技术资料

Pre-clinical research on B and NK cell development relies on murine stromal cell-based systems with reduced physiological relevance and clinical applicability. A serum-free,fully humanized co-culture system utilizing human bone marrow-derived mesenchymal stromal cells (BM-MSCs) was developed to differentiate CB-CD34+ cells towards B and NK cell lineages. Differentiation dynamics were monitored via flow cytometry,with immunophenotypic analysis tracking progression from progenitors to mature cells. The system generated CD19+ IgM+ immature B cells and CD56+ CD16+ NK cells,recapitulating fetal stages of human lymphopoiesis. Serum-free media conditions ensured reproducibility and high overall yield of CD19+ B (35 ± 5.32%) and CD56+ NK (28.46 ± 7.01%) cell progenitors. Flow cytometry identified distinct population peaks,confirming temporal control over differentiation. This clinically relevant platform addresses the limitations of traditional models by providing a more physiologically accurate human microenvironment. The serum-free system supports applications in disease modeling,genotoxic compound screening,and mutational studies of hematopoiesis. By enabling scalable production of B and NK cells it aims to accelerate translational research for immunodeficiencies,cancer immunotherapy,and hematopoietic disorders. View Publication

Staphylococcal enterotoxins (SE) crosslink the MHC‐II on antigen‐presenting cells (APC) with the T‐cell receptor,inducing a polyclonal T‐cell response. Although APCs are the initial targets of SE and are critical in shaping subsequent T‐cell activation,the effects of SE on APC function remain poorly understood. This study investigates the immunomodulatory effects of staphylococcal enterotoxin A (SEA) on monocytes and their differentiation into monocyte‐derived dendritic cells (moDC) or macrophages (MDM). Transcriptomic analyses of human monocytes via RNA sequencing revealed SEA‐induced enrichment of gene pathways associated with inflammation,infection,and dermatitis,effects that were amplified in the presence of T cells. Phenotypic and functional characterization showed that SEA‐primed monocytes differentiated into MDM with an altered polarization,deviating from classical M1/M2 pathways. SEA‐primed MDM exhibited downregulation of key markers,including HLA‐DR,CD80,CD86,and PD‐L1. Functional assays demonstrated that SEA‐primed MDM pushed hyperinflammatory T‐cell responses,with significantly enhanced proliferation and IFN‐γ secretion. In contrast,following SEA‐priming,moDC retained robust antigen‐presenting capabilities and displayed enhanced expression of molecules involved in T‐cell interactions. These findings provide mechanistic insights into SEA‐mediated immune modulation,illustrating how SEA reprograms MDM functions and amplifies proinflammatory T‐cell responses. This advances our understanding of superantigen‐driven immune interactions,offering a foundation for developing therapeutic strategies to mitigate superantigen‐mediated immune conditions. Staphylococcal enterotoxin A (SEA) alters monocyte differentiation and function,while preserving T cell stimulatory capacity. SEA‐primed macrophages downregulate antigen‐presenting markers yet drive heightened T‐cell proliferation and IFN‐γ secretion. These findings reveal mechanisms of SEA‐mediated immune modulation and superantigen‐driven inflammation. View Publication

