技术资料

In this study,we developed a cell system to study TCF4 in human oligodendrocyte differentiation,showed that TCF4 regulates human oligodendroglial differentiation in a dose-dependent manner,and established a system to dissect TCF4 function in a human tissue–like context. Heterozygous mutations of TCF4 in humans cause Pitt–Hopkins syndrome,a neurodevelopmental disease associated with intellectual disability and brain malformations. Although most studies focus on the role of TCF4 in neural stem cells and neurons,we here set out to assess the implication of TCF4 for oligodendroglial differentiation. We discovered that both monoallelic and biallelic mutations in TCF4 result in a diminished capacity to differentiate human neural progenitor cells toward myelinating oligodendrocytes through the forced expression of the transcription factors SOX10,OLIG2,and NKX6.2. Using this experimental strategy,we established a novel organoid model,which generates oligodendroglial cells within a human neurogenic tissue–like context. Also,here we found a reduced ability of TCF4 heterozygous cells to differentiate toward oligodendroglial cells. In sum,we establish a role of human TCF4 in oligodendrocyte differentiation and provide a model system,which allows to dissect the disease etiology in a human tissue–like context. View Publication

Stem cell-derived islet cell therapy can effectively treat type 1 diabetes,but its efficacy is hindered by low oxygen supply post-transplantation,particularly in subcutaneous spaces and encapsulation devices,leading to cell dysfunction. The response to hypoxia and effective strategies to alleviate its detrimental effects remain poorly understood. Here,we show that ? cells within stem cell-derived islets gradually undergo a decline in cell identity and metabolic function in hypoxia. This is linked to reduced expression of immediate early genes (EGR1,FOS,and JUN),which downregulates key ? cell transcription factors. We further identified genes important for maintaining ? cell fitness in hypoxia,with EDN3 as a potent player. Elevated EDN3 expression preserves ? cell identity and function in hypoxia by modulating genes involved in ? cell maturation,glucose sensing and regulation. These insights improve the understanding of hypoxia’s impact on stem cell-derived islets,offering a potential intervention for clinical applications. Hypoxia impairs the efficacy of stem cell-derived islet cell therapy,making it a potential barrier for treatment of type 1 diabetes. Wang et al. identify EDN3 as a key factor that preserves ? cell identity and function in hypoxia,offering possible strategies to improve therapeutic outcomes. View Publication

During a heart attack,ischemia causes losses of billions of cells; this is especially concerning given the minimal regenerative capability of cardiomyocytes (CMs). Heart remuscularization utilizing stem cells has improved cardiac outcomes despite little cell engraftment,thereby shifting focus to cell-free therapies. Consequently,we chose induced pluripotent stem cells (iPSCs) given their pluripotent nature,efficacy in previous studies,and easy obtainability from minimally invasive techniques. Nonetheless,using iPSC secretome-based therapies for treating injured CMs in a clinical setting is ill-understood. We hypothesized that the iPSC secretome,regardless of donor health,would improve cardiovascular outcomes in the CM model of ischemia–reperfusion (IR) injury. Episomal-generated iPSCs from healthy and dilated cardiomyopathy (DCM) donors,passaged 6–10 times,underwent 24 h incubation in serum-free media. Protein content of the secretome was analyzed by mass spectroscopy and used to treat AC16 immortalized CMs during 5 h reperfusion following 24 h of hypoxia. IPSC-derived secretome content,independent of donor health status,had elevated expression of proteins involved in cell survival pathways. In IR conditions,iPSC-derived secretome increased cell survival as measured by metabolic activity (p < 0.05),cell viability (p < 0.001),and maladaptive cellular remodelling (p = 0.052). Healthy donor-derived secretome contained increased expression of proteins related to calcium contractility compared to DCM donors. Congruently,only healthy donor-derived secretomes improved CM intracellular calcium concentrations (p < 0.01). Heretofore,secretome studies mainly investigated differences relating to cell type rather than donor health. Our work suggests that healthy donors provide more efficacious iPSC-derived secretome compared to DCM donors in the context of IR injury in human CMs. These findings illustrate that the regenerative potential of the iPSC secretome varies due to donor-specific differences. View Publication

