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BackgroundSpecific microglia responses are thought to contribute to the development and progression of neurodegenerative diseases,including Parkinson’s disease (PD). However,the phenotypic acquisition of microglial cells and their role during the underlying neuroinflammatory processes remain largely elusive. Here,according to the multiple-hit hypothesis,which stipulates that PD etiology is determined by a combination of genetics and various environmental risk factors,we investigate microglial transcriptional programs and morphological adaptations under PARK7/DJ-1 deficiency,a genetic cause of PD,during lipopolysaccharide (LPS)-induced inflammation.MethodsUsing a combination of single-cell RNA-sequencing,bulk RNA-sequencing,multicolor flow cytometry and immunofluorescence analyses,we comprehensively compared microglial cell phenotypic characteristics in PARK7/DJ-1 knock-out (KO) with wildtype littermate mice following 6- or 24-h intraperitoneal injection with LPS. For translational perspectives,we conducted corresponding analyses in human PARK7/DJ-1 mutant induced pluripotent stem cell (iPSC)-derived microglia and murine bone marrow-derived macrophages (BMDMs).ResultsBy excluding the contribution of other immune brain resident and peripheral cells,we show that microglia acutely isolated from PARK7/DJ-1 KO mice display a distinct phenotype,specially related to type II interferon and DNA damage response signaling,when compared with wildtype microglia,in response to LPS. We also detected discrete signatures in human PARK7/DJ-1 mutant iPSC-derived microglia and BMDMs from PARK7/DJ-1 KO mice. These specific transcriptional signatures were reflected at the morphological level,with microglia in LPS-treated PARK7/DJ-1 KO mice showing a less amoeboid cell shape compared to wildtype mice,both at 6 and 24 h after acute inflammation,as also observed in BMDMs.ConclusionsTaken together,our results show that,under inflammatory conditions,PARK7/DJ-1 deficiency skews microglia towards a distinct phenotype characterized by downregulation of genes involved in type II interferon signaling and a less prominent amoeboid morphology compared to wildtype microglia. These findings suggest that the underlying oxidative stress associated with the lack of PARK7/DJ-1 affects microglia neuroinflammatory responses,which may play a causative role in PD onset and progression.Supplementary InformationThe online version contains supplementary material available at 10.1186/s12974-024-03164-x. View Publication

AbstractINTRODUCTIONAfrica,home to 1.4 billion people and the highest genetic diversity globally,harbors unique genetic variants crucial for understanding complex diseases like neurodegenerative disorders. However,African populations remain underrepresented in induced pluripotent stem cell (iPSC) collections,limiting the exploration of population?specific disease mechanisms and therapeutic discoveries.METHODSTo address this gap,we established an open?access African Somatic and Stem Cell Bank.RESULTSIn this initial phase,we generated 10 rigorously characterized iPSC lines from fibroblasts representing five Nigerian ethnic groups and both sexes. These lines underwent extensive profiling for pluripotency,genetic stability,differentiation potential,and Alzheimer's disease and Parkinson's disease risk variants. Clustered regularly interspaced palindromic repeats (CRISPR)/CRISPR?associated protein 9 technology was used to introduce frontotemporal dementia?associated MAPT mutations (P301L and R406W).DISCUSSIONThis collection offers a renewable,genetically diverse resource to investigate disease pathogenicity in African populations,facilitating breakthroughs in neurodegenerative research,drug discovery,and regenerative medicine.Highlights We established an open?access African Somatic and Stem Cell Bank.10 induced pluripotent stem cell lines from five Nigerian ethnic groups were rigorously characterized.Clustered regularly interspaced palindromic repeats (CRISPR)/CRISPR?associated protein 9 technology was used to introduce frontotemporal dementia?causing MAPT mutations.The African Somatic and Stem Cell Bank is a renewable,genetically diverse resource for neurodegenerative research. View Publication

