技术资料

BackgroundThe epoxyeicosatrienoic acids (EETs) are derivatives of the arachidonic acid metabolism with anti-inflammatory activities. However,their efficacy is limited due to the rapid hydrolysis by soluble epoxide hydrolase (sEH). Inhibition of sEH has been shown to stabilize the EETs and reduce neuroinflammation in A? mouse models of Alzheimer’s disease (AD). However,the role of the sEH-EET signaling pathway in other CNS cell types and neurodegenerative conditions are less understood.MethodsHere we investigated the mechanisms and functional role of the sEH-EET axis in tauopathy by treating PS19 mice with a small molecule sEH inhibitor TPPU and by crossing the PS19 mice with Ephx2 (gene encoding sEH) knockout mice. This was followed by single-nucleus RNA-sequencing (snRNA-seq),biochemical and immunohistochemical analysis,and behavioral assessments. Additionally,we examined the effects of the sEH-EET pathway in primary microglia cultures and human induced pluripotent stem cell (iPSC)-derived neurons exhibiting seeding-induced Tau inclusions.ResultssEH inhibition improved cognitive function,rescued neuronal cell loss,and reduced Tau pathology and microglial reactivity. snRNA-seq revealed that TPPU treatment upregulated genes involved in actin cytoskeleton and excitatory synaptic pathways. Treatment of human iPSC-derived neurons with TPPU enhanced synaptic density without affecting Tau accumulation,suggesting a cell-autonomous neuroprotective effect of sEH blockade. Furthermore,sEH inhibition reversed disease-associated and interferon-responsive microglial states in PS19 mice,while EET supplementation promoted Tau phagocytosis and clearance in primary microglia cultures.ConclusionThese findings demonstrate that sEH blockade or EET augmentation confers therapeutic benefit in neurodegenerative tauopathies by simultaneously targeting neuronal and microglial pathways.Supplementary InformationThe online version contains supplementary material available at 10.1186/s13024-025-00844-x. View Publication

Human-induced pluripotent stem cell (iPSC)-derived mesenchymal stem cells (iMSCs) represent a promising and renewable cell source for therapeutic applications. A systematic evaluation of the immunological properties and engraftment potential of iMSCs generated from urine-derived iPSCs is lacking,which has impeded their broader application. In this study,we differentiated urine-derived iPSCs into iMSCs and assessed their fundamental MSC characteristics,immunogenicity,immunomodulatory capacity and in vivo engraftment. Compared to umbilical cord-derived MSCs (UCMSCs),iMSCs demonstrated an enhanced proliferative capacity,a higher level of regenerative gene expression,and lower immunogenicity,strengthening resistance to apoptosis induced by allogeneic peripheral blood mononuclear cells (PBMCs) and the NK-92 cell line. In addition,iMSCs exhibited a diminished ability to inhibit T cell proliferation and activation compared with UCMSCs. Transcriptomic analyses further revealed the decreased expression of immune regulatory factors in iMSCs. After transfusion into mouse models,iMSCs engrafted in the lungs,liver,and spleen and exhibited the ability to migrate to tumor tissues. Our results indicated that iMSCs generated from urine-derived iPSCs have a significant replicative capacity,low immunogenicity and unique immunomodulatory properties,and hence offer obvious advantages in immune privilege and allogenic therapeutic application prospects. View Publication

Amyotrophic lateral sclerosis (ALS) involves motor neuron death due to mislocalized TDP-43. Pathologic TDP-43 associates with stress granules (SGs),and lowering the SG-associated protein ataxin-2 (ATXN2) using Atxn2-targeting antisense oligonucleotides prolongs survival in TAR4/4 sporadic ALS mice but failed in clinical trials likely due to poor target engagement. Here we show that an AAV with potent motor neuron transduction delivering Atxn2-targeting miRNAs reduces Atxn2 throughout the central nervous system at doses 40x lower than published work. In TAR4/4 mice,miAtxn2 increased survival (50%) and strength,and reduced motor neuron death,inflammation,and phosphorylated TDP-43. TAR4/4 transcriptomic dysregulation recapitulated ALS gene signatures that were rescued by miAtxn2,identifying potential therapeutic mechanisms and biomarkers. In slow progressing hemizygous mice,miAtxn2 slowed disease progression,and in ALS patient-derived lower motor neurons,our AAV vector transduced >95% of cells and potently reduced ATXN2 at MOI 4 logs lower than previously reported. These data support AAV-RNAi targeting ATXN2 as a translatable therapy for sporadic ALS. Amado et al. develop a gene therapy for sporadic ALS using motor neuron-targeting AAVs to deliver RNAi targeting ataxin-2. In a mouse model,survival,strength,and disease-related pathology are improved; and human motor neurons are strongly transduced. View Publication

