技术资料

Chronic myeloid leukemia (CML) remains a therapeutic challenge,particularly in patients who develop resistance to standard tyrosine kinase inhibitors (TKIs) such as imatinib. Here,we present the first demonstration of the potent anti-leukemic activity of the histone deacetylase (HDAC) inhibitor martinostat in both TKI-sensitive and TKI-resistant CML. Structural and biochemical analyses confirmed the efficient and selective binding of martinostat to HDAC isoenzyme ligand-binding pockets,resulting in histone and tubulin hyperacetylation in both imatinib-sensitive and resistant CML cells,outperforming vorinostat,a clinically used HDAC inhibitor (HDACi). It selectively impaired CML cell proliferation and viability and induced apoptosis across various CML models,including resistant cell models and patient blasts,with minimal toxicity to healthy cells and low developmental toxicity in zebrafish. In addition to its single-agent efficacy,martinostat demonstrated enhanced anticancer effects when combined with imatinib,both in vitro and in vivo,significantly reducing tumor growth in resistant CML xenograft models. Mechanistically,mRNA-seq data showed that martinostat disrupted key survival signaling pathways and amplified apoptotic responses,contributing to its anticancer activity. These findings highlight the potential of martinostat as a selective,low-toxicity HDACi that,combined with TKIs,could provide an effective strategy to overcome drug resistance in CML and improve therapeutic outcomes. The online version contains supplementary material available at 10.1186/s13148-025-01921-0. View Publication

The irreversible erosion of X-chromosome inactivation (XCI) due to repression of the long non-coding RNA XIST presents a major challenge for disease modeling and raises safety concerns for the clinical application of female human pluripotent stem cells (hPSCs) due to the aberrant overexpression of X-linked genes. While Cas9-mediated non-homologous end joining (NHEJ) targeting the XIST promoter can induce DNA demethylation and restore XCI by reactivating XIST,its efficiency remains low. Here,we introduce a highly efficient strategy for XIST reactivation by combining TP53 inhibition with suppression of DNA methylation maintenance during Cas9-mediated NHEJ. This dual-inhibition approach increased the proportion of XIST -positive hPSCs from ~ 5 to ~ 43.7%,providing a robust method for stabilizing XCI in female hPSCs for diverse applications. The online version contains supplementary material available at 10.1186/s13287-025-04501-4. View Publication

The hypoxic tumor microenvironment,particularly hypoxia-conditioned cancer-associated fibroblasts (CAFs),drives breast cancer (BC) progression and therapy resistance. However,the molecular mechanisms linking hypoxic CAFs to BC plasticity and chemoresistance remain elusive. Primary CAFs were isolated from high-grade BC tissues (Grade III) and characterized (α-SMA⁺/CD34⁻/pan-CK⁻),with normal fibroblasts (NFs) from reduction mammoplasty as controls. Hypoxic CAF-derived exosomal circSTAT3 stability was validated using RNase R resistance and actinomycin D assays. Exosomes were characterized via transmission electron microscopy (TEM),dynamic light scattering (DLS),and marker profiling (CD63⁺/TSG101⁺/Alix⁺,calnexin⁻). Functional effects of hypoxic CAF exosomes on TNBC cells (MDA-MB-231,SUM159) were assessed through proliferation/migration assays,stemness/epithelial-mesenchymal transition (EMT) marker analysis,and siRNA-mediated circSTAT3 knockdown. Mechanistic studies employed luciferase assays and RNA immunoprecipitation (RIP). Chemoresistance was evaluated by cisplatin half-maximal inhibitory concentration (IC₅₀). In vivo tumor growth and stemness enrichment were analyzed in xenografts. Clinical validation used BC tissues (n = 60) and plasma exosomes from BC patients (n = 40) versus healthy controls (n = 25). Hypoxic CAF-derived exosomes efficiently transferred circSTAT3 to TNBC cells,promoting proliferation,migration,EMT,and stemness marker expression. SiRNA-mediated circSTAT3 knockdown reversed these effects. Mechanistically,circSTAT3 acted as a competitive endogenous RNA (ceRNA),sponging miR-671-5p to derepress NOTCH1. Hypoxic CAF exosomes increased cisplatin IC₅₀ in TNBC cells,while circSTAT3 depletion restored chemosensitivity. In vivo,hypoxic CAF exosomes accelerated tumor growth,enriched CD44⁺/NOTCH1⁺ populations,and elevated circulating exosomal circSTAT3. Clinically,circSTAT3 was significantly upregulated in advanced BC tissues (p < 0.01) and patient plasma exosomes (p < 0.01),correlating with lymph node metastasis. This study identifies a hypoxia-driven feedforward loop wherein CAF-derived exosomal circSTAT3 promotes TNBC stemness and chemoresistance via miR-671-5p/NOTCH1 signaling. CircSTAT3 redefines stromal-tumor crosstalk as a circRNA-driven process and serves as both a circulating non-invasive biomarker and a promising therapeutic target to disrupt stromal-mediated resistance in aggressive TNBC. The online version contains supplementary material available at 10.1186/s12967-025-06794-8. View Publication