Alcohol use disorder (AUD) is the most prevalent substance use disorder worldwide. Acamprosate and naltrexone are anti-craving drugs used in AUD pharmacotherapy. However,molecular mechanisms underlying their anti-craving effect remain unclear. This study utilized a patient-derived induced pluripotent stem cell (iPSC)-based model system and anti-craving drugs that are used to treat AUD as “molecular probes” to identify possible mechanisms associated with alcohol craving. We examined the pathophysiology of craving and anti-craving drugs by performing functional genomics studies using iPSC-derived astrocytes and next-generation sequencing. Specifically,RNA sequencing performed using peripheral blood mononuclear cells from AUD patients with extreme values for alcohol craving intensity prior to treatment showed that inflammation-related pathways were highly associated with alcohol cravings. We then performed a genome-wide assessment of chromatin accessibility and gene expression profiles of induced iPSC-derived astrocytes in response to ethanol or anti-craving drugs. Those experiments identified drug-dependent epigenomic signatures,with IRF3 as the most significantly enriched motif in chromatin accessible regions. Furthermore,the activation of IRF3 was associated with ethanol-induced endoplasmic reticulum (ER) stress which could be attenuated by anti-craving drugs,suggesting that ER stress attenuation might be a target for anti-craving agents. In conclusion,we found that craving intensity was associated with alcohol consumption and treatment outcomes. Our functional genomic studies suggest possible relationships among craving,ER stress,IRF3 and the actions of anti-craving drugs. View Publication

Human GWAS have shown that obesogenic FTO polymorphisms correlate with lean mass,but the mechanisms have remained unclear. It is counterintuitive because lean mass is inversely correlated with obesity and metabolic diseases. Here,we use CRISPR to knock-in FTOrs9939609-A into hESC-derived tissue models,to elucidate potentially hidden roles of FTO during development. We find that among human tissues,FTOrs9939609-A most robustly affect human muscle progenitors’ proliferation,differentiation,senescence,thereby accelerating muscle developmental and metabolic aging. An edited FTOrs9939609-A allele over-stimulates insulin/IGF signaling via increased muscle-specific enhancer H3K27ac,FTO expression and m6A demethylation of H19 lncRNA and IGF2 mRNA,with excessive insulin/IGF signaling leading to insulin resistance upon replicative aging or exposure to high fat diet. This FTO-m6A-H19/IGF2 circuit may explain paradoxical GWAS findings linking FTOrs9939609-A to both leanness and obesity. Our results provide a proof-of-principle that CRISPR-hESC-tissue platforms can be harnessed to resolve puzzles in human metabolism. Human GWAS paradoxically linked FTO SNPs to both lean mass and sarcopenia/obesity. Here,Guang et al used CRISPR-edited stem cells to reveal that an obesogenic FTO SNP accelerates both muscle development and aging,by increasing RNA m6A demethylation. View Publication

Mutation in CUL4B gene is one of the most common causes for X-linked intellectual disability (XLID). CUL4B is the scaffold protein in CUL4B-RING ubiquitin ligase (CRL4B) complex. While the roles of CUL4B in cancer progression and some developmental processes like adipogenesis,osteogenesis,and spermatogenesis have been studied,the mechanisms underlying the neurological disorders in patients with CUL4B mutations are poorly understood. Here,using 2D neuronal culture and cerebral organoids generated from the patient-derived induced pluripotent stem cells and their isogenic controls,we demonstrate that CUL4B is required to prevent premature cell cycle exit and precocious neuronal differentiation of neural progenitor cells. Moreover,loss-of-function mutations of CUL4B lead to increased synapse formation and enhanced neuronal excitability. Mechanistically,CRL4B complex represses transcription of PPP2R2B and PPP2R2C genes,which encode two isoforms of the regulatory subunit of protein phosphatase 2 A (PP2A) complex,through catalyzing monoubiquitination of H2AK119 in their promoter regions. CUL4B mutations result in upregulated PP2A activity,which causes inhibition of AKT and ERK,leading to premature cell cycle exit. Activation of AKT and ERK or inhibition of PP2A activity in CUL4B mutant organoids rescues the neurogenesis defect. Our work unveils an essential role of CUL4B in human cortical development. View Publication

