disease progression and exert synergistic effects, but exceeding a certain threshold, copper can inhibit disease development by inducing cuproptosis in pathological cells. This makes abnormal copper levels a potential new therapeutic target for IBD and CRC. This review emphasizes the dual function of copper metabolism and cuproptosis in the progression of IBD and CRC, while also exploring the potential application of copper-based therapies in disease treatment. The analysis further delineates the modulatory influence of tumor immune microenvironment on cuproptosis dynamics, while establishing the therapeutic potential of cuproptosis-targeted strategies in circumventing resistance to both conventional chemotherapeutic agents and emerging immunotherapies. This provides new research directions for the development of future cuproptosis inducers. Finally, this article discusses the latest advances in potential molecular targets of cuproptosis and their related genes in the treatment of IBD and CRC, highlighting future research priorities and unresolved issues.

Achieving high maturity and functionality in in vitro skeletal muscle models is essential for advancing our understanding of muscle biology, disease mechanisms, and drug discovery. However, current models struggle to fully recapitulate key features such as sarcomere structure, muscle fiber composition, and contractile function while also ensuring consistency and rapid production. Adult stem cells residing in muscle tissue are known for their powerful regenerative potential, yet tissue-derived skeletal muscle organoids have not been established. In this study, we introduce droplet-engineered skeletal muscle organoids derived from primary tissue using cascade-tubing microfluidics. These droplet-engineered organoids (DEOs) exhibit high maturity, including well-developed striated sarcomeres, spontaneous and stimulated contractions, and recapitulation of parental muscle fiber types. Notably, DEOs are produced in just 8 d without the need for primary cell culture—substantially accelerating the 50- to 60-d process required by classical organoid models. Additionally, the cascade-tubing microfluidics platform enables high-throughput production of hundreds of uniform DEO replicates from a small tissue sample, providing a scalable and reproducible solution for skeletal muscle research and drug screening.

Current strategies for cartilage repair, including decellularized cartilage matrices and synthetic bioactive materials, often encounter challenges such as immune responses and donor morbidity. In this study, we optimized an extracellular matrix (ECM) derived from mesenchymal stem cells through preconditioning with disease-associated inflammatory factors, specifically interleukin 6, tumor necrosis factor alpha, and interferon gamma (IFN-γ). Our in vitro experiments demonstrated that the cytokine-preconditioned stem-cell-derived ECM, especially IFN-γ-ECM, supports chondrocyte homeostasis by restoring mitochondrial energy metabolism. Furthermore, bioactive molecules secreted from this preconditioned ECM boost the recruitment of endogenous stem cells and facilitate their differentiation into chondrocytes. Notably, we found that IFN-γ-ECM facilitates the chondrogenic differentiation of mesenchymal stem cells through the activation of the integrin/phosphatidylinositol 3-kinase/Akt pathway and the Smad2/3 signaling cascade. These results highlight the potential of the cytokine-stimulated ECM, especially IFN-γ-ECM, to restore chondrocyte homeostasis, optimize the mobilization of endogenous stem cells, and substantially improve the regeneration of cartilage defects, offering a promising strategy for acellular cartilage graft reconstruction.

Estrogen fluctuations have been implicated in various mood disorders, including perimenopausal and postpartum depression (PPD), likely through complex neural networks. γ-aminobutyric acid-ergic (GABAergic) neurons in the medial preoptic area (MPOA) that express estrogen receptor 1 (ESR1) are essential for the development and expression of depressive-like behaviors in ovarian hormone withdrawal (HW) mice. However, the precise circuit mechanisms through which MPOA GABAergic neurons influence behavior remain incompletely understood. Here, we identified robust projections from MPOA GABAergic neurons to the paraventricular nucleus of the hypothalamus (PVN). In HW mice, chemogenetic activation of MPOA GABAergic neurons targeting PVN attenuated depressive-like behaviors. Conversely, in nonhormone withdrawal (NHW) control mice (which received continuous estrogen), suppression of MPOA GABAergic projections to PVN exacerbated depressive-like behaviors. Further analyses using quantitative polymerase chain reaction and immunostaining identified arginine vasopressin (AVP) as a key neuropeptide in this pathway in the HW mouse model. Chemogenetic inhibition of PVN^AVP neurons significantly alleviated depressive-like behaviors in HW mice, while their activation in NHW mice worsened depressive-like behaviors. These behaviors were dependent on AVP expression in PVN^AVP neurons. Moreover, in HW mice, chemogenetic inhibition of PVN^AVP neurons receiving MPOA input mitigated depressive-like behaviors. Conversely, in NHW mice, activation of these neurons exacerbated depressive-like behaviors. Electrophysiological recordings demonstrated that MPOA GABAergic neurons directly inhibit PVN^AVP neurons. Thus, our findings suggest that PVN^AVP neurons serve as downstream effectors of MPOA GABAergic neurons via monosynaptic inhibitory signaling to regulate depressive-like behaviors. Targeting this circuit may offer a novel therapeutic strategy for PPD.

