技术资料

Lipid dyshomeostasis and tau pathology are present in frontotemporal lobar degeneration (FTLD) and Alzheimer’s disease (AD). However,the relationship between lipid dyshomeostasis and tau pathology remains unclear. We report that GRAM Domain Containing 1B (GRAMD1B),a nonvesicular cholesterol transporter,is increased in excitatory neurons of human neural organoids (HNOs) with the MAPT R406W mutation. Human FTLD,AD cases,and PS19 tau mice also have increased GRAMD1B expression. We show that overexpression of GRAMD1B increases levels of free cholesterol,lipid droplets,and impairs autophagy flux. Modulating GRAMD1B in iPSC-derived neurons also alters key autophagy-related components such as PI3K,phospho-AKT,and p62,as well as phosphorylated tau,and CDK5R1. Blocking GRAMD1B function decreases free cholesterol and lipid droplets. Knocking down GRAMD1B additionally reduces phosphorylated tau,and CDK5R1 expression. Our findings elucidate the role of GRAMD1B in the nervous system and highlight its relevance to FTLD and AD. Subject terms: Diseases of the nervous system,Ageing View Publication

The CEBPA transcription factor is frequently mutated in acute myeloid leukemia (AML). Mutations in the CEBPA gene,which are typically biallelic,result in the production of a shorter isoform known as p30. Both the canonical 42-kDa isoform (p42) and the AML-associated p30 isoform bind chromatin and activate transcription,but the specific transcriptional programs controlled by each protein and how they are linked to a selective advantage in AML is not well understood. Here,we show that cells expressing the AML-associated p30 have reduced baseline inflammatory gene expression and display altered dynamics of transcriptional induction in response to LPS,consequently impacting cytokine secretion. This confers p30-expressing cells an increased resistance to the adverse effects of prolonged exposure to inflammatory signals. Mechanistically,we show that these differences primarily arise from the differential regulation of AP-1 family proteins. In addition,we find that the impaired function of the AP-1 member ATF4 in p30-expressing cells alters their response to ER stress. Collectively,these findings uncover a link between mutant CEBPA,inflammation and the stress response,potentially revealing a vulnerability in AML. Subject terms: Gene regulation,Acute myeloid leukaemia,Transcriptional regulatory elements,Epigenetics in immune cells View Publication

Ceramides are bioactive sphingolipids that have physiological effects on inflammation,apoptosis,and mitochondrial dysfunction. They may play a critical role in the harm of ischemia/reperfusion (IR). Ceramides and IR injury are not well-studied,and there is a lack of human data. Current studies aimed to investigate the role of ceramide buildup in cardiomyocytes (CMs) death using CMs derived from human induced pluripotent stem cell (hiPSC) as a model for simulating IR injury in vitro. In our model,serum- and glucose-free media was used to expose hiPSC-derived CMs to hypoxia (3% O 2 ) for 6 h (hrs),followed by reoxygenation (20% O 2 ) for 16 h. In contrast to normoxia (control) or hypoxia (ischemia),our data showed that following IR,there was an increase in the formation of mitochondrial superoxide and the mRNA levels of genes regulating ceramide synthesis,such as CerS2 and CerS4 in CMs. Further,there was a considerable rise in the levels of total ceramide,long-chain (C16:0,C18:0,and C18:1),and very long-chain (C22:0 and C24:1) ceramide species in CMs following reperfusion in comparison to control or ischemic CMs. Interestingly,compared to CMs exposed to IR without inhibitor,our data showed that inhibition of ceramide formation with fumonisin B1 (FB1) significantly lowered ceramide levels,reduced apoptosis,improved mitochondrial function,and enhanced survival of CMs exposed to IR. Furthermore,we used a transgenic mouse model,in which the CerS2 gene was overexpressed in the CMs of α-MHC-CerS2 mice,to validate the basic idea that ceramide contributes to heart disease in vivo. Our results showed that the heart tissues of α-MHC-CerS2 mice had significant levels of long-chain and very long-chain ceramides,which causes increased apoptosis,proinflammatory cytokines,interstitial inflammatory cell infiltration,and collagen deposition. Results from both in vitro and in vivo experiments show that ceramides have a significant role in either mediating or inducing damage to CMs. Additionally,in vitro findings show that ceramide reduction improves the outcome of IR injury by lowering intracellular Ca 2+ [Ca 2+ ] i concentration and improves mitochondrial function changes during IR. The online version contains supplementary material available at 10.1186/s13287-025-04340-3. View Publication