The significant advances in the differentiation of human pluripotent stem (hPS) cells into pancreatic endocrine cells,including functional ?-cells,have been based on a detailed understanding of the underlying developmental mechanisms. However,the final differentiation steps,leading from endocrine progenitors to mono-hormonal and mature pancreatic endocrine cells,remain to be fully understood and this is reflected in the remaining shortcomings of the hPS cell-derived islet cells (SC-islet cells),which include a lack of ?-cell maturation and variability among different cell lines. Additional signals and modifications of the final differentiation steps will have to be assessed in a combinatorial manner to address the remaining issues and appropriate reporter lines would be useful in this undertaking. Here we report the generation and functional validation of hPS cell reporter lines that can monitor the generation of INS+ and GCG+ cells and their resolution into mono-hormonal cells (INSeGFP,INSeGFP/GCGmCHERRY) as well as ?-cell maturation (INSeGFP/MAFAmCHERRY) and function (INSGCaMP6). The reporter hPS cell lines maintained strong and widespread expression of pluripotency markers and differentiated efficiently into definitive endoderm and pancreatic progenitor (PP) cells. PP cells from all lines differentiated efficiently into islet cell clusters that robustly expressed the corresponding reporters and contained glucose-responsive,insulin-producing cells. To demonstrate the applicability of these hPS cell reporter lines in a high-content live imaging approach for the identification of optimal differentiation conditions,we adapted our differentiation procedure to generate SC-islet clusters in microwells. This allowed the live confocal imaging of multiple SC-islets for a single condition and,using this approach,we found that the use of the N21 supplement in the last stage of the differentiation increased the number of monohormonal ?-cells without affecting the number of ?-cells in the SC-islets. The hPS cell reporter lines and the high-content live imaging approach described here will enable the efficient assessment of multiple conditions for the optimal differentiation and maturation of SC-islets. View Publication

SummaryGene-switch techniques hold promising applications in contemporary genetics research,particularly in disease treatment and genetic engineering. Here,we developed a compact drug-induced splicing system that maintains low background using a human ubiquitin C (hUBC) promoter and optimized drug (LMI070) binding sequences based on the Xon switch system. To ensure precise subcellular localization of the protein of interest (POI),we inserted a 2A self-cleaving peptide between the extra N-terminal peptide and POI. This streamlined and optimized switch system,named miniXon2G,effectively regulated POIs in different subcellular localizations both in vitro and in vivo. Furthermore,miniXon2G could be integrated into endogenous gene loci,resulting in precise,reversible regulation of target genes by both endogenous regulators and drugs. Overall,these findings highlight the performance of miniXon2G in controlling protein expression with great potential for general applicability to diverse biological scenarios requiring precise and delicate regulation. Graphical abstract Highlights•miniXon2G is a compact and versatile version of the Xon gene-switch system•A P2A peptide eliminates residual peptides from functional proteins•We demonstrate applications on multiple proteins of interest•miniXon2G is a precise and reversible switch system with minimal background expression MotivationThe Xon drug-inducible splice-switch system is a simple and highly adaptable tool for regulated protein expression. We sought to further engineer this system to expand its applications in contemporary genetics research. In particular,we focused on reducing the size of the switch elements,maintaining minimal background expression,introducing a feature to remove extraneous peptide fragments,and demonstrating genomic integration and validation on a range of targets. Chi et al. develop a compact and versatile miniXon2G drug-inducible splice-switch system based on the Xon system. It features a reduced size,minimal background,and the removal of extraneous peptide fragments,enabling application to various biological scenarios that require precise expression control. View Publication

ABSTRACTAutism spectrum disorder (ASD) and congenital heart disease (CHD) frequently co-occur,yet the underlying molecular mechanisms of this comorbidity remain unknown. Given that children with CHD are identified as newborns,understanding which CHD variants are associated with autism could help select individuals for early intervention. Autism gene perturbations commonly dysregulate neural progenitor cell (NPC) biology,so we hypothesized that CHD genes disrupting neurogenesis are more likely to increase ASD risk. Therefore,we performed an in vitro pooled CRISPR interference screen to identify CHD genes disrupting NPC biology and identified 45 CHD genes. A cluster of ASD and CHD genes are enriched for ciliary biology,and perturbing any one of seven such genes (CEP290,CHD4,KMT2E,NSD1,OFD1,RFX3 and TAOK1) impairs primary cilia formation in vitro. In vivo investigation of TAOK1 in Xenopus tropicalis reveals a role in motile cilia formation and heart development,supporting its prediction as a CHD gene. Together,our findings highlight a set of CHD genes that may carry risk for ASD and underscore the role of cilia in shared ASD and CHD biology. Highlighted Article: The increased likelihood of autism in individuals with congenital heart disease may stem from shared genetic mechanisms centered on cilia biology. View Publication