This paper presents a 360°,size-adjustable microelectrode array (MEA) system for the long-term electrophysiological monitoring of cerebral organoids derived from human pluripotent stem cells. The system consists of eight independently positionable multielectrode probes,each carrying eight electrodes arranged vertically. This configuration resulted in 64 recording channels surrounding the organoid. The multielectrode probes were mounted on custom-designed miniature manipulators with three degrees of freedom. This setup enabled positioning and contact with organoids of varying sizes (approximately 1–3.7 mm in diameter). The design allowed circumferential access and facilitated standard incubator-based cultivation without disrupting the recording setup. Fabricated using flexible printed circuit technology,this MEA system offers relatively low production costs. It is also amenable to widespread implementation in laboratory settings. Experimental results demonstrated the successful recording of neuronal activity,including spike detection and signal stability,over 2 weeks of continuous organoid culture. These results suggests that the three-dimensional system provides broad spatial coverage and supports long-term monitoring for basic biomedical research. It also holds potential for future applications such as biohybrid computing. View Publication

Genetic variants often produce complex phenotypic effects that confound current assays and predictive models. We developed Variant in situ sequencing (VIS-seq),a pooled,image-based method that measures variant effects on molecular and cellular phenotypes in diverse cell types. Applying VIS-seq to ~3,000 LMNA and PTEN variants yielded high-dimensional morphological profiles that captured variant-driven changes in protein abundance,localization,activity and cell architecture. We identified gain-of-function LMNA variants that reshape the nucleus and autism-associated PTEN variants that mislocalize. Morphological profiles predicted variant pathogenicity with near-perfect accuracy and distinguished autism-linked from tumor syndrome-linked PTEN variants. Most variants impacted a multidimensional continuum of phenotypes not recapitulated by any single functional readout. By linking protein variation to cell images at scale,we illuminate how variant effects cascade from molecular to subcellular to cell morphological phenotypes,providing a framework for resolving the complexity of variant function. View Publication

Mutations in the microtubule binding motor protein,kinesin family member 5A (KIF5A),cause the fatal motor neuron disease,Amyotrophic Lateral Sclerosis. While KIF5 family members transport a variety of cargos along axons,it is still unclear which cargos are affected by KIF5A mutations. We generated KIF5A null mutant human motor neurons to investigate the impact of KIF5A loss on the transport of various cargoes and its effect on motor neuron function at two different timepoints in vitro. The absence of KIF5A resulted in reduced neurite complexity in young motor neurons (DIV14) and significant defects in axonal regeneration capacity at all developmental stages. KIF5A loss did not affect neurofilament transport but resulted in decreased mitochondria motility and anterograde speed at DIV42. More prominently,KIF5A depletion strongly reduced anterograde transport of SFPQ-associated RNA granules in DIV42 motor neuron axons. We conclude that KIF5A most prominently functions in human motor neurons to promote axonal regrowth after injury as well as to anterogradely transport mitochondria and,to a larger extent,SFPQ-associated RNA granules in a time-dependent manner. View Publication

Single-cell technologies can measure the expression of thousands of molecular features in individual cells undergoing dynamic biological processes. While examining cells along a computationally-ordered pseudotime trajectory can reveal how changes in gene or protein expression impact cell fate,identifying such dynamic features is challenging due to the inherent noise in single-cell data. Here,we present DELVE,an unsupervised feature selection method for identifying a representative subset of molecular features which robustly recapitulate cellular trajectories. In contrast to previous work,DELVE uses a bottom-up approach to mitigate the effects of confounding sources of variation,and instead models cell states from dynamic gene or protein modules based on core regulatory complexes. Using simulations,single-cell RNA sequencing,and iterative immunofluorescence imaging data in the context of cell cycle and cellular differentiation,we demonstrate how DELVE selects features that better define cell-types and cell-type transitions. DELVE is available as an open-source python package: https://github.com/jranek/delve. Characteristic genes or proteins driving continuous biological processes are difficult to uncover from noisy single-cell data. Here,authors present DELVE,an unsupervised feature selection method to identify core molecular features driving cell fate decisions. View Publication