Toll-interacting protein (Tollip) suppresses excessive pro-inflammatory signaling,but its function in airway epithelial responses to IL-13,a key mediator in allergic diseases,remains unclear. This study investigates Tollip knockdown (TKD) effects in primary human airway epithelial cells using single-cell RNA sequencing,providing the first single-cell analysis of TKD and the first exploring its interaction with IL-13. IL-13 treatment upregulated key genes,including SPDEF,MUC5AC,POSTN,ALOX15,and CCL26,confirming IL-13’s effects and validating our methods. IL-13 reduced TNF-α signaling and epithelial-mesenchymal transition in certain cell types,suggesting a dual role in promoting type 2 inflammation while suppressing Th1-driven inflammation. Tollip deficiency alone significantly amplified TNF-α signaling and inflammatory pathways in goblet,club,and suprabasal cells. Comparisons between TKDIL13 vs IL13 and TKD vs CTR revealed that IL-13 does not substantially alter Tollip deficiency response in most cell types,reinforcing findings in TKD vs CTR. Tollip deficiency alters the response to IL-13 in a cell-type-specific manner,strongly downregulating TNF-α signaling in goblet cells but only weakly in basal and club cells. Tollip deficiency enhances IL-13’s suppression of Th1 inflammatory responses in goblet cells. These novel insights in Tollip-IL-13 interactions offer potential therapeutic targets for asthma and related diseases. The online version contains supplementary material available at 10.1186/s13104-025-07255-7. View Publication

Mounting evidence indicates that exosomes derived from human umbilical cord mesenchymal stem cells (hucMSCs-exosomes) combine the advantages of hucMSC pluripotency with their nanoscale dimensions,enhancing their clinical potential through prolonged circulation half-life. Despite these promising characteristics,research on their immunological toxicity remains insufficient. This study focuses on the impact of hucMSC-exosomes on the general toxicity and immunopathological indicators. When mice received tail vein injections of 6 × 10 10 hucMSC-exosomes particles,we observed no significant changes in body weight,feed intake,blood composition,organ indices,or histopathological findings throughout the 14 days observation period. Similarly,blood levels of immunoglobulins,cytokines,and lymphocyte subpopulations remained stable. The hucMSC-exosomes produced no detectable negative effects on immune organs including the thymus,spleen,and bone marrow. These findings indicate that intravenous administration of 6 × 10 10 particles of hucMSC-exosomes appears relatively safe at the murine level. This assessment of safety and immunological impact following intravenous hucMSC-exosomes infusion offers experimental support for potential clinical applications and future analyses in this field. View Publication

Tumor-associated macrophages (TAMs) are key promoters of inflammatory breast cancer (IBC),the most aggressive form of breast cancer. The receptor tyrosine kinase AXL is highly expressed in various cancer types,including IBC,but its role in TAMs remains unexplored. We examined the effects of AXL inhibitor TP-0903 on tumor growth and tumor microenvironment (TME) component M2 macrophages (CD206 + ) in IBC and triple-negative breast cancer mouse models using flow cytometry and immunohistochemical staining. Additionally,we knocked out AXL expression in human THP-1 monocytes and evaluated the effect of AXL signaling on immunosuppressive M2 macrophage polarization and IBC cell growth and migration. We then investigated the underlying mechanisms through RNA sequencing analysis. Last,we performed CIBERSORT deconvolution to analyze the association between AXL expression and tumor-infiltrating immune cell types in tumor samples from the Inflammatory Breast Cancer International Consortium. We found that inhibiting the AXL pathway significantly reduced IBC tumor growth and decreased CD206 + macrophage populations within tumors. Mechanistically,our in vitro data showed that AXL promoted M2 macrophage polarization and enhanced the secretion of immunosuppressive chemokines,including CCL20,CCL26,and epiregulin,via the transcription factor STAT6 and thereby accelerated IBC cell growth and migration. RNA sequencing analysis further indicated that AXL signaling in immunosuppressive M2 macrophages regulated the expression of molecules and cytokines,contributing to an immunosuppressive TME in IBC. Moreover,high AXL expression was correlated with larger populations of immunosuppressive immune cells but smaller populations of immunoactive immune cells in tissues from patients with IBC. AXL signaling promotes IBC growth by inducing M2 macrophage polarization and driving the secretion of immunosuppressive molecules and cytokines via STAT6 signaling,thereby contributing to an immunosuppressive TME. Collectively,these findings highlight the potential of targeting AXL signaling as a novel therapeutic approach for IBC that warrants further investigation in clinical trials. The online version contains supplementary material available at 10.1186/s13058-025-02015-8. View Publication

