技术资料

Efficient tumor T-cell infiltration is crucial for the effectiveness of T-cell-based therapies against solid tumors. Eosinophils play crucial roles in recruiting T cells in solid tumors. Our group has previously generated induced eosinophils (iEOs) from human pluripotent stem cells and exhibited synergistic efficacy with CAR-T cells in solid tumor inhibition. However,administrated eosinophils might influx into inflammatory lungs,posing a potential safety risk. Mitigating the safety concern and enhancing efficacy is a promising development direction for further application of eosinophils.MethodsWe developed a new approach to generate eosinophils with enhanced potency from human chemically reprogrammed induced pluripotent stem cells (hCiPSCs) with the Toll-like receptor (TLR) 7/8 signaling agonist R848.ResultsR848-activated iEOs (R-iEOs) showed significantly decreased influx to the inflamed lungs,indicating a lower risk of causing airway disorders. Furthermore,these R-iEOs had enhanced anti-tumor functions,preferably accumulated at tumor sites,and further increased T-cell infiltration. The combination of R-iEOs and CAR-T cells suppressed tumor growth in mice. Moreover,the chemo-trafficking signaling increased in R-iEOs,which may contribute to the decreased lung influx of R-iEOs and the increased tumor recruitment of T cells.ConclusionOur study provides a novel approach to alleviate the potential safety concerns associated with eosinophils while increasing T-cell infiltration in solid tumors. This finding offers a prospective strategy for incorporating eosinophils to improve CAR-T-cell immunotherapy for solid tumors in the future. View Publication

Targeted genome editing of human pluripotent stem cells (hPSCs) is critical for basic and translational research and can be achieved with site-specific endonucleases. Cpf1 (CRISPR from Prevotella and Francisella) is a programmable DNA endonuclease with AT-rich PAM sequences. In this protocol,we describe procedures for using a single vector system to deliver Cpf1 and CRISPR RNA (crRNA) for genome editing in hPSCs. This protocol enables indel formation and homologous recombination-mediated precise editing at multiple loci. With the delivery of Cpf1 and a single U6 promoter-driven guide RNA array composed of an AAVS1-targeting and a MAFB-targeting crRNA array,efficient multiplex genome editing at the AAVS1 (knockin) and MAFB (knockout) loci in hPSCs could be achieved in a single experiment. The edited hPSCs expressed pluripotency markers and could differentiate into neurons in vitro. This system also generated INS reporter hPSCs with a 6 kb cassette knockin at the INS locus. The INS reporter cells can differentiate into β-cells that express tdTomato and luciferase,permitting fluorescence-activated cell sorting of hPSC-β-cells. By targeted screening of potential off-target sequences that are most homologous to crRNA sequences,no off-target mutations were detected in any of the tested sequences. This work provides an efficient and flexible system for precise genome editing in mammalian cells including hPSCs with the benefits of less off-target effects. Key features • A single-vector system to deliver Cpf1 and crRNA enables the sorting of transfected cells • Efficient and simultaneous multi-modular genome editing exemplified by mutation of MAFB and knockin of AAVS1 loci in a single experiment • Edited PSCs showed minimal off-target effects and can be differentiated into multiple cell types. View Publication

Human embryonic stem cells (hESCs) serve as a valuable in vitro model for studying early human developmental processes due to their ability to differentiate into all three germ layers. Here,we present a comprehensive multi-omics dataset generated by differentiating hESCs into cardiomyocytes via the mesodermal lineage,collecting samples at 10 distinct time points. We measured mRNA levels by mRNA sequencing (mRNA-seq),translation levels by ribosome profiling (Ribo-seq),and protein levels by quantitative mass spectrometry-based proteomics. Technical validation confirmed high quality and reproducibility across all datasets,with strong correlations between replicates. This extensive dataset provides critical insights into the complex regulatory mechanisms of cardiomyocyte differentiation and serves as a valuable resource for the research community,aiding in the exploration of mammalian development and gene regulation. View Publication

The rare,accelerated aging disease Hutchinson-Gilford Progeria Syndrome (HGPS) is commonly caused by a de novo c.1824 C?>?T point mutation of the LMNA gene that results in the protein progerin. The primary cause of death is a heart attack or stroke arising from atherosclerosis. A characteristic feature of HGPS arteries is loss of smooth muscle cells. An adenine base editor (ABE7.10max) corrected the point mutation and produced significant improvement in HGPS mouse lifespan,vascular smooth muscle cell density,and adventitial fibrosis. To assess whether base editing correction of human HGPS tissue engineered blood vessels (TEBVs) prevents the HGPS vascular phenotype and to identify the minimum fraction of edited smooth muscle cells needed to effect such changes,we transduced HGPS iPSCs with lentivirus containing ABE7.10max. Endothelial cells (viECs) and smooth muscle cells (viSMCs) obtained by differentiation of edited HGPS iPSCs did not express progerin and had double-stranded DNA breaks and reactive oxygen species at the same levels as healthy viSMCs and viECs. Editing HGPSviECs restored a normal response to shear stress. Normal vasodilation and viSMC density were restored in TEBVs made with edited cells. When TEBVs were prepared with at least 50% edited smooth muscle cells,viSMC proliferation and myosin heavy chain levels significantly improved. Sequencing of TEBV cells after perfusion indicated an enrichment of edited cells after 5?weeks of perfusion when they comprised 50% of the initial number of cells in the TEBVs. Thus,base editing correction of a fraction of HGPS vascular cells improves human TEBV phenotype. View Publication