Becker muscular dystrophy (BMD) is caused by in-frame mutations in dystrophin gene,leading to progressive muscle weakness,and cardiac and respiratory complications. Currently,there is no cure. We have recently identified the importance of poly-ubiquitination in regulating dystrophin stability through the binding of lncRNA H19 to the dystrophin C-terminal zinc-finger domain (ZNF),inhibiting TRIM63-mediated poly-ubiquitination. We also demonstrated that BMD mutations lead to conformational changes in ZNF domain,reduced lncRNA H19 binding and increased dystrophin ubiquitination. Here we used BMD iPSCs to investigate the in vitro myogenic potential of BMD myogenic cells,as well as in vitro and in vivo studies to evaluate the therapeutic efficacy of three candidate molecules targeting dystrophin ubiquitination pathway. In vitro assays indicated significant deficiencies in myogenic cell differentiation of BMD iPSCs,including reduced proliferation,cell-cycle arrest,increased apoptosis,senescence,and membrane damage,and impaired myotube formation. In vivo engraftment demonstrated significant improvement in BMD iPSC myogenic cell survival and dystrophin expression in the animals treated with two molecules: a TRIM63 inhibitor and an ?-synuclein aggregation inhibitor. These findings provide promising evidence for the potential therapeutic efficacy of these ubiquitination pathway inhibitors to improve muscle progenitor cell survival and dystrophin expression in BMD patients. Graphical abstract Regulation of dystrophin stability via poly-ubiquitination is crucial in Becker muscular dystrophy (BMD). BMD mutations impair lncRNA H19 binding,increasing dystrophin ubiquitination. Darabi and colleagues’ studies,using BMD iPSCs and in vivo models,demonstrate that inhibiting TRIM63 or ?-synuclein aggregation improves myogenic cell survival and dystrophin expression,suggesting promising therapeutic avenues for BMD. View Publication

SummaryBackgroundPresence of nerves in tumours,by axonogenesis and neurogenesis,is gaining increased attention for its impact on cancer initiation and development,and the new field of cancer neuroscience is emerging. A recent study in prostate cancer suggested that the tumour microenvironment may influence cancer progression by recruitment of Doublecortin (DCX)-expressing neural progenitor cells (NPCs). However,the presence of such cells in human breast tumours has not been comprehensively explored.MethodsHere,we investigate the presence of DCX-expressing cells in breast cancer stromal tissue from patients using Imaging Mass Cytometry. Single-cell analysis of 372,468 cells across histopathological images of 107 breast cancers enabled spatial resolution of neural elements in the stromal compartment in correlation with clinicopathological features of these tumours. In parallel,we established a 3D in vitro model mimicking breast cancer neural progenitor-innervation and examined the two cell types as they co-evolved in co-culture by using mass spectrometry-based global proteomics.FindingsStromal presence of DCX + cells is associated with tumours of higher histological grade,a basal-like phenotype,and shorter patient survival in tumour tissue from patients with breast cancer. Global proteomics analysis revealed significant changes in the proteomic landscape of both breast cancer cells and neural progenitors in co-culture.InterpretationThese results support that neural involvement plays an active role in breast cancer and warrants further studies on the relevance of nerve elements for tumour progression.FundingThis work was supported by the 10.13039/501100005416Research Council of Norway through its Centre of Excellence funding scheme,project number 223250 (to L.A.A),the 10.13039/100008730Norwegian Cancer Society (to L.A.A. and H.V.),the Regional Health Trust Western Norway (Helse Vest) (to L.A.A.),the 10.13039/501100008728Meltzer Research Fund (to H.V.) and the 10.13039/100000002National Institutes of Health (NIH)/10.13039/100000057NIGMS grant R01 GM132129 (to J.A.P.). View Publication

Adherent two-dimensional human gastruloids have provided insights into early human embryogenesis. Even though the model system is highly reproducible,no available automated technology can screen and sort large numbers of these near-millimeter-sized complex structures for large-scale assays. Here,we developed a microraft array-based technology to perform image-based assays of large numbers of fixed or living gastruloids and sort individual gastruloids for downstream assays,such as gene expression analysis. Arrays of 529 indexed magnetic microrafts each (789?µm side length) possessing flat surfaces were photopatterned with a central circular region (500?µm diameter) of extracellular matrix with an accuracy of 93?±?1% to form a single gastruloid on each raft. An image analysis pipeline extracted features from transmitted light and fluorescence images of the gastruloids. The large microrafts were released and collected by an automated sorting system with efficiencies of 98?±?4% and 99?±?2%,respectively. The microraft array platform was used to assay individual euploid and aneuploid (possessing abnormal numbers of chromosomes) gastruloids with clear phenotypic differences. Aneuploid gastruloids displayed significantly less DNA/area than euploid gastruloids. However,even gastruloids with the same condition displayed significant heterogeneity. Both noggin (NOG) and keratin 7 (KRT7),two genes involved in spatial patterning within gastruloids,were upregulated in aneuploid relative to that in the euploid gastruloids. Moreover,relative NOG and KRT7 expressions were negatively correlated with DNA/area. The microraft arrays will empower novel screens of single gastruloids for a better understanding of key mechanisms underlying phenotypic differences between gastruloids. View Publication