Oligodendrocytes are the myelinating cells of the central nervous system. Regulation of the early stages of oligodendrocyte development is critical to the function of the cell. Specifically,myelin sheath formation is an energetically demanding event that requires precision,as alterations may lead to dysmyelination. Fatty acid β‐oxidation has been shown to be critical for the function of oligodendrocytes. We previously showed that myeloid cell leukemia‐1 (MCL‐1),a well‐characterized anti‐apoptotic protein,is required for the development of murine oligodendrocytes in vivo. Further,MCL‐1 regulates long‐chain fatty acid β‐oxidation in cancer cells through its interaction with Acyl‐CoA synthetase long‐chain family member 1 (ACSL1),an enzyme responsible for the conversion of free long‐chain fatty acids into fatty acyl‐CoA esters. Here,we introduce an in vitro system to isolate human stem cell‐derived oligodendrocyte progenitor cells (OPCs) and investigate the involvement of MCL‐1 during human oligodendrocyte development. Using this system,we pharmacologically inhibited MCL‐1 in OPCs to investigate its non‐apoptotic function at this developmental stage. We also used a motor neuron‐oligodendrocyte co‐culture system to examine the downstream effects of MCL‐1 at later developmental stages when oligodendrocytes begin to contact axons and generate myelin. We demonstrate that the mitochondrial network changes in human oligodendrocyte development resemble those reported in mouse tissue. Our findings point to MCL‐1 as a critical factor essential for proper oligodendrocyte morphogenesis. A unified model of oligodendrocyte differentiation from human embryonic stem cells revealed that MCL‐1 is critical for regulating the expression of oligodendrocyte‐related genes and the morphogenesis of myelinating oligodendrocytes. View Publication

Hypertrophic cardiomyopathy (HCM) is a common and deadly cardiac disease characterized by enlarged myocytes,increased myocardial wall thickening,and fibrosis. A majority of HCM cases are associated with mutations in the β-myosin heavy chain (MYH7) converter domain locus,which leads to varied pathophysiological and clinical manifestations. Using base-editing technology,we generated mutant human-induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) harboring HCM-causing myosin converter domain mutations (MYH7 c.2167C>T [R723C]; MYH6 c.2173C>T [R725C]) to define HCM pathogenesis in vitro. In this study,we integrated transcriptomic analysis with phenotypic and molecular analyses to dissect the HCM disease mechanisms using MYH6/7 myosin mutants. Our KEGG analysis of bulk RNA-sequencing data revealed significant upregulation of transcripts associated with HCM in the mutant hiPSC-CMs. Further,in-depth transcriptomic analysis using Gene-Ontology (GO-term) analysis for biological process showed upregulation of several transcripts associated with heart development and disease. Notably,our analysis showed robust upregulation of cytoskeletal transcripts,including actin-cytoskeleton networks,sarcomere components,and other structural proteins in the mutant CMs. Furthermore,cellular and nuclear morphological analysis showed that the MYH6/7 mutation induced cellular hypertrophy and increased aspect ratio compared to the isogenic control. Immunostaining experiments showed marked sarcomere disorganization with lower sarcomeric order and higher dispersion in the mutant hiPSC-CMs,highlighting the remodeling of the myofibril arrangement. Notably,the MYH6/7 mutant showed reduced cortical F-actin expression and increased central F-actin expression compared to the isogenic control,confirming the cytoskeletal remodeling and sarcomeric organization during HCM pathogenesis. These pathological changes accumulated progressively over time,underscoring the chronic and evolving nature of HCM driven by the MYH6/7 mutations. Together,our findings provide critical insights into the cellular and molecular underpinnings of MYH6/7-mutation-associated disease. These findings offer valuable insights into HCM pathogenesis,aiding in future therapies. View Publication

INTRODUCTION: Alzheimer's disease (AD) pathology is complex and involves mitochondrial dysfunction. There are emerging therapies targeting mitochondrial function in clinical trials for AD. This highlights the need for biomarkers that measure mitochondrial function. METHODS: We determined the utility of a novel blood‐based mitochondrial biomarker,the mitochondrial functional index (MFI),in the context of AD in a pilot study.RESULTS: In vitro and in vivo models of AD had a reduced MFI. MFI was lower in human AD subjects and APOE ????4 carriers. Receiver operating characteristic analysis showed MFI had a higher area under the curve than other plasma biomarkers. The MFI biomarker correlated with the Mini‐Mental State Examination (MMSE) and the Clinical Dementia Rating (CDR) scale. DISCUSSION: This study highlights the potential utility of MFI as a functional blood‐based mitochondrial biomarker to interrogate energy metabolism. Ongoing studies are examining the relationship of MFI with brain energy metabolism outcomes. Highlights: The MFI biomarker is reduced in cell and animal models of AD. The MFI biomarker is reduced in human AD subjects and APOE ε4 carriers. The MFI biomarker can discriminate between subjects with normal cognition and AD with better performance than other plasma biomarkers. The MFI biomarker correlates with cognitive scores. View Publication