Directed evolution is a process of mutation and artificial selection to breed biomolecules with new or improved activity. Directed evolution platforms are primarily prokaryotic or yeast-based,and stable mammalian systems have been challenging to establish and apply. To this end,we develop PROTein Evolution Using Selection (PROTEUS),a platform that uses chimeric virus-like vesicles to enable extended mammalian directed evolution campaigns without loss of system integrity. This platform is stable and can generate sufficient diversity for directed evolution in mammalian systems. Using PROTEUS,we alter the doxycycline responsiveness of tetracycline-controlled transactivators,generating a more sensitive TetON-4G tool for gene regulation with mammalian-specific adaptations. PROTEUS is also compatible with intracellular nanobody evolution,and we use it to evolve a DNA damage-responsive anti-p53 nanobody. Overall,PROTEUS is an efficient and stable platform to direct evolution of biomolecules within mammalian cells. Subject terms: Synthetic biology,Synthetic biology,Molecular evolution,Next-generation sequencing View Publication

Acute myeloid leukemia (AML) remains a therapeutic challenge due to drug resistance and relapse. Selinexor,an XPO1 inhibitor,shows limited efficacy as monotherapy,necessitating combination strategies. JQ1,a BET inhibitor targeting MYC,may synergize with Selinexor to enhance antileukemic effects. AML cell lines,primary patient samples,and xenograft models (MLL-AF9,CDX,PDX) were treated with Selinexor and JQ1 alone or combined. Synergy was assessed via viability assays (Compusyn/SynergyFinder),apoptosis (flow cytometry/Western blot),and C-MYC suppression (qPCR/CRISPR). In vivo efficacy was evaluated by tumor burden (flow cytometry) and survival. The combination demonstrated strong synergy (CI < 1,HSA > 10) across AML models,with > 80% inhibition in cell lines and primary samples. Mechanistically,it suppressed C-MYC (protein/mRNA),induced apoptosis (cleaved PARP),and arrested cell cycle. In vivo,the combination reduced leukemic burden in bone marrow,spleen,and liver,extending survival in xenografts. PDX models confirmed efficacy in primary AML cells. Selinexor and JQ1 synergistically target AML by dual C-MYC inhibition,offering a promising strategy to overcome resistance. Further clinical evaluation is warranted. The online version contains supplementary material available at 10.1186/s12967-025-06525-z. View Publication

This study investigates the use of silver nanoparticles as a potential new treatment for colorectal cancer. Colorectal cancer is one of the most common cancers worldwide,and finding more effective treatments is essential. The researchers tested silver nanoparticles AgNPs with two different surface coatings to see how they affect cancer cells compared to healthy cells. One type of nanoparticles showed significant effects,reducing cancer cell growth and inducing cell death,while the other had minimal impact. These findings suggest that modifying the surface of nanoparticles could help target cancer cells more specifically,leading to treatments that are both more effective and have fewer side effects. This research could pave the way for new therapies for colorectal cancer and other types of cancer,ultimately improving patient outcomes and advancing cancer treatment strategies. View Publication

Enhanced glycolysis plays a pivotal role in fueling the aberrant proliferation,survival and therapy resistance of acute myeloid leukemia (AML) cells. Here,we aimed to elucidate the extent of glycolysis dependence in AML by focusing on the role of lactate dehydrogenase A (LDHA),a key glycolytic enzyme converting pyruvate to lactate coupled with the recycling of NAD + . We compared the glycolytic activity of primary AML patient samples to protein levels of metabolic enzymes involved in central carbon metabolism including glycolysis,glutaminolysis and the tricarboxylic acid cycle. To evaluate the therapeutic potential of targeting glycolysis in AML,we treated AML primary patient samples and cell lines with pharmacological inhibitors of LDHA and monitored cell viability. Glycolytic activity and mitochondrial oxygen consumption were analyzed in AML patient samples and cell lines post-LDHA inhibition. Perturbations in global metabolite levels and redox balance upon LDHA inhibition in AML cells were determined by mass spectrometry,and ROS levels were measured by flow cytometry. Among metabolic enzymes,we found that LDHA protein levels had the strongest positive correlation with glycolysis in AML patient cells. Blocking LDHA activity resulted in a strong growth inhibition and cell death induction in AML cell lines and primary patient samples,while healthy hematopoietic stem and progenitor cells remained unaffected. Investigation of the underlying mechanisms showed that LDHA inhibition reduces glycolytic activity,lowers levels of glycolytic intermediates,decreases the cellular NAD + pool,boosts OXPHOS activity and increases ROS levels. This increase in ROS levels was however not linked to the observed AML cell death. Instead,we found that LDHA is essential to maintain a correct NAD + /NADH ratio in AML cells. Continuous intracellular NAD + supplementation via overexpression of water-forming NADH oxidase from Lactobacillus brevis in AML cells effectively increased viable cell counts and prevented cell death upon LDHA inhibition. Collectively,our results demonstrate that AML cells critically depend on LDHA to maintain an adequate NAD + /NADH balance in support of their abnormal glycolytic activity and biosynthetic demands,which cannot be compensated for by other cellular NAD + recycling systems. These findings also highlight LDHA inhibition as a promising metabolic strategy to eradicate leukemic cells. The online version contains supplementary material available at 10.1186/s40170-025-00392-4. View Publication