The disruption of ferroptosis, an emerging form of programmed cell death, is crucial in the development and aggressiveness of tumors. Meanwhile, the mechanisms and treatments that control ferroptosis in neuroblastoma (NB), a prevalent extracranial cancer in children, are still unknown. In this study, forkhead box C1 (FOXC1) and O-GlcNAc transferase (OGT) are identified as regulators of asparagine- and alanine-mediated ferroptosis repression in NB. Mechanistically, OGT facilitates FOXC1 stabilization via inducing O-GlcNAcylation in liquid condensates to increase the expression of asparagine synthetase (ASNS) and glutamate pyruvate transaminase 2 (GPT2), resulting in asparagine and alanine biogenesis, and subsequent synthesis of cystathionine β-synthase (CBS) or ferritin heavy chain 1 (FTH1). Meanwhile, exonic circular OGT RNA (ecircOGT) is able to encode a novel protein (OGT-570aa) containing domain essential for binding of OGT to FOXC1, which competitively decreases the OGT–FOXC1 interaction. Preclinically, miconazole nitrate facilitates the interaction of OGT-570aa with FOXC1, suppresses ferroptosis resistance of NB cells, and inhibits their growth, invasion, and metastasis. In clinical NB cases, higher OGT, FOXC1, ASNS, GPT2, CBS, or FTH1 levels are correlated with worse survival, while lower ecircOGT or OGT-570aa expression is associated with tumor progression. These results indicate that targeting the ecircOGT/OGT/FOXC1 axis inhibits asparagine- and alanine-mediated ferroptosis repression in NB progression.

Vascular inflammatory aging is strongly associated with multimorbidity, including immunosenescence. Here, bioinformatic analysis indicated elevated expression of the lysozyme (LYZ) gene in age-dependent vascular diseases. Lyz1 deficiency led to vascular inflammatory aging, including damage to indicators related to oxidative stress, vascular function, and inflammation in the serum and vascular tissues of wild-type (WT) and Lyz1^−/− mice. The 16S ribosomal RNA sequencing of intestinal contents revealed increased Bifidobacterium and its metabolism of acetate, butyrate, omega-muricholic acid, propionate, and valeric acid in Lyz1^−/− mice compared with that in WT mice. Additionally, RNA sequencing of vascular tissues identified differentially expressed genes in Lyz1^−/− mice compared with those in WT mice, as well as enrichment of the common phosphatidylinositol 3-kinase (PI3K)–Akt signaling pathway. Vascular inflammatory aging phenotypes were detected in the blood vessels of antibiotic-treated and germ-free mice, and the PI3K–Akt signaling pathway was inhibited. Importantly, intravenous LYZ administration worsened the pathological conditions, whereas oral LYZ administration successfully restored the gut microbial balance and reversed the vascular inflammatory aging phenotypes. Collectively, this study establishes LYZ as a novel biomarker for age-related vascular diseases and the gut microbiota–PI3K–Akt axis as a promising therapeutic target.

