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ABSTRACTProneural genes are conserved drivers of neurogenesis across the animal kingdom. How their functions have adapted to guide human-specific neurodevelopmental features is poorly understood. Here,we mined transcriptomic data from human fetal cortices and generated from human embryonic stem cell-derived cortical organoids (COs) to show that NEUROG1 and NEUROG2 are most highly expressed in basal neural progenitor cells,with pseudotime trajectory analyses indicating that NEUROG1-derived lineages predominate early and NEUROG2 lineages later. Using ChIP-qPCR,gene silencing and overexpression studies in COs,we show that NEUROG2 is necessary and sufficient to directly transactivate known target genes (NEUROD1,EOMES,RND2). To identify new targets,we engineered NEUROG2-mCherry knock-in human embryonic stem cells for CO generation. The mCherry-high CO cell transcriptome is enriched in extracellular matrix-associated genes,and two genes associated with human-accelerated regions: PPP1R17 and FZD8. We show that NEUROG2 binds COL1A1,COL3A1 and PPP1R17 regulatory elements,and induces their ectopic expression in COs,although NEUROG2 is not required for this expression. Neurog2 similarly induces Col3a1 and Ppp1r17 in murine P19 cells. These data are consistent with a conservation of NEUROG2 function across mammalian species. Summary: Analysis of human cortical organoids reveals that NEUROG1 lineages prevail early and NEUROG2 lineages later,and that NEUROG2 targets include COL genes and PPP1R17,a human-accelerated region-associated gene. View Publication

Lateral Meningocele Syndrome (LMS),a disorder associated with NOTCH3 pathogenic variants,presents with neurological,craniofacial and skeletal abnormalities. Mouse models of the disease exhibit osteopenia that is ameliorated by the administration of Notch3 antisense oligonucleotides (ASO) targeting either Notch3 or the Notch3 mutation. To determine the consequences of LMS pathogenic variants in human cells and whether they can be targeted by ASOs,induced pluripotent NCRM1 and NCRM5 stem (iPS) cells harboring a NOTCH36692-93insC insertion were created. Parental iPSCs,NOTCH36692-93insC and isogenic controls,free of chromosomal aberrations as determined by human CytoSNP850 array,were cultured under conditions of neural crest,mesenchymal and osteogenic cell differentiation. The expected cell phenotype was confirmed by surface markers and a decline in OCT3/4 and NANOG mRNA. NOTCH36692-93insC cells displayed enhanced expression of Notch target genes HES1,HEY1,2 and L demonstrating a NOTCH3 gain-of-function. There was enhanced osteogenesis in NOTCH36692-93insC cells as evidenced by increased mineralized nodule formation and ALPL,BGLAP and BSP expression. ASOs targeting NOTCH3 decreased both NOTCH3 wild type and NOTCH36692-93insC mutant mRNA by 40% in mesenchymal and 90% in osteogenic cells. ASOs targeting the NOTCH3 insertion decreased NOTCH36692-93insC by 70–80% in mesenchymal cells and by 45–55% in osteogenic cells and NOTCH3 mRNA by 15–30% and 20–40%,respectively. In conclusion,a NOTCH3 pathogenic variant causes a modest increase in osteoblastogenesis in human iPS cells in vitro and NOTCH3 and NOTCH3 mutant specific ASOs downregulate NOTCH3 transcripts associated with LMS. View Publication

SummaryRibosomopathies arise from the disruptions in ribosome biogenesis within the nucleolus,which is organized via liquid-liquid phase separation (LLPS). The roles of LLPS in ribosomopathies remain poorly understood. Here,we generated human induced pluripotent stem cell (hiPSC) models of ribosomopathy caused by mutations in small nucleolar RNA (snoRNA) gene SNORD118. Mutant hiPSC-derived neural progenitor cells (NPCs) or neural crest cells (NCCs) exhibited ribosomopathy hallmark cellular defects resulting in reduced organoid growth,recapitulating developmental delay in patients. SNORD118 mutations in NPCs disrupted nucleolar morphology and LLPS properties coupled with impaired ribosome biogenesis and a translational downregulation of fibrillarin (FBL),the key LLPS effector acting via the intrinsically disordered region (IDR) motif. IDR-depleted FBL failed to rescue NPC defects,whereas a chimeric FBL with swapped IDR motif from an unrelated protein mitigated ribosomopathy and organoid growth defects. Thus,SNORD118 human iPSC models revealed aberrant phase separation and nucleolar functions as potential pathogenic mechanisms in ribosomopathies. Graphical abstract Highlights•SNORD118 mutant hiPSC-derived cells and organoids recapitulate the ribosomopathy defects•Mutations impair ribosome biogenesis and translation of phase separation effector FBL•Phase separation and nucleolar organization are defective in SNORD118 mutant cells•Impaired phase separation causes ribosomopathy and growth defects in hiPSC models Natural sciences; Biological sciences; Cell biology; Stem cell research View Publication