Regulatory T (Treg)-based cell therapy holds promise for autoimmune and inflammatory diseases,yet challenges remain regarding the functional stability and persistence of transferred Tregs. Here we engineer Tregs to express a partial agonist form of IL-2 (IL-2pa) to enhance persistence while avoiding toxicity from excessive signaling. Mouse Tregs expressing wild-type IL-2 (Tregs-IL2wt) have only a transient growth advantage,limited by toxicity from likely excessive signaling. By contrast,mouse Tregs-IL2pa exhibit sustained expansion,long-term survival in immunocompetent mice for over a year,and bystander expansion of endogenous Tregs. Tregs-IL2pa maintain a stable activated phenotype,Treg-specific demethylation,and a diverse TCR repertoire. In vivo,prophylactic transfer of Tregs-IL2pa ameliorates multi-organ autoimmunity in a Treg depletion-induced mouse autoimmune model. Lastly,compared with control Treg,human Tregs-IL2pa show enhanced survival in the IL-2-depleted environment of immune-deficient mice and improved control of xenogeneic graft-versus-host disease. Our results thus show that IL-2pa self-sufficiency enhances the stability,durability and efficacy of Treg therapies in preclinical settings. Subject terms: Cell delivery,Regulatory T cells,Autoimmune diseases,Interleukins View Publication

Targeted therapy interventions using tyrosine kinase inhibitors (TKIs) provide encouraging treatment responses in patients with ALK -rearranged lung adenocarcinomas,yet resistance occurs almost inevitably. In addition to tumor cell-intrinsic resistance mechanisms,accumulating evidence suggests that cancer-associated fibroblasts (CAFs) within the tumor microenvironment contribute to therapy resistance. This study aimed to investigate CAF-driven molecular networks that shape the therapeutic susceptibility of ALK -driven lung adenocarcinoma cells. Three-dimensional (3D) spheroid co-cultures comprising ALK -rearranged lung adenocarcinoma cells and CAFs were utilized to model the tumor microenvironment. Single-cell RNA sequencing was performed to uncover transcriptional differences between TKI-treated homotypic and heterotypic spheroids. Functional assays assessed the effects of CAF-conditioned medium and CAF-secreted factors on tumor cell survival,proliferation,lipid metabolism,and downstream AKT signaling. The therapeutic potential of targeting metabolic vulnerabilities was evaluated using pharmacological inhibition of lipid metabolism and by ferroptosis induction. CAFs significantly diminished the apoptotic response of lung tumor cells to ALK inhibitors while simultaneously enhancing their proliferative capacity. Single-cell RNA sequencing identified lipogenesis-associated genes as a key transcriptional difference between TKI-treated homotypic and heterotypic lung tumor spheroids. CAF-conditioned medium and the CAF-secreted factors HGF and NRG1 activated AKT signaling in 3D-cultured ALK-rearranged lung tumor cells,leading to increased de novo lipogenesis and suppression of lipid peroxidation. These metabolic adaptations were critical for promoting tumor cell survival and fostering therapy resistance. Notably,both dual inhibition of ALK and the lipid-regulatory factor SREBP-1,as well as co-treatment with ferroptosis inducers such as erastin or RSL3,effectively disrupted the CAF-driven metabolic-supportive niche and restored sensitivity of resistant lung tumor spheroids to ALK inhibition. This study highlights a critical role for CAFs in mediating resistance to ALK-TKIs by reprogramming lipid metabolism in ALK-rearranged lung cancer cells. It suggests that targeting these metabolic vulnerabilities,particularly through inhibition of lipid metabolism or induction of ferroptosis,could provide a novel therapeutic approach to overcome resistance and improve patient outcomes. The online version contains supplementary material available at 10.1186/s40170-025-00400-7. View Publication