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Simple SummaryAtypical teratoid rhabdoid tumors (ATRTs) and diffuse intrinsic pontine gliomas (DIPGs) are lethal pediatric brain tumors that can resist chemotherapy and be influenced by their microenvironment. Astrocytes are the key components of the brain tumor microenvironment and can support tumor growth. We investigated the effects of astrocytes on cisplatin sensitivity in pediatric brain cancer cells. The crosstalk between astrocytes and cancer cells activated astrocytes and promoted cancer cell proliferation. Moreover,the tumor cells expressed elevated levels of drug resistance genes in the presence of astrocytes. In conclusion,astrocytes can significantly improve the growth of these tumor cells and modulate their chemosensitivity,highlighting their role in therapeutic resistance. AbstractBackground: ATRTs and DIPGs are deadly pediatric brain tumors with poor prognosis. These tumors can develop resistance to chemotherapies,which may be significantly influenced by their microenvironment. Since astrocytes are the most abundant glial cell type in the brain microenvironment and may support tumor growth and chemoresistance,this study investigated the effects of induced pluripotent stem cell-derived astrocytes (iPSC-astrocytes) on cisplatin sensitivity in CHLA-05-ATRT and SF8628 (DIPG) cells. iPSCs provide an unlimited and standardized source of nascent astrocytes,which enables modeling the interaction between childhood brain tumor cells and iPSC-astrocytes within a controlled coculture system. Methods: To study the effects on tumor growth,the iPSC-astrocytes were cocultured with tumor cells. Additionally,the tumor cells were exposed to various concentrations of cisplatin to evaluate their chemosensitivity in the presence of astrocytes. Results: The paracrine interaction of iPSC-astrocytes with tumor cells upregulated astrocyte activation markers GFAP and STAT3 and promoted tumor cell proliferation. Moreover,the cisplatin treatment significantly decreased the viability of CHLA-05-ATRT and SF8628 cells. However,tumor cells exhibited reduced sensitivity to cisplatin in the coculture with iPSC-astrocytes. During cisplatin treatment,DIPG cells in particular showed upregulation of resistance markers,ERK1,STAT3,and MTDH,which are associated with enhanced proliferation and invasion. They also had increased expression of APEX1,which is involved in the base excision repair pathway following cisplatin-induced DNA damage. Conclusion: These findings underscore the significance of the tumor microenvironment in modulating tumor cell survival and chemosensitivity. View Publication

Differentiation approaches to obtain mesenchymal stem cells (MSCs) have gradually developed over the last few decades. The problem is that different protocols give different MSC types,making further research difficult. Here,we tried three different approaches to differentiate embryonic stem cells (ESCs) from early mesoderm to MSCs using serum-containing or xeno-free differentiation medium and observed differences in the cells’ morphology,doubling rate,ability to form colonies,surface marker analysis,and multilineage differentiation potential of the obtained cell lines. We concluded that the xeno-free medium best fits the criteria of MSCs’ morphology,growth kinetics,and surface marker characterization. In contrast,the serum-containing medium gives better potential for further MSC differentiation into osteogenic,chondrogenic,and adipogenic lineages. View Publication

A large number of synaptic proteins have been recurrently associated with complex brain disorders. One of these proteins,the Traf and Nck interacting kinase (TNIK),is a postsynaptic density (PSD) signaling hub,with many variants reported in neurodevelopmental disorder (NDD) and psychiatric disease. While rodent models of TNIK dysfunction have abnormal spontaneous synaptic activity and cognitive impairment,the role of mutations found in patients with TNIK protein deficiency and TNIK protein kinase activity during early stages of neuronal and synapse development has not been characterized. Here,using hiPSC-derived excitatory neurons,we show that TNIK mutations dysregulate neuronal activity in human immature synapses. Moreover,the lack of TNIK protein kinase activity impairs MAPK signaling and protein phosphorylation in structural components of the PSD. We show that the TNIK interactome is enriched in NDD risk factors and TNIK lack of function disrupts signaling networks and protein interactors associated with NDD that only partially overlap to mature mouse synapses,suggesting a differential role of TNIK in immature synapsis in NDD. View Publication