HexaBody-CD27 (GEN1053/BNT313) is an investigational novel agonistic CD27 antibody engineered to enhance T-cell costimulation and promote antitumor immunity. Through the introduction of a hexamerization-enhancing mutation in the IgG Fc domain,HexaBody-CD27 was designed to drive clustering and activation of CD27 via intermolecular Fc:Fc interactions between membrane-bound antibodies,independent of crosslinking by FcγR-bearing cells. HexaBody-CD27 carries an Fc-silencing mutation to prevent T-cell depletion through Fc-mediated effector functions. In vitro,HexaBody-CD27 induced CD27 receptor signaling independent of FcγR-mediated crosslinking in a reporter assay. It also enhanced T-cell proliferation,cytotoxic activity and proinflammatory cytokine secretion in primary human lymphocytes. In contrast to benchmark IgG1 CD27 antibodies,HexaBody-CD27 did not induce phagocytosis of T cells in vitro. HexaBody-CD27 promoted ex vivo tumor infiltrating lymphocyte (TIL) expansion in non-small cell lung cancer (NSCLC) specimens,in particular of CD8 + TILs. The combination of HexaBody-CD27 with an anti-PD-1 antibody enhanced T-cell proliferation,cytokine secretion,and cytotoxic activity in vitro compared to either compound alone. In conclusion,HexaBody-CD27 enhanced T-cell activation and effector functions in an FcγR-crosslinking-independent manner,without inducing T-cell depletion. The immune agonist activity of HexaBody-CD27 was potentiated in combination with PD-1 blockade. View Publication

Arteriovenous malformations (AVMs) are congenital vascular anomalies defined by abnormal direct connections between arteries and veins due to their complex structure or endovascular approaches. Pharmacological strategies targeting the underlying molecular mechanisms are thus gaining increasing attention in an effort to determine the mechanism involved in AVM regulation. In this study,we examined 30 human tissue samples,comprising 10 vascular samples,10 human fibroblasts derived from AVM tissue,and 10 vascular samples derived from healthy individuals. The pharmacological agents thalidomide,U0126,and rapamycin were applied to the isolated endothelial cells (ECs). The pharmacological treatments reduced the proliferation of AVM ECs and downregulated miR-135b-5p,a biomarker associated with AVMs. The expression levels of angiogenesis-related genes,including VEGF,ANG2,FSTL1,and MARCKS,decreased; in comparison,CSPG4,a gene related to capillary networks,was upregulated. Following analysis of these findings,skin samples from 10 AVM patients were reprogrammed into induced pluripotent stem cells (iPSCs) to generate AVM blood vessel organoids. Treatment of these AVM blood vessel organoids with thalidomide,U0126,and rapamycin resulted in a reduction in the expression of the EC markers CD31 and α-SMA. The establishment of AVM blood vessel organoids offers a physiologically relevant in vitro model for disease characterization and drug screening. The authors of future studies should aim to refine this model using advanced techniques,such as microfluidic systems,to more efficiently replicate AVMs’ pathology and support the development of personalized therapies. View Publication