Background: Ischemic heart disease is a leading cause of mortality and disability worldwide among cardiovascular conditions. Myocardial ischemia–reperfusion injury (MIRI) occurs following percutaneous coronary intervention, during which neutrophils generate neutrophil extracellular traps (NETs) in response to injury. This study aims to elucidate the mechanisms underlying NET activation and its impact on MIRI. Methods: Sham and MIRI rat models were established. Various techniques, including enzyme-linked immunosorbent assay, hematoxylin and eosin staining, Masson staining, and transmission electron microscopy, were used to assess endothelial cell injury and myocardial tissue inflammation. Immunofluorescence was employed to evaluate NET activation in tissues, peripheral blood neutrophils, and protein colocalization. MitoTracker and ER-Tracker staining were conducted to assess the formation of mitochondria-associated membranes (MAMs). Extracted NETs were applied to conduct microvascular endothelial cell tube formation assay and flow cytometry. RNA-sequencing and immunoprecipitation–mass spectrometry were applied to determine the key regulators. Flow cytometry and Western blot were used to assess Ca²⁺ and mitophagy levels in neutrophils. Deoxyribonuclease I, NET inhibitor, was injected into MIRI rats to evaluate the in vivo effects of NET modulation on MIRI severity. Results: MIRI was often accompanied by cardiac microvascular endothelial cell (CMEC) injury and inflammation. Lactate mediated H3K18 lactylation at the MICU3 promoter in neutrophils, enhancing its transcription and leading to elevated MICU3 levels. Besides, lactate also promoted the interaction between MICU3 and AASR1, stabilizing MICU3 through lactylation. Up-regulated MICU3 interacted with VDAC1, facilitating MAM formation, excessive Ca²⁺ uptake, mitochondrial dysfunction, mitophagy activation, and NET activation. Elevated NET level exacerbated CMEC dysfunction, further aggravating MIRI. Conclusion: Lactate-driven MICU3 transcriptional activation and stabilization facilitates NET formation, contributing to MIRI development.

It has been demonstrated that glutamine is a key player in boosting endothelial cell (EC) proliferation. However, despite its importance, the role of endothelial glutaminolysis in diabetes remains largely unexplored. Our research aimed to investigate the function of glutaminolysis in ECs within the context of diabetes and to evaluate the potential therapeutic effects of salvianolic acid B (SalB) and α-ketoglutarate (α-KG) on diabetic vascular complications. Histological analysis of skin wounds in diabetic patients revealed delayed restoration of vascularization and collagen synthesis during wound healing, accompanied by decreased glutaminase 1 (GLS1) expression and reduced colocalization with the EC marker platelet-endothelial cell adhesion molecule-1 (CD31). Additionally, a significant decline in GLS1 activity and expression was observed in ECs isolated from diabetic hearts. In vitro studies using cultured ECs demonstrated that exposure to high glucose and high fat (HGHF) reduced GLS1 expression and suppressed glutaminolysis, impairing EC proliferation and tube formation. These adverse effects were mitigated by treatment with SalB or supplementation with α-KG plus nonessential amino acids (NEAAs). Among diabetic mice subjected to myocardial ischemia/reperfusion (MI/R), SalB administration or α-KG supplementation promoted myocardial revascularization and improved cardiac dysfunction. Notably, endothelial-specific GLS1 deletion in mice blocked the beneficial effects afforded by SalB but not those afforded by α-KG. Furthermore, SalB administration accelerated angiogenesis and cutaneous wound healing in diabetic mice, and these influences were removed by pharmacological inhibition of GLS1 using bis-2-(5-phenylacetamido-1,3,4-thiadiazol-2-yl) ethyl sulfide (BPTES) or genetic deletion of endothelial GLS1. These findings indicate that defective endothelial glutaminolysis contributes to impaired angiogenesis and poor ischemic tissue repair in diabetes. Improving endothelial glutaminolysis by treatment with SalB or metabolic supplementation with α-KG promotes angiogenesis and ischemic tissue repair in diabetic mice, emphasizing the possibility of GLS1 as a treatment target.

To improve the treatment outcomes for large bone defects and osteoporosis, researchers have been committed to reducing bone loss and accelerating bone regeneration through cell transplantation, biomaterial intervention, and biophysical stimulation over the past few decades. Magnetism, as a noninvasive biophysical stimulus, has been employed in the repair of the musculoskeletal system, achieving a series of promising results. In this review, we provide a retrospective analysis and perspective of research on magnetic-driven bone regeneration and functional reconstruction. This review aims to delineate safe and efficient magnetic application modalities and to summarize the potential mechanisms by which magnetism regulates the behavior of skeletal lineage cells, thereby providing insights for the expansion and translational application of magnetic-driven regenerative medicine.