Hepatocellular carcinoma (HCC) is an aggressive malignancy that is often refractory to chemotherapy and immune checkpoint inhibitors. This therapeutic resistance is driven in part by the persistence of cancer stem-like cells (CSCs) and the development of an immune-cold tumor microenvironment. However,the upstream regulators that coordinate these malignant features remain poorly defined. In this study,we identified dysadherin as a novel upstream activator of YAP that promotes both CSC plasticity and immune evasion through the FAK/YAP/TEAD2 signaling axis. Using single-cell transcriptomic analysis,in vitro assays,and multiple in vivo models including a humanized immune mouse system,we showed that dysadherin enhances the expression of pluripotency genes,such as OCT4 and upregulates PD-L1. These changes support stem-like tumor behavior and contribute to T-cell exclusion,fostering an immunosuppressive niche. Notably,genetic knockdown or peptide-based pharmacologic inhibition of dysadherin effectively restored antitumor immune activation,suppressed metastasis and improved therapeutic responsiveness. Our findings reveal a mechanistic link between dysadherin-mediated cell adhesion signaling and the transcriptional regulation of both stemness and immune escape. Collectively,these findings establish the dysadherin/YAP axis as a key driver of HCC progression and resistance,and highlight it as a compelling therapeutic target that could overcome treatment failure in advanced liver cancer. View Publication

Propofol is a commonly used anesthetic for sedation during surgery. This drug is reported to exhibit nonanaesthetic immunomodulatory and anti-inflammatory effects. Herein,we investigated the impact of topical propofol delivery with the aim of mitigating psoriatic inflammation. The antipsoriatic potency of propofol was evaluated in a cell-based study in which keratinocytes,macrophages,and neutrophils were used as models. A significant reduction in the proinflammatory effectors interleukin (IL)-6,IL-8,and CXC motif chemokine ligand (CXCL)1 was found in activated keratinocytes (HaCaT) treated with propofol. This reduction could enable baseline control. Immunoblotting suggested that the antioxidant enzymes nuclear factor erythroid 2-related factor (Nrf)2 and heme oxygenase (HO)-1 were involved in the protective effect of propofol on keratinocyte stimulation. The increase in Nrf2 and HO-1 was mediated by kelch-like ECH-associated protein (KEAP)1 downregulation. Propofol presented scavenging activity and decreased 2,2-diphenyl-1-picrylhydrazyl (DPPH) by 47%. The downregulation of cytokines/chemokines in activated macrophages (differentiated THP-1) and mouse neutrophils was also found after propofol treatment. Macrophage migration triggered by the conditioned medium of activated keratinocytes could be blocked with the intervention of propofol. The absorption level of propofol (3 mM) into intact pig skin was 1.2 nmol/mg. Skin deposition was increased to 3.7 nmol/mg after SC lipid removal to mimic psoriasiform skin. In silico molecular docking demonstrated the facile interaction of propofol with ceramides in the stratum corneum (SC). The treatment of imiquimod (IMQ)-sensitized mice with topical propofol suppressed erythema,acanthosis,and macrophage/neutrophil infiltration. Propofol also dramatically decreased cytokine/chemokine levels and epidermal thickness in the lesion. In summary,propofol exhibits anti-inflammatory and antioxidant properties to treat psoriasiform lesions. Topical propofol delivery is useful as an ideal route to accomplish antipsoriatic therapy and avoid systemic effects. View Publication