Introduction: The lack of functional hepatocytes poses a significant challenge for drug safety testing and therapeutic applications due to the inability of mature hepatocytes to expand and their tendency to lose functionality in vitro. Previous studies have demonstrated the potential of Human Liver Stem Cells (HLSCs) to differentiate into hepatocyte-like cells within an in vitro rotary cell culture system,guided by a combination of growth factors and molecules known to regulate hepatocyte maturation. In this study,we employed a matrix multi-assay approach to comprehensively characterize HLSC differentiation. Methods: We evaluated the expression of hepatic markers using qRT-PCR,immunofluorescence,and Western blot analysis. Additionally,we measured urea and FVIII secretion into the supernatant and developed an updated indocyanine green in vitro assay to assess hepatocyte functionality. Results: Molecular analyses of differentiated HLSC aggregates revealed significant upregulation of hepatic genes,including CYP450,urea cycle enzymes,and uptake transporters exclusively expressed on the sinusoidal side of mature hepatocytes,evident as early as 1 day post-differentiation. Interestingly,HLSCs transiently upregulated stem cell markers during differentiation,followed by downregulation after 7 days. Furthermore,differentiated aggregates demonstrated the ability to release urea and FVIII into the supernatant as early as the first 24 h,with accumulation over time. Discussion: These findings suggest that a 3D rotation culture system may facilitate rapid hepatic differentiation of HLSCs. Despite the limitations of this rotary culture system,its unique advantages hold promise for characterizing HLSC GMP batches for clinical applications. View Publication

ABSTRACTThe ultimate aim of nuclear reprogramming is to provide stem cells or differentiated cells from unrelated cell types as a cell source for regenerative medicine. A popular route towards this is transcription factor induction,and an alternative way is an original procedure of transplanting a single somatic cell nucleus to an unfertilized egg. A third route is to transplant hundreds of cell nuclei into the germinal vesicle (GV) of a non-dividing Amphibian meiotic oocyte,which leads to the activation of silent genes in 24 h and robustly induces a totipotency-like state in almost all transplanted cells. We apply this third route for potential therapeutic use and describe a procedure by which the differentiated states of cells can be reversed so that totipotency and pluripotency gene expression are regained. Differentiated cells are exposed to GV extracts and are reprogrammed to form embryoid bodies,which shows the maintenance of stemness and could be induced to follow new directions of differentiation. We conclude that much of the reprogramming effect of eggs is already present in meiotic oocytes and does not require cell division or selection of dividing cells. Reprogrammed cells by oocytes could serve as replacements for defective adult cells in humans. Summary: Stem cell therapy has shed light on incurable diseases. We describe a novel method for cell reprogramming and provide personalized stem cell sources for stem cell therapies. View Publication