Background: Osteosarcoma (OS) is a primary malignant bone tumor predominantly affecting adolescents. Chemotherapeutic agents, such as cisplatin, are commonly used in OS treatment; however, drug resistance markedly undermines treatment efficacy and contributes to reduced patient survival. The mechanisms underlying cisplatin resistance remain poorly understood. Recently, palmitoyl-protein thioesterase 1 (PPT1), a depalmitoylation enzyme, has attracted attention for its role in tumorigenesis and drug resistance. Investigating the mechanisms of PPT1 may offer new strategies to overcome resistance. Methods: This study analyzed multiple Gene Expression Omnibus datasets and utilized the OncoPredict tool to demonstrate the elevated expression of PPT1 in OS and its critical role in cisplatin resistance. By combining single-cell analysis with in vitro and in vivo experiments, we explored how PPT1 influences OS development through depalmitoylation and assessed the antitumor effects of the PPT1 inhibitor Ezurpimtrostat (GNS561), as well as its synergistic effects when combined with cisplatin. Results: We demonstrated that Sprouty 4 (SPRY4) undergoes a dynamic palmitoylation cycle regulated by zinc finger DHHC-type palmitoyl transferase 7 (ZDHHC7) and PPT1, which modulates mitogen-activated protein kinase (MAPK) signaling and subsequently affects tumor cell proliferation, migration, apoptosis, and drug resistance. Further validation confirmed the effectiveness of the PPT1 inhibitor GNS561 in overcoming cisplatin resistance. Notably, GNS561 exhibited a significant synergistic effect when used in combination with cisplatin, greatly enhancing the sensitivity of cisplatin-resistant cells. Conclusion: This study highlights the pivotal role of PPT1 in OS resistance mechanisms. PPT1 and ZDHHC7 regulate SPRY4 through a dynamic palmitoylation–depalmitoylation cycle that modulates MAPK signaling activation and contributes to OS cell proliferation, migration, and drug resistance. As a PPT1 inhibitor, GNS561 not only inhibits OS cell proliferation but also demonstrates synergistic effects with cisplatin, significantly enhancing cisplatin sensitivity in resistant cells and promoting apoptosis. Our findings offer a novel approach for targeting PPT1 in therapeutic strategies. GNS561 holds promise as an adjunctive therapy when combined with cisplatin, potentially overcoming resistance and improving efficacy, thereby enhancing the prognosis for OS patients. Future studies should further investigate the clinical potential of GNS561 and optimize OS treatment strategies.

Bedside monitoring of brain function in severely brain-injured patients remains a critical clinical challenge. We demonstrate the translational potential of functional ultrasound (fUS) imaging for this purpose. In 6 comatose patients (Glasgow coma scale ≤ 8) with cranial windows after decompressive craniectomy, we used a 7.8-MHz transducer optimized for cortical depths of 1.5 to 4 cm to perform real-time fUS during auditory stimulation. We observed task-related increases in regional cerebral blood flow (rCBF) in relevant brain regions (P < 0.001, t test), which correlated with subsequent neurological recovery at 9-month follow-up. These findings establish fUS as a sensitive and portable tool for bedside brain function assessment, offering potential for improved prognostication, treatment guidance, and development of targeted rehabilitative strategies.

Nitrite reductases (NiRs) are natural enzymes that facilitate the reduction of nitrite. They are essential for the microbial nitrogen cycle and play a vital role in regulating numerous physiological and pathological processes associated with nitric oxide (NO) in living organisms. By the merits of protein engineering, a variety of artificial NiR mimics have been developed. These include traditional artificial proteins, metal-azacycle complexes, and nanozymes such as metal, metal oxide/sulfide nanoparticles, metal-organic frameworks, bioinorganic nanohybrids, and advanced single-atom nanozymes. This development marks an important milestone in broadening the application of enzyme-like catalytic nitrite reduction across various fields, such as biomedicine, biosensing, food science, and environmental science. In this review, we first outline the different types of NiRs, along with their active center structures and catalytic mechanisms, drawing from recent research and discoveries. We then classify the reported NiR mimic materials, discussing their active center structures and enzyme-like catalytic mechanisms. Additionally, we explore the potential future applications and challenges facing NiR mimics in the field of biomedicine.

