技术资料

SummaryInducible loss-of-function strategies are crucial for understanding gene function. However,creating inducible,multiple-gene knockout models is challenging and time-consuming. Here,we present a protocol for establishing a doxycycline-inducible CRISPR interference (CRISPRi) system to concurrently silence multiple genes in human induced pluripotent stem cells (hPSCs). We describe the steps for establishing host CRISPRi hPSCs,designing and cloning single-guide RNAs (sgRNAs) into a lentivirus plasmid,and establishing monoclonal CRISPRi hPSC lines transduced with sgRNAs. We also detail the procedures for selecting effective CRISPRi clones.For complete details on the use and execution of this protocol,please refer to Matsui et al.1 Graphical abstract Highlights•Dox-inducible CRISPRi system to silence multiple genes concurrently•Instructions for generating CRISPRi hPSCs transduced with four sgRNAs•FOXA1/A2/A3-CRISPRi system represses expression of all three FOXA genes by 95% Publisher’s note: Undertaking any experimental protocol requires adherence to local institutional guidelines for laboratory safety and ethics. Inducible loss-of-function strategies are crucial for understanding gene function. However,creating inducible,multiple-gene knockout models is challenging and time-consuming. Here,we present a protocol for establishing a doxycycline-inducible CRISPR interference (CRISPRi) system to concurrently silence multiple genes in human induced pluripotent stem cells (hPSCs). We describe the steps for establishing host CRISPRi hPSCs,designing and cloning single-guide RNAs (sgRNAs) into a lentivirus plasmid,and establishing monoclonal CRISPRi hPSC lines transduced with sgRNAs. We also detail the procedures for selecting effective CRISPRi clones. View Publication

The oral mucosa plays an important role in maintaining oral and systemic health by protecting the body from harmful environmental stimuli and pathogens. Current reconstructed human gingiva models (RhG) serve as valuable testing platforms for safety and efficacy testing of dental materials,however they lack important phenotypic characteristics typical of the gingival epithelium. We aimed to determine whether incorporating induced pluripotent stem cells (iPSCs) into the hydrogel of a cell-line RhG (reconstructed epithelium on fibroblast-populated-hydrogel) would improve its phenotype. Immortalized human gingival fibroblasts were resuspended with and without iPSCs in collagen-fibrin hydrogels and gingival keratinocytes were seeded on top of the hydrogels to construct RhGs. RhGs were cultured at air-liquid interface for 1,2,4 and 6 weeks and extensively characterized by immunohistochemistry. In situ hybridization for X and Y chromosomes was conducted to identify female iPSCs and male fibroblasts in the RhGs. iPSC-RhGs showed increased epithelial thickening,rete ridge formation,increased cell proliferation and normalized expression of differentiation markers (keratins,involucrin,loricrin,SKALP/elafin) compared to standard RhGs,resulting in an epithelial phenotype very similar to the native gingiva. An increase in apoptotic cells was detected in iPSC-RhGs after 1 week air-exposed culture,and no iPSCs were detected in the hydrogels after 2 weeks air-exposed culture. The increase in apoptotic iPSCs after 1 week air-exposed culture correlated with an increase in keratinocyte proliferation responsible for the superior phenotype observed at 2 weeks. View Publication

Liver disease secondary to an inborn or genetic error of metabolism is a rare group of conditions often associated with chronic ill health and reduced survival. Curative treatment is mainly limited to liver transplantation with major long-term risks. Cell therapy is a promising alternative,but current approaches are ineffective. To develop histotripsy,a non-invasive high-intensity ultrasound procedure for liver tissue mechanical ablation,combined with hepatocyte stem cell implantation as a novel method of reversing liver failure from genetic disease. This study assessed the safety and feasibility of this approach in healthy rodents. Under general anaesthesia,adult rats (n = 12) underwent laparotomy and ultrasound histotripsy to the exposed liver. Around 1 million cells were injected into a single histotripsy cavity in each animal under direct vision (n = 10) with two receiving only histotripsy without cell injection. On completion of cell implant,haemostasis was secured,laparotomy incision closed and the animals recovered. Groups of animals were terminated immediately and after 4 h,8 h,24 h,4 days and 7 days. Liver and vital organs were assessed for procedure-related injuries and evidence of viable implanted cells by histology and immunohistochemistry. All animals successfully recovered,and no complication was observed throughout the study. Created cavities were successfully identified in histological analysis of rat. The presence of human cells was verified using anti-human nuclei antibody confirming successful implantation of liver organoids into decellularised cavities. In this feasibility study,we demonstrated suitability of histotripsy to create decellularised cavities in liver parenchyma. In addition,feasibility of direct transplantation of undissociated liver organoids into the created cavities was demonstrated as a potential approach to treat inborn liver disease by creating nodules of healthy cells capable of performing loss metabolic function. Therapeutic efficacy of this approach will be evaluated in an upcoming study. Graphical Abstract View Publication