Regulation of gene expression through enhancers is one of the major processes shaping the structure and function of the human brain during development. High-throughput assays have predicted thousands of enhancers involved in neurodevelopment,and confirming their activity through orthogonal functional assays is crucial. Here,we utilized Massively Parallel Reporter Assays (MPRAs) in stem cells and forebrain organoids to evaluate the activity of ~ 7000 gene-linked enhancers previously identified in human fetal tissues and brain organoids. We used a Gaussian mixture model to evaluate the contribution of background noise in the measured activity signal to confirm the activity of ~ 35% of the tested enhancers,with most showing temporal-specific activity,suggesting their evolving role in neurodevelopment. The temporal specificity was further supported by the correlation of activity with gene expression. Our findings provide a valuable gene regulatory resource to the scientific community. 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

BackgroundThe simultaneous differentiation of human pluripotent stem cells (hPSCs) into both endodermal and mesodermal lineages is crucial for developing complex,vascularized tissues,yet poses significant challenges. This study explores a method for co-differentiation of mesoderm and endoderm,and their subsequent differentiation into pancreatic progenitors (PP) with endothelial cells (EC).MethodsTwo hPSC lines were utilized. By manipulating WNT signaling,we optimized co-differentiation protocols of mesoderm and endoderm through adjusting the concentrations of CHIR99021 and mTeSR1. Subsequently,mesoderm and endoderm were differentiated into vascularized pancreatic progenitors (vPP) by adding VEGFA. The differentiation characteristics and potential of vPPs were analyzed via transcriptome sequencing and functional assays.ResultsA low-dose CHIR99021 in combination with mTeSR1 yielded approximately 30% mesodermal and 70% endodermal cells. Introduction of VEGFA significantly enhanced EC differentiation without compromising PP formation,increasing the EC proportion to 13.9%. Transcriptomic analyses confirmed the effectiveness of our protocol,showing up-regulation of mesodermal and endothelial markers,alongside enhanced metabolic pathways. Functional assays demonstrated that vPPs could efficiently differentiate into insulin-producing ?-cells,as evidenced by increased expression of ?-cell markers and insulin secretion.ConclusionOur findings provide a robust method for generating vPPs,which holds significant promise for regenerative medicine applications,particularly in diabetes treatment.Supplementary InformationThe online version contains supplementary material available at 10.1186/s13287-024-04120-5. View Publication

AbstractBackgroundRodent models have been widely used to investigate skin development,but do not account for significant differences in composition compared to human skin. On the other hand,two-dimensional and three-dimensional engineered skin models still lack the complex features of human skin such as appendages and pigmentation. Recently,hair follicle containing skin organoids (SKOs) with a stratified epidermis,and dermis layer have been generated as floating spheres from human-induced pluripotent stem cells (hiPSCs).MethodsThe current study aims to investigate the generation of hiPSCs-derived SKOs using an air-liquid interface (ALI) model on transwell membranes (T-SKOs) and compares their development with conventional floating culture in low-attachment plates (F-SKOs).ResultsMature SKOs containing an epidermis,dermis,and appendages are created in both T-SKO and F-SKO conditions. It was found that the hair follicles are smaller and shorter in the F-SKO compared with T-SKOs. Additionally,the ALI conditions contribute to enhanced hair follicle numbers than conventional floating culture.ConclusionsTogether,this study demonstrates the significant influence of transwell culture on the morphogenesis of hair follicles within SKOs and highlights the potential for refinement of skin model engineering for advancing dermatology and skin research. View Publication

The faithful segregation of intact genetic material and the perpetuation of chromatin states through mitotic cell divisions are pivotal for maintaining cell function and identity across cell generations. However,most exogenous mutagens generate long-lasting DNA lesions that are segregated during mitosis. How this segregation is controlled is unknown. Here,we uncover a mitotic chromatin-marking pathway that governs the segregation of UV-induced damage in human cells. Our mechanistic analyses reveal two layers of control: histone ADP-ribosylation,and the incorporation of newly synthesized histones at UV damage sites,that both prevent local mitotic phosphorylations on histone H3 serine residues. Functionally,this chromatin-marking pathway controls the segregation of UV damage in the cell progeny with consequences on daughter cell fate. We propose that this mechanism may help preserve the integrity of stem cell compartments during asymmetric cell divisions. The transmission of unrepaired DNA lesions through mitosis needs tight control. Here,the authors uncover a damaged chromatin marking mechanism driving the segregation of UV damage through mitosis with potential consequences on daughter cell fate. View Publication