SummaryThe cornea and sclera are distinct adjacent tissues,yet their stromal cells originate from common neural crest cells (NCCs). Sclerocornea is a disease characterized by an indistinguishable boundary between the cornea and sclera. Previously,we identified a RAD21 mutation in a sclerocornea pedigree. Here,we investigated the impacts of RAD21 on NCC activities during eye development. RAD21 deficiency caused upregulation of PCDHGC3. Both RAD21 knockdown and PCDHGC3 upregulation disrupted the migration of NCCs. Transcriptome analysis indicated that WNT9B had 190.9-fold higher expression in scleral stroma than in corneal stroma. WNT9B was also significantly upregulated by both RAD21 knockdown and PCDHGC3 overexpression,and knock down of WNT9B rescued the differentiation and migration of NCCs with RAD21 deficiency. Consistently,overexpressing wnt9b in Xenopus tropicalis led to ocular developmental abnormalities. In summary,WNT9B is a determinant factor during NCC differentiation into corneal keratocytes or scleral stromal cells and is affected by RAD21 expression. Graphical abstract Highlights•Established a stable differentiation protocol from hESCs to corneal keratocytes•RAD21 deficiency affected the proliferation and migration ability of NCCs•Increased scleral markers after RAD21 knockdown during NCC differentiation to cornea•WNT9B is a crucial mediator during ocular NCC differentiation Cell biology; Developmental biology View Publication

BackgroundTimely resolution of innate immune responses activated by surgical intervention is crucial for patient recovery. While cytokines and innate immune cells are critical in inflammation resolution,the specific role of IL-18 in these processes remains controversial and underexplored.MethodsWe investigate determinants of successful recovery using peripheral blood samples from orthopedic surgery (ORT) patients (n?=?33) at T0 (before surgery),T1 (24 h after surgery) and T2 (3 days after surgery). Monocytes from ORT patients underwent immunophenotyping together with bulk transcriptomic analysis. We found that IL-18 strongly defines the recovery immune signature. These results were further validated in vitro by comparing IL-18 and TNF-? effects on monocytes,and in 3D human intestine organoids together with single cell (sc)-RNAseq analysis.ResultsTranscriptomics of ORT monocytes revealed upregulation of ITG family integrins,namely ITGB3 and ITGB5,CXCL family chemokines,notably CXCL1-3,CXCL5,and SCL/TAL1 factor controlling differentiation and migration,but not pro-inflammatory genes. Similar changes were observed in IL-18 stimulated healthy donor monocytes in vitro,including an increase in CD11b,CD64,and CD86 levels,accompanied by increased phosphorylation of Akt but not NF?B. These changes were attenuated in the presence of TNF-?,thus showing a unique role of IL-18 when acting alone without its most frequent paired cytokine TNF-?. We further confirmed that IL-18 induces monocyte-macrophage transition and migration using human intestinal organoids. Finally,TNF-?/IL-18 ratio showed a high predictive value of clinical severity in septic patients.ConclusionsWe propose a novel role of IL-18 on monocyte migration and macrophage transition characterizing successful orthopedic surgery recovery,as well as the ratio of IL-18/TNF-? as a novel marker of inflammation resolution,with potential implications for patient monitoring and therapeutic strategies.Supplementary InformationThe online version contains supplementary material available at 10.1186/s12967-025-06652-7. View Publication

Hydrogen Peroxide (H2O2) is a central oxidant in redox biology due to its pleiotropic role in physiology and pathology. However,real-time monitoring of H2O2 in living cells and tissues remains a challenge. We address this gap with the development of an optogenetic hydRogen perOxide Sensor (oROS),leveraging the bacterial peroxide binding domain OxyR. Previously engineered OxyR-based fluorescent peroxide sensors lack the necessary sensitivity and response speed for effective real-time monitoring. By structurally redesigning the fusion of Escherichia coli (E. coli) ecOxyR with a circularly permutated green fluorescent protein (cpGFP),we created a novel,green-fluorescent peroxide sensor oROS-G. oROS-G exhibits high sensitivity and fast on-and-off kinetics,ideal for monitoring intracellular H2O2 dynamics. We successfully tracked real-time transient and steady-state H2O2 levels in diverse biological systems,including human stem cell-derived neurons and cardiomyocytes,primary neurons and astrocytes,and mouse brain ex vivo and in vivo. These applications demonstrate oROS’s capabilities to monitor H2O2 as a secondary response to pharmacologically induced oxidative stress and when adapting to varying metabolic stress. We showcased the increased oxidative stress in astrocytes via A?-putriscine-MAOB axis,highlighting the sensor’s relevance in validating neurodegenerative disease models. Lastly,we demonstrated acute opioid-induced generation of H2O2 signal in vivo which highlights redox-based mechanisms of GPCR regulation. oROS is a versatile tool,offering a window into the dynamic landscape of H2O2 signaling. This advancement paves the way for a deeper understanding of redox physiology,with significant implications for understanding diseases associated with oxidative stress,such as cancer,neurodegenerative,and cardiovascular diseases. 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

Autism 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. View Publication