BackgroundChronic lung disease of prematurity,called bronchopulmonary dysplasia (BPD),lacks effective therapies,stressing the need for preclinical testing systems that reflect human pathology for identifying causal pathways and testing novel compounds. Alveolar organoids derived from human pluripotent stem cells (hPSC) are promising test platforms for studying distal airway diseases like BPD,but current protocols do not accurately replicate the distal niche environment of the native lung. Herein,we investigated the contributions of cellular constituents of the alveolus and fetal respiratory movements on hPSC-derived alveolar organoid formation.MethodsHuman PSCs were differentiated in 2D culture into lung progenitor cells (LPC) which were then further differentiated into alveolar organoids before and after removal of co-developing mesodermal cells. LPCs were also differentiated in Transwell® co-cultures with and without human fetal lung fibroblast. Forming organoids were subjected to phasic mechanical strain using a Flexcell® system. Differentiation within organoids and Transwell® cultures was assessed by flow cytometry,immunofluorescence,and qPCR for lung epithelial and alveolar markers of differentiation including GATA binding protein 6 (GATA 6),E-cadherin (CDH1),NK2 Homeobox 1 (NKX2-1),HT2-280,surfactant proteins B (SFTPB) and C (SFTPC).ResultsWe observed that co-developing mesenchymal progenitors promote alveolar epithelial type 2 cell (AEC2) differentiation within hPSC-derived lung organoids. This mesenchymal effect on AEC2 differentiation was corroborated by co-culturing hPSC-NKX2-1+ lung progenitors with human embryonic lung fibroblasts. The stimulatory effect did not require direct contact between fibroblasts and NKX2-1+ lung progenitors. Additionally,we demonstrate that episodic mechanical deformation of hPSC-derived lung organoids,mimicking in situ fetal respiratory movements,increased AEC2 differentiation without affecting proximal epithelial differentiation.ConclusionOur data suggest that biophysical and mesenchymal components promote AEC2 differentiation within hPSC-derived distal organoids in vitro.Supplementary InformationThe online version contains supplementary material available at 10.1186/s13287-024-03890-2. View Publication

Coronary microvascular disease (CMD) and its progression towards major adverse coronary events pose a significant health challenge. Accurate in vitro investigation of CMD requires a robust cell model that faithfully represents the cells within the cardiac microvasculature. Human pluripotent stem cell-derived endothelial cells (hPSC-ECs) offer great potential; however,they are traditionally derived via differentiation protocols that are not readily scalable and are not specified towards the microvasculature. Here,we report the development and comprehensive characterisation of a scalable 3D protocol enabling the generation of phenotypically stable cardiac hPSC-microvascular-like ECs (hPSC-CMVECs) and cardiac pericyte-like cells. These were derived by growing vascular organoids within 3D stirred tank bioreactors and subjecting the emerging 3D hPSC-ECs to high-concentration VEGF-A treatment (3DV). Not only did this promote phenotypic stability of the 3DV hPSC-ECs; single cell-RNA sequencing (scRNA-seq) revealed the pronounced expression of cardiac endothelial- and microvascular-associated genes. Further,the generated mural cells attained from the vascular organoid exhibited markers characteristic of cardiac pericytes. Thus,we present a suitable cell model for investigating the cardiac microvasculature as well as the endothelial-dependent and -independent mechanisms of CMD. Moreover,owing to their phenotypic stability,cardiac specificity,and high angiogenic potential,the cells described within would also be well suited for cardiac tissue engineering applications.Supplementary InformationThe online version contains supplementary material available at 10.1007/s10456-024-09929-5. View Publication