PurposeOxaliplatin-induced peripheral neuropathy (OIPN) is a chronic,debilitating late effect following oxaliplatin treatment. Neurofilament light chain (NfL) is a structural protein found in nerve axons that was investigated upon oxaliplatin exposure in vitro and in vivo correlated to symptoms of OIPN in colorectal cancer patients receiving oxaliplatin.MethodsHuman sensory neurons,derived from induced pluripotent stem cells,were exposed to clinically relevant concentrations of oxaliplatin in vitro,with NfL concentrations measured in the cell medium. The prospective clinical study included patients with colorectal cancer undergoing chemotherapy therapy with or without oxaliplatin. Possible OIPN was defined as bilateral presence of numbness and/or presence of pricking sensations in the feet documented in an interview at the time of blood sampling prior to,3,and 6 months after initiating treatment.ResultsOxaliplatin exposure led to a dose-dependent NfL increase in vitro. In the clinical cohort of 30 patients (18 in the oxaliplatin group),NfL levels rose at 3 and 6 months compared to controls. NfL level changes correlated to OIPN symptoms at the 6-month timepoint (rho 0.81,p? View Publication

AbstractTGF-? signaling family plays an essential role to regulate fate decisions in pluripotency and lineage specification. How the action of TGF-? family signaling is intrinsically executed remains not fully elucidated. Here,we show that HBO1,a MYST histone acetyltransferase (HAT) is an essential cell intrinsic determinant for TGF-? signaling in human embryonic stem cells (hESCs). HBO1?/? hESCs fail to response to TGF-? signaling to maintain pluripotency and spontaneously differentiate into neuroectoderm. Moreover,HBO1 deficient hESCs show complete defect in mesendoderm specification in BMP4-triggered gastruloids or teratomas. Molecularly,HBO1 interacts with SMAD4 and co-binds the open chromatin labeled by H3K14ac and H3K4me3 in undifferentiated hESCs. Upon differentiation,HBO1/SMAD4 co-bind and maintain the mesoderm genes in BMP4-triggered mesoderm cells while lose chromatin occupancy in neural cells induced by dual-SMAD inhibition. Our data reveal an essential role of HBO1,a chromatin factor to determine the action of SMAD in both human pluripotency and mesendoderm specification. Graphical Abstract Graphical Abstract View Publication

To investigate intestinal health and its potential disruptors in vitro,representative models are required. Human induced pluripotent stem cell (hiPSC)-derived intestinal epithelial cells (IECs) more closely resemble the in vivo intestinal tissue than conventional in vitro models like human colonic adenocarcinoma Caco-2 cells. However,the potential of IECs to study immune-related responses upon external stimuli has not been investigated in detail yet. The aim of the current study was to evaluate immune-related effects of IECs by challenging them with a pro-inflammatory cytokine cocktail. Subsequently,the effects of Lactiplantibacillus plantarum WCFS1 were investigated in unchallenged and challenged IECs. All exposures were compared to Caco-2 cells and in vivo data where possible. Upon the inflammatory challenge,IECs and Caco-2 cells induced a pro-inflammatory response which was strongest in IECs. Heat-killed L. plantarum exerted the strongest effect on immune parameters in the IEC model,while L. plantarum in the stationary growth phase had most pronounced effects on immune-related gene expression in Caco-2 cells. Unfortunately,comparison to in vivo transcriptomics data showed limited similarities,which could be explained by essential differences in the study setups. Altogether,hiPSC-derived IECs show a high potential as a model to study immune-related responses in the intestinal epithelium in vitro.Supplementary InformationThe online version contains supplementary material available at 10.1038/s41598-024-74802-w. View Publication

AbstractRett syndrome (RTT) is a severe neurodevelopmental disorder primarily caused by loss-of-function mutations in the MECP2 gene,resulting in diverse cellular dysfunctions. Here,we investigated the role of the long noncoding RNA (lncRNA) NEAT1 in the context of MeCP2 deficiency using human neural cells and RTT patient samples. Through single-cell RNA sequencing and molecular analyses,we found that NEAT1 is markedly downregulated in MECP2 knockout (KO) cells at various stages of neural differentiation. NEAT1 downregulation correlated with aberrant activation of the mTOR pathway,abnormal protein metabolism,and dysregulated autophagy,contributing to the accumulation of protein aggregates and impaired mitochondrial function. Reactivation of NEAT1 in MECP2-KO cells rescued these phenotypes,indicating its critical role downstream of MECP2. Furthermore,direct RNA–RNA interaction was revealed as the key process for NEAT1 influence on autophagy genes,leading to altered subcellular localization of specific autophagy-related messenger RNAs and impaired biogenesis of autophagic complexes. Importantly,NEAT1 restoration rescued the morphological defects observed in MECP2-KO neurons,highlighting its crucial role in neuronal maturation. Overall,our findings elucidate lncRNA NEAT1 as a key mediator of MeCP2 function,regulating essential pathways involved in protein metabolism,autophagy,and neuronal morphology. Graphical Abstract Graphical Abstract View Publication