A growing body of clinical literature has described neurodevelopmental delays in infants with chronic prenatal opioid exposure and withdrawal. Despite this,the mechanism of how opioids impact the developing brain remains unknown. Here,we developed an in vitro model of prenatal morphine exposure and withdrawal using healthy human induced pluripotent stem cell (iPSC)-derived midbrain neural progenitors in monolayer. To optimize our model,we identified that a longer neural induction and regional patterning period increases expression of canonical opioid receptors mu and kappa in midbrain neural progenitors compared to a shorter protocol (OPRM1,two-tailed t-test,p =? 0.004; OPRK1,p =? 0.0003). Next,we showed that the midbrain neural progenitors derived from a longer iPSC neural induction also have scant toll-like receptor 4 (TLR4) expression,a key player in neonatal opioid withdrawal syndrome pathophysiology. During morphine withdrawal,differentiating neural progenitors experience cyclic adenosine monophosphate overshoot compared to cell exposed to vehicle (p =? 0.0496) and morphine exposure conditions (p,=? 0.0136,1-way ANOVA). Finally,we showed that morphine exposure and withdrawal alters proportions of differentiated progenitor cell fates (2-way ANOVA,F =? 16.05,p View Publication

Poisoning with the organophosphorus nerve agent VX can be life-threatening due to limitations of the standard therapy with atropine and oximes. To date,the underlying pathomechanism of VX affecting the neuromuscular junction has not been fully elucidated structurally. Results of recent studies investigating the effects of VX were obtained from cells of animal origin or immortalized cell lines limiting their translation to humans. To overcome this limitation,motor neurons (MN) of this study were differentiated from in-house feeder- and integration-free-derived human-induced pluripotent stem cells (hiPSC) by application of standardized and antibiotic-free differentiation media with the aim to mimic human embryogenesis as closely as possible. For testing VX sensitivity,MN were initially exposed once to 400 µM,600 µM,800 µM,or 1000 µM VX and cultured for 5 days followed by analysis of changes in viability and neurite outgrowth as well as at the gene and protein level using µLC-ESI MS/HR MS,XTT,IncuCyte,qRT-PCR,and Western Blot. For the first time,VX was shown to trigger neuronal cell death and decline in neurite outgrowth in hiPSC-derived MN in a time- and concentration-dependent manner involving the activation of the intrinsic as well as the extrinsic pathway of apoptosis. Consistent with this,MN morphology and neurite network were altered time and concentration-dependently. Thus,MN represent a valuable tool for further investigation of the pathomechanism after VX exposure. These findings might set the course for the development of a promising human neuromuscular test model and patient-specific therapies in the future. View Publication

Arrhythmogenic right ventricular cardiomyopathy (ARVC) is an inherited cardiac disorder characterized by sodium channel dysfunction. However,the clinical management of ARVC remains challenging. Identifying novel compounds for the treatment of ARVC is crucial for advancing drug development.PurposeIn this study,we aim to identify novel compounds for treating ARVC.MethodsMachine learning (ML) models were constructed using proteins analyzed from the scRNA-seq data of ARVC rats and their corresponding protein-protein interaction (PPI) network to predict binding affinity (BA). To validate these predictions,a series of experiments in cardiac organoids were conducted,including Western blotting,ELISA,MEA,and Masson staining to assess the effects of these compounds.ResultsWe first discovered and identified SCN5A as the most significantly affected sodium channel protein in ARVC. ML models predicted that Kaempferol binds to SCN5A with high affinity. In vitro experiments further confirmed that Kaempferol exerted therapeutic effects in ARVC.ConclusionThis study presents a novel approach for identifying potential compounds to treat ARVC. By integrating ML modeling with organoid validation,our platform provides valuable support in addressing the public health challenges posed by ARVC,with broad application prospects. Kaempferol shows promise as a lead compound for ARVC treatment. View Publication

Human induced pluripotent stem cell-derived sensory neuron (iPSC-dSN) models are a valuable resource for the study of neurotoxicity but are affected by poor replicability and reproducibility,often due to a lack of optimization. Here,we identify experimental factors related to culture conditions that substantially impact cellular drug response in vitro and determine optimal conditions for improved replicability and reproducibility. Treatment duration and cell seeding density were both found to be significant factors,while cell line differences also contributed to variation. A replicable dose–response in viability was demonstrated after 48-h exposure to docetaxel or paclitaxel. Additionally,a replicable dose-dependent reduction in neurite outgrowth was demonstrated,demonstrating the applicability of the model for the examination of additional phenotypes. Overall,we have established an optimized iPSC-dSN model for the study of taxane-induced neurotoxicity. View Publication