Klotho,a well-known aging suppressor protein,has been implicated in neuroprotection and the regulation of neuronal senescence. While previous studies have demonstrated its anti-aging properties in human brain organoids,its potential to mitigate neurodegenerative processes triggered by ?-amyloid remains underexplored. In this study,we utilised human induced pluripotent stem cells (iPSCs) engineered with a doxycycline-inducible system to overexpress KLOTHO and generated 2D cortical neuron cultures from these cells. These neurons were next exposed to pre-aggregated ?-amyloid 1–42 oligomers to model the neurotoxicity associated with Alzheimer’s disease. Our data reveal that upregulation of KLOTHO significantly reduced ?-amyloid-induced neuronal degeneration and apoptosis,as evidenced by decreased cleaved caspase-3 expression and preservation of axonal integrity. Additionally,KLOTHO overexpression prevented the loss of dendritic branching and mitigated reductions in axonal diameter,hallmark features of neurodegenerative pathology. These results highlight Klotho’s protective role against ?-amyloid-induced neurotoxicity in human cortical neurons and suggest that its age-related decline may contribute to neurodegenerative diseases such as Alzheimer’s disease. Our findings underscore the therapeutic potential of Klotho-based interventions in mitigating age-associated neurodegenerative processes.Supplementary InformationThe online version contains supplementary material available at 10.1186/s13041-025-01199-6. View Publication

Inclusion body myositis (IBM) is an inflammatory myopathy that displays proximal and distal muscle weakness. At the histopathological level,the muscles of IBM patients show inflammatory infiltrates,rimmed vacuoles and mitochondrial changes. The etiology of IBM remains unknown,and there is a lack of validated disease models,biomarkers and effective treatments. To contribute to unveil disease underpins we developed a cell model based on myotubes derived from induced pluripotent stem cells (iPSC-myotubes) from IBM patients and compared the molecular phenotype vs. age and sex-paired controls (n?=?3 IBM and 4 CTL). We evaluated protein histological findings and the gene expression profile by mRNA-seq,alongside functional analysis of inflammation,degeneration and mitochondrial function. Briefly,IBM iPSC-myotubes replicated relevant muscle histopathology features of IBM,including aberrant expression of HLA,TDP-43 and COX markers. mRNA seq analysis identified 1007 differentially expressed genes (DEGs) (p-value adj? View Publication

SUMMARY Resident cardiac macrophages are critical mediators of cardiac function. Despite their known importance to cardiac electrophysiology and tissue maintenance,there are currently no stem-cell-derived models of human engineered cardiac tissues (hECTs) that include resident macrophages. In this study,we made an induced pluripotent stem cell (iPSC)-derived hECT model with a resident population of macrophages (iM0) to better recapitulate the native myocardium and characterized their impact on tissue function. Macrophage retention within the hECTs was confirmed via immunofluorescence after 28 days of cultivation. The inclusion of iM0s significantly impacted hECT function,increasing contractile force production. A potential mechanism underlying these changes was revealed by the interrogation of calcium signaling,which demonstrated the modulation of ?-adrenergic signaling in +iM0 hECTs. Collectively,these findings demonstrate that macrophages significantly enhance cardiac function in iPSC-derived hECT models,emphasizing the need to further explore their contributions not only in healthy hECT models but also in the contexts of disease and injury. In brief Lock and Graney et al. develop a human engineered cardiac tissue with an incorporated iPSC-derived macrophage population to better mimic the complex cell landscape of the native myocardium. Macrophage inclusion leads to increased contractile function of the tissue,which is attributed to macrophage stimulation of the cardiomyocyte ?-adrenergic signaling pathway. Graphical Abstract View Publication

Huntington disease (HD) is a neurodegenerative disease caused by the abnormal expansion of a polyglutamine tract resulting from a mutation in the HTT gene. Oxidative stress has been identified as a significant contributing factor to the development of HD and other neurodegenerative diseases,and targeting anti-oxidative stress has emerged as a potential therapeutic approach. CHCHD2 is a mitochondria-related protein involved in regulating cell migration,anti-oxidative stress,and anti-apoptosis. Although CHCHD2 is highly expressed in HD cells,its specific role in the pathogenesis of HD remains uncertain. We postulate that the up-regulation of CHCHD2 in HD models represents a compensatory protective response against mitochondrial dysfunction and oxidative stress associated with HD. To investigate this hypothesis,we employed HD mouse striatal cells and human induced pluripotent stem cells (hiPSCs) as models to examine the effects of CHCHD2 overexpression (CHCHD2-OE) or knockdown (CHCHD2-KD) on the HD phenotype. Our findings demonstrate that CHCHD2 is crucial for maintaining cell survival in both HD mouse striatal cells and hiPSCs-derived neurons. Our study demonstrates that CHCHD2 up-regulation in HD serves as a compensatory protective response against oxidative stress,suggesting a potential anti-oxidative strategy for the treatment of HD. View Publication