For genome editing,the use of CRISPR ribonucleoprotein (RNP) complexes is well established and often the superior choice over plasmid-based or viral strategies. RNPs containing dCas9 fusion proteins,which enable the targeted manipulation of transcriptomes and epigenomes,remain significantly less accessible. Here,we describe the production,delivery,and optimization of second generation CRISPRa RNPs (dRNPs). We characterize the transcriptional and cellular consequences of dRNP treatments in a variety of human target cells and show that the uptake is very efficient. The targeted activation of genes demonstrates remarkable potency,even for genes that are strongly silenced,such as developmental master transcription factors. In contrast to DNA-based CRISPRa strategies,gene activation is immediate and characterized by a sharp temporal precision. We also show that dRNPs allow very high-target multiplexing,enabling undiminished gene activation of multiple genes simultaneously. Applying these insights,we find that intensive target multiplexing at single promoters synergistically elevates gene transcription. Finally,we demonstrate in human stem and differentiated cells that the preferable features of dRNPs allow to instruct and convert cell fates efficiently without the need for DNA delivery or viral vectors. View Publication

Background: Effective molecular diagnosis of congenital diseases hinges on comprehensive genomic analysis,traditionally reliant on various methodologies specific to each variant type-whole exome or genome sequencing for single nucleotide variants (SNVs),array CGH for copy-number variants (CNVs),and microscopy for structural variants (SVs). Methods: We introduce a novel,integrative approach combining exome sequencing with chromosome conformation capture,termed Exo-C. This method enables the concurrent identification of SNVs in clinically relevant genes and SVs across the genome and allows analysis of heterozygous and mosaic carriers. Enhanced with targeted long-read sequencing,Exo-C evolves into a cost-efficient solution capable of resolving complex SVs at base-pair accuracy. Results: Applied to 66 human samples Exo-C achieved 100% recall and 73% precision in detecting chromosomal translocations and SNVs. We further benchmarked its performance for inversions and CNVs and demonstrated its utility in detecting mosaic SVs and resolving diagnostically challenging cases. Conclusions: Through several case studies,we demonstrate how Exo-C's multifaceted application can effectively uncover diverse causative variants and elucidate disease mechanisms in patients with rare disorders. View Publication

Alternative splicing is a major contributor of transcriptomic complexity,but the extent to which transcript isoforms are translated into stable,functional protein isoforms is unclear. Furthermore,detection of relatively scarce isoform-specific peptides is challenging,with many protein isoforms remaining uncharted due to technical limitations. Recently,a family of advanced targeted MS strategies,termed internal standard parallel reaction monitoring (IS-PRM),have demonstrated multiplexed,sensitive detection of pre-defined peptides of interest. Such approaches have not yet been used to confirm existence of novel peptides. Here,we present a targeted proteogenomic approach that leverages sample-matched long-read RNA sequencing (LR RNAseq) data to predict potential protein isoforms with prior transcript evidence. Predicted tryptic isoform-specific peptides,which are specific to individual gene product isoforms,serve as “triggers” and “targets” in the IS-PRM method,Tomahto. Using the model human stem cell line WTC11,LR RNAseq data were generated and used to inform the generation of synthetic standards for 192 isoform-specific peptides (114 isoforms from 55 genes). These synthetic “trigger” peptides were labeled with super heavy tandem mass tags (TMT) and spiked into TMT-labeled WTC11 tryptic digest,predicted to contain corresponding endogenous “target” peptides. Compared to DDA mode,Tomahto increased detectability of isoforms by 3.6-fold,resulting in the identification of five previously unannotated isoforms. Our method detected protein isoform expression for 43 out of 55 genes corresponding to 54 resolved isoforms. This LR RNA seq-informed Tomahto targeted approach,called LRP-IS-PRM,is a new modality for generating protein-level evidence of alternative isoforms – a critical first step in designing functional studies and eventually clinical assays. View Publication