Biallelic mutations in PIGK cause GPI biosynthesis defect 22 (GPIBD22),characterized with developmental delay,hypotonia,and cerebellar atrophy. The understanding of the underlying causes is limited due to the lack of suitable disease models. To address this gap,we generated a mouse model with PIGK deficits,specifically in Purkinje cells (Pcp2-cko) and an induced pluripotent stem cell (iPSC) model using the c.87dupT mutant (KI) found in GPIBD22 patients. Pcp2-cko mice demonstrated cerebellar atrophy,ataxia and progressive Purkinje cells loss which were accompanied by increased apoptosis and neuroinflammation. Similarly,KI iPSCs exhibited increased apoptosis and accelerated neural rosette formation,indicating that PIGK defects could impact early neural differentiation that confirmed by the RNA-Seq results of neural progenitor cells (NPCs). The increased apoptosis and accelerated NPC differentiation in KI iPSCs are associated with excessive unfolded protein response (UPR) pathway activation,and can be rescued by UPR pathway inhibitor. Our study reveals potential pathogenic mechanism of GPIBD22 and providing new insights into the therapeutic strategy for GPIBD. View Publication

ABSTRACTHuman induced pluripotent stem cells (iPSCs) are an invaluable endless cell source for generating various therapeutic cells and tissues. However,their differentiation into specific cell lineages,such as definitive endoderm (DE) and pancreatic progenitor (PP),often suffers from poor reproducibility,due partially to their pluripotency. In this work,we investigated the impact of iPSC confluency during cell self?renewal and seeding density on cell metabolic activity,glycolysis to oxidative phosphorylation shift,and differentiation potential toward DE and PP lineages. Our findings demonstrated that cell seeding strategy influences cellular metabolic activity and the robustness of iPSC differentiation. iPSCs maintained at higher seeding density exhibited lower initial oxygen consumption rate (OCR) and metabolic activity. There is an optimal seeding density to ensure sufficient oxygen consumption during differentiation and to yield high expression of SOX17 in the DE lineage and high PDX1/NKX6.1 dual?positive cells in PPs. Interestingly,we found that cell confluency at the time of harvest has less impact on the efficacy of pancreatic lineage formation or metabolic activity. This study sheds light on the interplay between metabolic activity and iPSC lineage specification,offering new insights into the robustness of iPSC self?renewal and differentiation for creating human tissues. Graphical Abstract and Lay SummaryHuman induced pluripotent stem cell (iPSC) differentiation into specific cell lineages often shows poor reproducibility due to cell pluripotency. This study demonstrated impact of iPSC seeding strategy on metabolic activity and differentiation potential,offering new insights into the robustness of iPSC self?renewal and differentiation for creating human tissues. View Publication

SummaryGlioblastomas are the most common malignant brain tumors in adults; they are highly aggressive and heterogeneous and show a high degree of plasticity. Here,we show that methyltransferase-like 7B (METTL7B) is an essential regulator of lineage specification in glioblastoma,with an impact on both tumor size and invasiveness. Single-cell transcriptomic analysis of these tumors and of cerebral organoids derived from expanded potential stem cells overexpressing METTL7B reveal a regulatory role for the gene in the neural stem cell-to-astrocyte differentiation trajectory. Mechanistically,METTL7B downregulates the expression of key neuronal differentiation players,including SALL2,via post-translational modifications of histone marks. Graphical abstract Highlights•METTL7B is highly expressed in human glioblastoma stem cells•METTL7B regulates tumor size and invasiveness in an in vivo xenograft model•METTL7B controls the neural stem cell-to-astrocyte differentiation trajectory•METTL7B regulates SALL2 expression via H3K27me3 modulation Constantinou et al. identify METTL7B as an essential regulator of lineage specification and a modulator of the expression of the transcription factor SALL2 with wide-ranging impacts on invasion and tumor growth in glioblastoma. View Publication