The recently identified proton-activated chloride (PAC) channel is ubiquitously expressed,and it regulates several proton-sensitive physiological and pathophysiological processes. While the PAC channel is activated by strong acids due to the binding of protons to extracellular binding sites,here,we describe the way in which weak acids inhibit the PAC channel by a mechanism involving a distinct extracellular binding site. Whole-cell patch clamp was performed on wildtype HEK293T cells,PAC-knockout HEK293 cells expressing human (h)PAC mutant constructs,and on hiPSC-derived cardiomyocytes. Proton-induced cytotoxicity was examined in HEK293T cells. Acetic acid inhibited endogenous PAC channels in HEK 293T cells in a reversible,concentration-dependent,and pH-dependent manner. The inhibition of PAC channels was also induced by lactic acid,propionic acid,itaconic acid,and β-hydroxybutyrate. Weak acids also inhibited recombinant wildtype hPAC channels and PAC-like currents in hiPSC-derived cardiomyocytes. Replacement of the extracellular arginine 93 by an alanine (hPAC–Arg93Ala) strongly reduced the inhibition by some weak acids,including arachidonic acid. Although lactic acid inhibited PAC,it did not reduce the proton-induced cytotoxicity examined in wildtype HEK 293 cells. To conclude,weak acids inhibit PAC via an extracellular mechanism involving Arg93. These data warrant further investigations into the regulation of the PAC channel by endogenous weak acids. View Publication

The present study focused on the culture medium of induced pluripotent stem cells (iPSCs) prior to the use of cardiomyocytes differentiation induction medium (pre-culture medium). Seven types (Nos. 1-7) of StemFit AK03 medium (Ajinomoto) for clinical iPSCs with varying compositions were prepared as pre-culture medium. The cardiac muscle troponin T (cTnT) positivity of No. 1 (StemFit AK03 medium) was 84%,No. 3 (similar to E8 medium) was 89%,No. 2 (similar to E8 medium) was 91%,No. 5 (similar to EB Formation medium) was 95%,when using differentiation induction medium prepared with known components available for clinical cell production. The formation of cardiac tissues was assessed by evaluating the expression levels of specific markers,including cTnT,atrial natriuretic peptides (ANP),and pro-B-type natriuretic peptide (proBNP). The results demonstrated that cardiac tissue with high protein expression levels of cTnT and ANP was formed when similar to E8 medium as pre-culture medium. The online version contains supplementary material available at 10.1038/s41598-025-13259-x. View Publication

Fatty-acid-hydroxylase-associated neurodegeneration (FAHN) is a rare neurodegenerative disorder caused by loss-of-function mutations in the FA2H gene,leading to impaired enzymatic activity and resulting in myelin sheath instability,demyelination,and axonal degeneration. In this study,we established a human in vitro model using neurons and oligodendrocytes derived from induced pluripotent stem cells (hiPSCs) of a FAHN patient. This coculture system enabled the investigation of myelination processes and myelin integrity in a disease-relevant context. Analyses using immunofluorescence and Western blot revealed impaired expression and localisation of key myelin proteins in oligodendrocytes and cocultures. FA2H-deficient cells showed reduced myelination,shortened internodes,and disrupted formation of the nodes of Ranvier. Additionally,we identified autophagy defects—a hallmark of many neurodegenerative diseases—including reduced p62 expression,elevated LC3B levels,and impaired fusion of autophagosomes with lysosomes. This study presents a robust hiPSC-based model to study FAHN,offering new insights into the molecular pathology of the disease. Our findings suggest that FA2H mutations compromise both the structural integrity of myelin and the efficiency of the autophagic machinery,highlighting potential targets for future therapeutic interventions. View Publication

In bone marrow,cell numbers are balanced between production and loss. After chemotherapy,blood cell counts decrease initially but later recover as hematopoietic progenitor cells expand,although the mechanisms underlying this recovery are still unclear. We investigated the influence of red blood cells (RBCs) on hematopoietic stem cell (HSC) function during bone marrow recovery. Following chemotherapy,RBC concentrations in bone marrow peaked on day 5 posttreatment,coinciding with the recovery of hematopoiesis. Coculture of HSCs with RBCs resulted in a significant increase in hematopoiesis. Direct contact between RBCs and HSCs was essential for enhancement of hematopoiesis,and HSCs precultured with RBCs resulted in greater numbers of donor‐derived mature hematopoietic cells after transplantation. RNA‐sequencing analysis showed that Hes1 was the most significantly upregulated transcription factor in RBC coculture,and the response to RBC‐induced hematopoiesis of Hes1‐deficient HSCs was reduced. These findings imply a role of RBCs and Hes1 in the enhancement of hematopoietic recovery following bone marrow stress. View Publication