BackgroundTrichloroethylene (TCE) is a ubiquitous pollutant with potential capacity to induce congenital heart disease (CHD). However,the mechanisms underlying TCE-induced CHD are largely unraveled.MethodsWe exposed zebrafish embryos to TCE to investigate its cardiac development toxicity and related response factor through bulk RNA sequencing. We constructed transgenic fluorescent fish and employed the CRISPR/dCas9 system along with single-cell RNA sequencing to identify the genetic cause of TCE-induced CHD.ResultsWe found that early-stage exposure to TCE induced significant cardiac defects characterized by elongated SV-BA distance,thinned myocardium,and attenuated contractility. Gremlin1 encoding gene,grem1a,a putative target showing high expression at the beginning of cardiac development,was sharply down-regulated by TCE. Consistently,grem1a knockdown in zebrafish induced cardiac phenotypes generally like those of the TCE-treated group,accompanying the disarrangement of myofibril structure. Single-cell RNA-seq depicted that mitochondrial respiration in grem1a-repressed cardiomyocytes was greatly enhanced,ultimately leading to a branch from the normal trajectory of myocardial development. Accordingly,in vitro results demonstrated that GREM1 repression increased mitochondrial content,ATP production,mitochondrial reactive oxygen species,mitochondrial membrane potential,and disrupted myofibril expansion in hPSC-CMs.ConclusionsThese results suggested that TCE-induced gremlin1 repression could result in mitochondrial hyperfunction,thereby hampering cardiomyocyte development and causing cardiac defects in zebrafish embryos. This study not only provided a novel insight into the etiology for environmental stressor-caused cardiac development defects,but also offered a potential therapeutic and preventive target for TCE-induced CHD.Supplementary InformationThe online version contains supplementary material available at 10.1186/s12964-025-02314-9. View Publication

AbstractDespite being one of the most prevalent RNA modifications,the role of N6?methyladenosine (m6A) in amyotrophic lateral sclerosis (ALS) remains ambiguous. In this investigation,we explore the contribution of genetic defects of m6A?related genes to ALS pathogenesis. We scrutinized the mutation landscape of m6A genes through a comprehensive analysis of whole?exome sequencing cohorts,encompassing 508 ALS patients and 1660 population?matched controls. Our findings reveal a noteworthy enrichment of RNA binding motif protein X?linked (RBMX) variants among ALS patients,with a significant correlation between pathogenic m6A variants and adverse clinical outcomes. Furthermore,Rbmx knockdown in NSC?34 cells overexpressing mutant TDP43Q331K results in cell death mediated by an augmented p53 response. Similarly,RBMX knockdown in ALS motor neurons derived from induced pluripotent stem cells (iPSCs) manifests morphological defects and activation of the p53 pathway. Transcriptional analysis using publicly available single?cell sequencing data from the primary motor cortex indicates that RBMX?regulated genes selectively influence excitatory neurons and exhibit enrichment in ALS?implicated pathways. Through integrated analyses,our study underscores the emerging roles played by RBMX in ALS,suggesting a potential nexus between the disease and dysregulated m6A?mediated mRNA metabolism. The dysregulation of m6A modification has gained recognition as a crucial factor in the development of amyotrophic lateral sclerosis (ALS). Among the m6A reader proteins,RNA binding motif protein X?linked (RBMX) stands out with a notable enrichment of variants in ALS patients,and the presence of pathogenic RBMX variants is associated with a faster disease progression. In vitro experiments have provided evidence that reducing RBMX levels can result in neuronal defects. Additionally,bioinformatic analyses have supported these findings by revealing that RBMX?associated genes specifically impact excitatory neurons. Furthermore,these genes are involved in the regulation of pathways and genes associated with neurodegeneration and RNA metabolism,underscoring the relevance of RBMX in ALS pathogenesis. View Publication