Malignant and premalignant ocular surface tumors (OSTs) can be sight-threatening or even life-threatening if not diagnosed and treated promptly. Artificial intelligence holds great promise for the early detection of these diseases. However, training traditional convolutional neural networks (CNNs) for this task presents challenges due to the lack of large, well-annotated datasets containing OST images labeled according to histopathological results. Here, we introduce the ocular surface pretrained model (OSPM), a domain-specific pretrained model designed to address the scarcity of labeled data. OSPM is constructed utilizing self-supervised learning on approximately 0.76 million unlabeled ocular surface images from 10 clinical centers across China and can be readily adapted to the OST classification task. We then develop and evaluate an OSPM-enhanced classification model (OECM) using 1,455 OST images labeled with histopathological diagnoses to differentiate between malignant, premalignant, and benign OSTs. OECM achieves excellent performance with AUROCs ranging from 0.891 to 0.993 on internal, external, and prospective test datasets, significantly outperforming the traditional CNN models. OECM demonstrated performance comparable to that of senior ophthalmologists and increased the diagnostic accuracy of junior ophthalmologists. Greater label efficiency was observed in OECM compared to CNN models. Our proposed model has high potential to enhance the early detection and treatment of malignant and premalignant OSTs, thereby reducing cancer-related mortality and optimizing functional outcomes.

Autoimmune kidney diseases (AIKDs) depict a range of disorders involving immune-mediated damage to the kidneys, where conventional biologic therapies involving monoclonal antibodies often prove insufficient because of persistent autoreactive B cell reservoirs in lymphoid organs and inflammatory tissues. The appearance of chimeric antigen receptor (CAR)-T cell therapies targeting B cells has shown transformative potential, with recent clinical trials showing the remarkable efficacy of anti-CD19 CAR-T cells in achieving profound B cell depletion, reducing immune complex deposition, and ameliorating renal inflammation in AIKDs. While these results highlight the potential of CAR-T cell therapy in facilitating immune reset and overcoming treatment resistance, further clinical investigations are imperative to establish its long-term safety and sustained therapeutic benefits. This review synthesizes current evidence on CAR-T cell applications in AIKDs, discusses critical considerations for clinical translation, identifies existing limitations and challenges, and proposes strategic directions for therapeutic optimization and advancement.

Antiangiogenesis gene therapy based on adeno-associated virus (AAV) vectors represents a promising advancement in the treatment of neovascular age-related macular degeneration (nAMD), providing an alternative to antibody-based therapies. However, the development of a safe and effective AAV vector capable of precisely targeting neovascularization and choroidal leakage remains a critical unmet need. In the present study, we engineered a novel intravitreally administered AAV vector with retinal-pigment-epithelium (RPE)-specific tropism. This vector demonstrated robust and localized gene expression in RPE cells while maintaining a favorable safety profile. The RPE-tropic AAV vector delivered a dual-acting antibody against vascular endothelial growth factor (VEGF) and angiopoietin-2 (ANG-2), exhibiting strong therapeutic efficacy and tolerability in both rodent and nonhuman primate choroidal neovascularization models. Based on the promising preclinical data, a single-center, single-arm, investigator-initiated trial (ChiCTR2400085329) was conducted to assess its safety and efficacy in patients with nAMD. The RPE-tropic AAV vector expressing anti-VEGF-A and anti-ANG-2 effectively alleviated disease progression and was well tolerated in the clinical setting. These findings highlight the potential of this engineered AAV-RPE capsid as a versatile platform for gene therapy, not only for nAMD but also for other ocular diseases involving RPE cells.

This commentary highlights the importance and implications of the study “Quadruple-band synglisis enables high thermoelectric efficiency in earth-abundant tin sulfide crystals”, led by C. Chang and L. Zhao, published in Science. They improved the thermoelectric efficiency by activating quadruple-band synglisis and facilitating carrier transport in tin sulfide crystals, and successfully developed an optical pump–terahertz probe technique in reflection mode to diagnose the carrier dynamics for high-conductivity bulk thermoelectric materials. This study inspires mutual promotion and complementary development between the fields of thermoelectrics and terahertz technology.