Stargardt disease (STGD),predominantly caused by mutations in the ABCA4 gene,is a leading cause of inherited retinal degeneration. Although several lines of mice expressing disease-causing variants have been produced,mice due to the lack of macular may not be the perfect model to mimic the characteristics of STGD. To address this knowledge gap,we generated retinal organoids from patient-derived induced pluripotent stem cells (iPSCs) harboring ABCA4 mutations and performed biological validation. The generated retinal organoids were subjected to single-cell RNA sequencing (scRNA-seq) at major developmental stages (40,90,150,200,and 260 days),and we additionally compared the transcriptomics with our recently published control retinal organoids to further confirm the reliability of the dataset. By using iPSCs carrying most common variant in Chinese STGD patients,the dataset not only provides a powerful resource for studying STGD,but also offers novels insight into the developmental mechanisms underlying ABCA4-associated pathological changes in the retinal organoid system. View Publication

Disease modeling with isogenic Induced Pluripotent Stem Cell (iPSC)-differentiated organoids serves as a powerful technique for studying disease mechanisms. Multiplexed coculture is crucial to mitigate batch effects when studying the genetic effects of disease-causing variants in differentiated iPSCs or organoids,and demultiplexing at the single-cell level can be conveniently achieved by assessing natural genetic barcodes. Here,to enable cost-efficient time-series experimental designs via multiplexed bulk and single-cell RNA-seq of hybrids,we introduce a computational method in our Vireo Suite,Vireo-bulk,to effectively deconvolve pooled bulk RNA-seq data by genotype reference,and thereby quantify donor abundance over the course of differentiation and identify differentially expressed genes among donors. Furthermore,with multiplexed scRNA-seq and bulk RNA-seq,we demonstrate the usefulness and necessity of a pooled design to reveal donor iPSC line heterogeneity during macrophage cell differentiation and to model rare WT1 mutation-driven kidney disease with chimeric organoids. Our work provides an experimental and analytic pipeline for dissecting disease mechanisms with chimeric organoids. IPSC-derived organoids model diseases. Multiplexed coculture and demultiplexing natural genetic barcodes aid in studying genetic effects. Here,authors introduce Vireo-bulk to deconvolve bulk RNA-seq data,quantify donor abundance and identify differentially expressed genes. View Publication

To uncover molecular changes underlying blood-brain-barrier dysfunction in Alzheimer’s disease,we performed single nucleus RNA sequencing in 24 Alzheimer’s disease and control brains and focused on vascular and astrocyte clusters as main cell types of blood-brain-barrier gliovascular-unit. The majority of the vascular transcriptional changes were in pericytes. Of the vascular molecular targets predicted to interact with astrocytic ligands,SMAD3,upregulated in Alzheimer’s disease pericytes,has the highest number of ligands including VEGFA,downregulated in Alzheimer’s disease astrocytes. We validated these findings with external datasets comprising 4,730 pericyte and 150,664 astrocyte nuclei. Blood SMAD3 levels are associated with Alzheimer’s disease-related neuroimaging outcomes. We determined inverse relationships between pericytic SMAD3 and astrocytic VEGFA in human iPSC and zebrafish models. Here,we detect vast transcriptome changes in Alzheimer’s disease at the gliovascular-unit,prioritize perturbed pericytic SMAD3-astrocytic VEGFA interactions,and validate these in cross-species models to provide a molecular mechanism of blood-brain-barrier disintegrity in Alzheimer’s disease. Systematic studies are needed to discover molecular determinants of blood brain barrier dysfunction in Alzheimer’s disease. This study identifies perturbed pericytic SMAD3-astrocytic VEGFA interactions as a potential driver of this dysfunction. View Publication