CD8+ T cells are an important weapon in the therapeutic armamentarium against cancer. While CD8+CD103+ T cells with a tissue-resident memory T (TRM) cell phenotype are associated with favorable prognoses,the tumor microenvironment also contains dysfunctional exhausted T (TEX) cells that exhibit a variety of TRM-like features. Here we deconvolute TRM and TEX cells across human cancers,ascribing markers and gene signatures that distinguish these populations and enable their functional distinction. Although TRM cells have superior functionality and are associated with long-term survival post-tumor resection,they are not associated with responsiveness to immune checkpoint blockade. Tumor-associated TEX and TRM cells are clonally distinct,with the latter comprising tumor-independent bystanders and tumor-specific cells segregated from cognate antigen. Intratumoral TRM cells can be forced toward an exhausted fate when chronic antigen stimulation occurs,indicating that the presence or absence of continuous antigen exposure within the microenvironment is the key distinction between tumor-associated TEX and TRM populations. These results highlight unique functions for TRM and TEX cells in tumor control,underscoring the need for distinct strategies to harness these populations for cancer therapies. Here the authors show that tissue-resident memory and exhausted T cells in tumors are distinct populations that are shaped by relative presence or absence of TCR signals,suggesting that a tailored therapeutic strategy is needed to target each subset. View Publication

Multiple myeloma (MM) is a plasma cell malignancy that disrupts bone homeostasis by suppressing osteogenesis and promoting osteoclast activity. While most therapeutic interventions to date have focused on targeting tumor cells and reducing osteolysis,we investigate whether osteoinductive strategies can restore bone formation and counteract disease progression. Using a human bone marrow-like scaffold model that enables direct in vivo evaluation of tumor–stroma interactions and human bone formation,we demonstrate that MM-derived mesenchymal stromal cells (MSCs) retain osteogenic potential but are functionally suppressed by MM cells. Transcriptomic profiling of MM-primed MSCs revealed the downregulation of small leucine-rich proteoglycans (SLRPs),ASPN,OGN,and OMD,key mediators of bone morphogenetic protein (BMP) signaling,which governs osteoblast differentiation. Among the BMPs analyzed,BMP6 emerged as a potent inducer of osteogenesis and regulator of the expression of these SLRPs. Notably,BMP6 selectively promoted bone formation without enhancing osteoclastogenesis and attenuated inflammatory and tumor-supportive MSC phenotypes. BMP6 also directly inhibited MM cell proliferation and suppressed IL6-induced growth. These findings highlight BMP6 as a distinct multifunctional regulator warranting further investigation as a potential therapeutic approach,while establishing the humanized model as a valuable platform for dissecting tumor–bone interactions in MM. View Publication

Palmitic acid (PA) is the most common dietary saturated fatty acid,and is abundant in palm and cottonseed oil,butter,and cheese,whereas oleic acid (OA) is a monounsaturated omega-9 fatty acid found in olive oil. The differences in the cytotoxic and pro-inflammatory effects of PA and OA across endothelial cells (ECs) isolated from different vascular beds have not been investigated in detail. Here,we incubated primary human aortic valve (HAVEC),saphenous vein (HSaVEC),internal thoracic artery (HITAEC),and microvascular (HMVEC) ECs with albumin-bound PA or OA for 24 h and found that PA induced a considerable cytotoxic response,accompanied by an elevated expression of the genes encoding cell adhesion molecules (VCAM1,ICAM1,SELE,and SELP) and pro-inflammatory cytokines (MIF,PTX3,CSF2,CSF3,IL1A,IL6,CCL2,CCL5,CCL20,CSF2,CSF3,CXCL1,CXCL2,CXCL3,CXCL5,CXCL6,CXCL8,and CXCL10),followed by an increased release of interleukin-6 and interleukin-8. HAVEC and HSaVEC were more susceptible to PA,whereas OA had mild-to-moderate cytotoxic effects on HAVEC and HMVEC but did not induce generalized EC activation. Compared with other EC types,HITAEC was the most resistant to PA and OA treatment. Collectively,these results indicate considerable heterogeneity across the ECs of distinct origin in response to PA. View Publication