During gastrulation,the primitive streak (PS) forms and begins to differentiate into mesendodermal subtypes. This process involves an epithelial-mesenchymal transition (EMT),which is marked by cadherin switching,where E-Cadherin is downregulated,and N-Cadherin is upregulated. To understand the relationships between differentiation,EMT,and cadherin switching,we made measurements of these processes during differentiation of human pluripotent stem cells (hPSCs) to PS and subsequently to mesendoderm subtypes using established protocols,as well as variants in which signaling through key pathways including Activin,BMP,and Wnt were modulated. We found that perturbing signaling so that cells acquired identities ranging from anterior to posterior PS had little impact on the subsequent differentiation potential of cells but strongly impacted the degree of cadherin switching. The degree of E-Cadherin downregulation and N-Cadherin upregulation were uncorrelated and had different dependence on signaling. The exception to the broad potential of cells throughout the PS was the loss of definitive endoderm potential in cells with mid to posterior PS identities. Thus,cells induced to different PS coordinates had similar potential within the mesoderm but differed in cadherin switching. Consistently,E-Cadherin knockout did not alter cell fates outcomes during differentiation. Overall,cadherin switching and EMT are modulated independently of cell fate commitment in mesendodermal differentiation. View Publication

To accurately study human organ function and disease ‘in the dish’,it is necessary to develop reliable cell-based models that closely track human physiology. Our interest lay with the liver,which is the largest solid organ in the body. The liver is a multifunctional and highly regenerative organ; however,severe liver damage can have dire consequences for human health. A common cause of liver damage is adverse reactions to prescription drugs. Therefore,the development of predictive liver models that capture human drug metabolism patterns is required to optimise the drug development process. In our study,we aimed to identify compounds that could improve the metabolic function of stem cell-derived liver tissue. Therefore,we screened a compound library to identify additives that improved the maturity of in vitro-engineered human tissue,with the rationale that by taking such an approach,we would be able to fine-tune neonatal and adult cytochrome P450 metabolic function in stem cell-derived liver tissue. View Publication

β-propeller protein-associated neurodegeneration (BPAN) is a rare X-linked neurodegenerative disorder caused by mutations in the WDR45 gene,yet its molecular mechanisms remain poorly understood. Here,we identify a role for WDR45 in stress granule (SG) disassembly,mediated through its phase separation with Caprin-1. We demonstrate that WDR45 forms gel-like condensates via its WD5 domain,which competitively displaces G3BP1 from Caprin-1 to promote SG disassembly. BPAN-associated WDR45 mutations impair condensate formation and Caprin-1 interaction,leading to delayed SG disassembly,which correlates with earlier disease onset. WDR45 depletion also exacerbates amyotrophic lateral sclerosis-associated pathological SGs,highlighting its broader relevance to neurodegenerative diseases. Using iPSC-derived midbrain neurons from a BPAN patient,we demonstrate delayed SG recovery,directly linking WDR45 dysfunction to neurodegeneration. These findings establish WDR45 as a critical regulator of SG dynamics,uncover a potential molecular basis of BPAN pathogenesis,and identify therapeutic targets for neurodegenerative diseases associated with SG dysregulation. BPAN is a rare neurodegenerative disease caused by WDR45 mutations. Here,the authors discover that WDR45 can competitively displace G3BP1 from Caprin-1 to promote stress granule disassembly,a function that is disrupted by BPAN-associated WDR45 mutations. View Publication

Spinal cord injury (SCI) elicits a hostile microenvironment characterized by inflammation,gliosis,and disrupted signaling pathways that collectively impede neural repair. Neural progenitor cells (NPCs) represent a promising regenerative approach,yet their survival and differentiation are often compromised in this setting. Here,we investigated whether engineering NPCs to overexpress the Notch pathway modulator Delta-like non-canonical Notch ligand 1 (DLK1) could overcome these limitations and improve functional outcomes after cervical SCI in rats. NPCs were engineered to express DLK1 under a Pax6 promoter-driven expression system,ensuring elevated DLK1 levels during the progenitor state. Following transplantation of DLK1-overexpressing NPCs or control NPCs,we assessed graft survival,lineage differentiation,behavioral performance,and electrophysiological integration over 12 weeks. DLK1-expressing NPCs exhibited significantly greater retention in the injured spinal cord and showed enhanced neuronal differentiation alongside reduced astrocytic commitment compared to controls. Behavioral tests—including forelimb grip strength and CatWalk gait assessments—demonstrated that DLK1-modified NPCs conferred robust improvements in forelimb motor coordination and overall locomotion. Concordantly,electrophysiological recordings revealed increased motor-evoked potential amplitudes and area-under-the-curve values in animals receiving DLK1-transduced NPC grafts,indicative of strengthened synaptic integration within the host motor circuitry. View Publication