Diabetes involves the death or dysfunction of pancreatic ?-cells. Analysis of bulk sequencing from human samples and studies using in vitro and in vivo models suggest that endoplasmic reticulum and inflammatory signaling play an important role in diabetes progression. To better characterize cell type-specific stress response,we perform multiplexed single-cell RNA sequencing to define the transcriptional signature of primary human islet cells exposed to endoplasmic reticulum and inflammatory stress. Through comprehensive pair-wise analysis of stress responses across pancreatic endocrine and exocrine cell types,we define changes in gene expression for each cell type under different diabetes-associated stressors. We find that ?-,?-,and ductal cells have the greatest transcriptional response. We utilize stem cell-derived islets to study islet health through the candidate gene CIB1,which was upregulated under stress in primary human islets. Our findings provide insights into cell type-specific responses to diabetes-associated stress and establish a resource to identify targets for diabetes therapeutics. Endoplasmic reticulum and inflammatory stress are associated with diabetes. Maestas et al. use single-cell sequencing to profile primary human islets under stress and identified tissue and cell-type responses. View Publication

SummaryPattern recognition receptors (PRRs) induce host defense but can also induce exacerbated inflammatory responses. This raises the question of whether other mechanisms are also involved in early host defense. Using transcriptome analysis of disrupted transcripts in herpes simplex virus (HSV)-infected cells,we find that HSV infection disrupts the hypoxia-inducible factor (HIF) transcription network in neurons and epithelial cells. Importantly,HIF activation leads to control of HSV replication. Mechanistically,HIF activation induces autophagy,which is essential for antiviral activity. HSV-2 infection in vivo leads to hypoxia in CNS neurons,and mice with neuron-specific HIF1/2? deficiency exhibit elevated viral load and augmented PRR signaling and inflammatory gene expression in the CNS after HSV-2 infection. Data from human stem cell-derived neuron and microglia cultures show that HIF also exerts antiviral and inflammation-restricting activity in human CNS cells. Collectively,the HIF transcription factor system senses virus-induced hypoxic stress to induce cell-intrinsic antiviral responses and limit inflammation. Graphical abstract Highlights•HSV-1 and -2 disrupt the hypoxia-inducible factor (HIF) network in permissive cells•HIF activation induces autophagy,which exerts anti-HSV activity in neurons•Neuronal HIF activation regulates infection and inflammation in the infected brain Using transcriptome analysis of disrupted transcripts in herpes simplex virus-infected cells,Farahani et al. identify the hypoxia-inducible factor gene network to possess antiviral activity through induction of autophagy. This contributes to antiviral defense and regulation of inflammation during infection in the CNS. View Publication

SummaryCell size is a crucial physical property that significantly impacts cellular physiology and function. However,the influence of cell size on stem cell specification remains largely unknown. Here,we investigated the dynamic changes in cell size during the differentiation of human pluripotent stem cells into definitive endoderm (DE). Interestingly,cell size exhibited a gradual decrease as DE differentiation progressed with higher stiffness. Furthermore,the application of hypertonic pressure or chemical to accelerate the reduction in cell size significantly and specifically enhanced DE differentiation. By functionally intervening in mechanosensitive elements,we have identified actomyosin activity as a crucial mediator of both DE differentiation and cell size reduction. Mechanistically,the reduction in cell size induces actomyosin-dependent angiomotin (AMOT) nuclear translocation,which suppresses Yes-associated protein (YAP) activity and thus facilitates DE differentiation. Together,our study has established a novel connection between cell size diminution and DE differentiation,which is mediated by AMOT nuclear translocation. Additionally,our findings suggest that the application of osmotic pressure can effectively promote human endodermal lineage differentiation. Graphical abstract Highlights•Cell size decreases during the differentiation of human pluripotent stem cells into endoderm•Hypertonic pressure is conducive to the differentiation of human definitive endoderm•Actomyosin contributes to both size diminution and endoderm promotion under hypertonic pressure•Cell size diminution represses YAP activity via promoting AMOT nuclear translocation Jiang and colleagues show that cell size exhibits a gradual decrease during human endoderm differentiation. The application of hypertonic pressure or chemical to accelerate the reduction in cell size significantly and specifically enhanced endoderm differentiation. This enhancement is reliant on actomyosin activity and achieved by promoting the nuclear translocation of AMOT,thereby repressing YAP activity. View Publication