The development of new alternative models is essential to overcome the limitations of traditional two-dimensional (2D) cell cultures and animal models. Three-dimensional (3D) models,such as organoids,better mimic the structural and functional complexity of mammalian organs,thereby reducing the ethical and economic issues related to animal experimentation. These systems provide more physiologically relevant environments,improving the accuracy of disease modeling and drug response prediction. In this context,we have developed mouse hepatic organoids from livers of adult BALB/c mice and characterized them by microscopy and transcriptional analysis. This model was applied to a robust and reproducible high-throughput screening (HTS) platform for testing cytotoxicity at the preclinical stage of drug discovery. In addition,mouse hepatic organoids were co-cultured with amastigotes of Leishmania donovani parasites to establish a model of host–parasite interaction,which was characterized by RNA-seq linked to differential expression analysis and cytokine production by the hepatic organoids. The findings provided in this work establish mouse hepatic organoids as an alternative model for drug discovery and pathogenesis studies. View Publication

Background: DDB1 and CUL4‐associated factor 7 (DCAF7) is a WD‐repeat adaptor that recruits substrates to the CUL4DDB1 ubiquitinligase complex,but its pan‐cancer relevance and mechanistic contribution to tumor progression remain unclear. Methods: Multi‐omics datasets (genomic,transcriptomic,epigenomic,proteomic and single‐cell) from 33 tumor types were integrated to define DCAF7 expression,regulation,and clinical significance. Somatic alterations and copy‐number variation were analysed across cohorts,and promoter methylation and RNA modification signatures were interrogated. Immune associations were assessed by computational deconvolution and checkpoint‐gene profiling. Pathway and network analyses were performed to infer DCAF7‐linked programmes. Mechanistic and functional validation was conducted in hepatocellular carcinoma (LIHC) cell lines (HepG2,Huh7) using DCAF7 perturbation and pharmacologic Wnt inhibition. Results: DCAF7 was overexpressed in most cancers,consistent with copy‐number gain,focal promoter hypomethylation and putative m6A‐linked post‐transcriptional regulation,whereas hypermethylation at two CpG loci predicted poor prognosis in LIHC. DCAF7 alterations,predominantly amplifications,were associated with shorter overall survival in LIHC and positively correlated with DCAF7 mRNA abundance across cohorts. Immunogenomic analyses linked high DCAF7 to CD4+ T‐cell enrichment,broad upregulation of checkpoint genes (PD‐1/PD‐L1,CTLA‐4,TIGIT),and increased tumour mutational burden,microsatellite instability and neoantigen load,suggesting an immune‐evasive phenotype. Network and enrichment analyses converged on canonical Wnt/β‐catenin,Hippo and cell‐cycle programs. In vitro,DCAF7 promoted LIHC cell proliferation and migration by stabilising β‐catenin via increased inhibitory Ser9 phosphorylation of GSK‐3β,thereby inducing c‐Myc and cyclin D1; DCAF7 knockdown or the Wnt inhibitor XAV939 attenuated these effects. Drug‐response modelling further predicted increased sensitivity of DCAF7‐high tumours to 17‐AAG,docetaxel and alsterpaullone. Conclusions: DCAF7 is frequently activated by genetic and epigenetic mechanisms across cancers,associates with an immunotherapy‐relevant tumour immune milieu,and drives Wnt/β‐catenindependent malignant phenotypes in LIHC. These findings support DCAF7 as a prognostic biomarker and a candidate therapeutic target,particularly for stratified intervention in LIHC. Key points: DCAF7 is up‐regulated in various tumours and correlates with poor prognosis,particularly in LIHC. High DCAF7 expression is linked to CD4+ T cell infiltration,up‐regulation of immune checkpoint genes and increased tumour mutational burden,suggesting a role in tumour immune escape. DCAF7 stabilises β‐catenin by enhancing GSK‐3β Ser9 phosphorylation,thereby driving c‐Myc/cyclin D1 expression and contributing to proliferation and migration in LIHC. DCAF7‐high tumours demonstrate therapeutic vulnerability to 17‐AAG,docetaxel and CDK/GSK‐3 inhibitor,revealing potential targeted treatment strategies. View Publication