Cancer research has long focused on mutations in normal body cells,but this approach has not produced major breakthroughs for most cancers. Our study explores a different concept that some aggressive cancers may actually arise from early reproductive cells called primordial germ cells,which normally develop into eggs and sperm. We created a new experimental model showing how a virus can transform human primordial germ cell-like cells into virus-positive Merkel cell carcinoma,a rare but deadly skin cancer. This model shows that cancers can emerge through changes in developmental states rather than relying solely on genetic mutations. By linking cancer development to early germ cells,our findings suggest a unifying explanation for both germ cell cancers and body cancers. This new perspective may guide more effective approaches to study,diagnose,and treat cancer by focusing on early human development rather than only DNA mutations and later developmental stages. View Publication

Despite recent approval of monoclonal antibodies that reduce amyloid (Aβ) accumulation,the development of disease-modifying strategies targeting the underlying mechanisms of Alzheimer's disease (AD) is urgently needed. We demonstrate that mitochondrial complex I (mtCI) represents a druggable target,where its weak inhibition activates neuroprotective signalling,benefiting AD mouse models with Aβ and p-Tau pathologies. Rational design and structure‒activity relationship studies yielded mtCI inhibitors profiled in a drug discovery funnel designed to address safety,selectivity,and efficacy. The lead compound C458 is highly protective against Aβ toxicity,has favourable pharmacokinetics,and minimal off-target effects. C458 exhibited excellent brain penetrance,activating neuroprotective pathways with a single dose. Preclinical studies in APP/PS1 mice were conducted using functional tests,metabolic assessment,in vivo 31 P-NMR spectroscopy,blood cytokine panels,ex vivo electrophysiology,and Western blotting. Chronic oral administration improved long-term potentiation,reduced oxidative stress and inflammation,and enhanced mitochondrial biogenesis,antioxidant signalling,and cellular energetics. Efficacy against Aβ and p-Tau was confirmed in human organoids. These studies provide further evidence that the restoration of mitochondrial function in response to mild energetic stress represents a promising disease-modifying strategy for AD. This research was supported by grants from NIH AG 5549-06,NS1 07265,AG 062135,UG3/UH3 NS 113776,and ADDF 291204 (all to ET); U19 AG069701 (to TK); the Alzheimer’s Association Research Fellowship grant 23AARF-1027342 (to TKON). View Publication

Tissue remodeling is a key feature of allergic rhinitis (AR),but its underlying molecular mechanisms remain unclear. Lysyl oxidase-like 2 (LOXL2),a regulator of tissue remodeling,has not been studied in AR. Proteomic analysis was performed on nasal mucosal tissues from 8 AR patients and 8 healthy controls (HCs) to identify differentially expressed proteins (DEPs). The top three upregulated DEPs and their association with tissue remodeling markers were validated by immunofluorescence,Western blot,and RT-qPCR in an independent cohort of 30 AR patients and 30 HCs. In vitro,human nasal epithelial cells (HNECs) were treated with IL-4,and the effects of candidate protein inhibitors on remodeling were assessed. An AR mouse model was used to evaluate the impact of these inhibitors on nasal inflammation and remodeling. Proteomic analysis revealed a disease-specific protein expression profile in the nasal mucosa of AR patients,with the top three upregulated proteins being LOXL2,TGF-β1,and TIRAP. Tissue validation showed that LOXL2 was significantly upregulated in the nasal mucosa of AR patients compared to HCs and was significantly correlated with EMT markers (TGF-β1,α-SMA,and E-cadherin). In vitro,IL-4 stimulation significantly upregulated LOXL2,TGF-β1,and α-SMA,while downregulating E-cadherin in a dose-dependent manner in human nasal epithelial cells. These effects were reversed by inhibition of LOXL2. Further investigations demonstrated that LOXL2 promotes tissue remodeling through activation of the TGF-β1/Smad signaling pathway. In the AR mouse model,LOXL2 inhibitors significantly reduced nasal mucosal inflammation and tissue remodeling. Our proteomic analysis suggests that LOXL2 may be involved in the pathological remodeling processes of AR,potentially through modulation of the TGF-β1/Smad signaling pathway. These findings provide preliminary evidence that LOXL2 could serve as a candidate biomarker and a possible therapeutic target in AR,warranting further investigation. View Publication