Mohr-Tranebjaerg syndrome (MTS) is a rare X-linked recessive neurodegenerative disorder caused by mutations in the Translocase of Inner Mitochondrial Membrane 8A (TIMM8A) gene,which encodes TIMM8a,a protein localized to the mitochondrial intermembrane space (IMS). The pathophysiology of MTS remains poorly understood. To investigate the molecular mechanisms underlying MTS,we established induced pluripotent stem cells (iPSCs) from a male MTS patient carrying a novel TIMM8A mutation (c.225-229del,p.Q75fs95*),referred to as MTS-iPSCs. To generate an isogenic control,we introduced the same mutation into healthy control iPSCs (CTRL-iPSCs) using the Clustered Regularly Interspaced Short Palindromic Repeats/CRISPR-associated protein 9 (CRISPR/Cas9),resulting in mutant iPSCs (MUT-iPSCs). We differentiated the three iPSC lines into neurons and evaluated their mitochondrial function and neuronal development. Both MTS- and MUT-iPSCs exhibited impaired neuronal differentiation,characterized by smaller somata,fewer branches,and shorter neurites in iPSC-derived neurons. Additionally,these neurons showed increased susceptibility to apoptosis under stress conditions,as indicated by elevated levels of cytochrome c and cleaved caspase-3. Mitochondrial function analysis revealed reduced protein levels and activity of complex IV,diminished ATP synthesis,and increased reactive oxygen species (ROS) generation in MTS- and MUT-neurons. Furthermore,transmission electron microscopy revealed mitochondrial fragmentation in MTS-neurons. RNA sequencing identified differentially expressed genes (DEGs) involved in axonogenesis,synaptic activity,and apoptosis-related pathways. Among these DEGs,coiled-coil-helix-coiled-coil-helix domain-containing 2 (CHCHD2),which encodes a mitochondrial IMS protein essential for mitochondrial homeostasis,was significantly downregulated in MTS-neurons. Western blot analysis confirmed decreased CHCHD2 protein levels in both MTS- and MUT-neurons. Overexpression of CHCHD2 rescued mitochondrial dysfunction and promoted neurite elongation in MTS-neurons,suggesting that CHCHD2 acts as a downstream effector of TIMM8a in the pathogenesis of MTS. In summary,loss-of-function of TIMM8a leads to a downstream reduction in CHCHD2 levels,collectively impairing neurogenesis by disrupting mitochondrial homeostasis. TIMM8a mutation (p.Q75fs95*) leads to mitochondrial dysfunction and neuronal defects in iPSC-derived neurons from patient with Mohr-Tranebjaerg syndrome,which are rescued by overexpression of CHCHD2. TIMM8a translocase of inner mitochondrial membrane 8a,CHCHD2 coiled-coil-helix-coiled-coil-helix domain-containing protein 2,MTS Mohr-Tranebjaerg syndrome,I mitochondrial complex I,II mitochondrial complex II,III mitochondrial complex III,IV mitochondrial complex IV,Q coenzyme Q10,Cyt c cytochrome c. View Publication

Stem cell fate decisions,including proliferation,differentiation,morphological changes,and viability,are impacted by microenvironmental cues such as physical and biochemical signals. However,the specific impact of matrix elasticity on kidney cell development and function remains less understood due to the lack of models that can closely recapitulate human kidney biology. An established protocol to differentiate podocytes from human-induced pluripotent stem (iPS) cells provides a promising avenue to elucidate the role of matrix elasticity in kidney tissue development and lineage determination. In this study,we synthesized polyacrylamide hydrogels with different stiffnesses and investigated their ability to promote podocyte differentiation and biomolecular characteristics. We found that 3 kPa and 10 kPa hydrogels significantly support the adhesion,differentiation,and viability of podocytes. Differentiating podocytes on a more compliant (0.7 kPa) hydrogel resulted in significant cell loss and detachment. Further investigation of the mechanosensitive proteins yes-associated protein (YAP) and synaptopodin revealed nuanced molecular distinctions in cellular responses to matrix elasticity that may otherwise be overlooked if morphology and cell spreading alone were used as the primary metric for selecting matrices for podocyte differentiation. Specifically,hydrogels with kidney-like rigidities outperformed traditional tissue culture plates at modulating the molecular-level expression of active mechanosensitive proteins critical for podocyte health and function. These findings could guide the development of physiologically relevant platforms for kidney tissue engineering,disease modeling,and mechanistic studies of organ physiology and pathophysiology. Such advances are critical for realizing the full potential of in vitro platforms in accurately predicting human biological responses. View Publication

DNA methylation regulation involves multi-layered chromatin interactions that require remodeling proteins like the helicase,lymphoid-specific (HELLS). Here,we generate HELLS and DNA methyltransferase 3A and B (DNMT3A/B) knockout human pluripotent stem cells and report telomere-to-telomere maps of whole genome bisulfite sequencing data combined with ATAC-sequencing. Disrupting HELLS induces a global loss of DNA methylation that is distinct from the DNMTs,in particular over peri/centromeric satellite repeats as defined in the telomere-to-telomere genome assembly. However,HELLS appears dispensable for local enhancer remodeling and the potential to differentiate into the three embryonic germ layers. Taken together,our results further clarify the genomic targets and role of HELLS in human cells.Supplementary InformationThe online version contains supplementary material available at 10.1186/s13059-025-03681-9. View Publication

Personalized antisense oligonucleotides (ASOs) have achieved positive results in the treatment of rare genetic disease1. As clinical sequencing technologies continue to advance,the ability to identify patients with rare disease harbouring pathogenic genetic variants amenable to this therapeutic strategy will probably improve. Here we describe a scalable platform for generating patient-derived cellular models and demonstrate that these personalized models can be used for preclinical evaluation of patient-specific ASOs. We describe protocols for delivery of ASOs to patient-derived organoid models and confirm reversal of disease-associated phenotypes in cardiac organoids derived from a patient with Duchenne muscular dystrophy (DMD) with a structural deletion in the gene encoding dystrophin (DMD) that is amenable to treatment with existing ASO therapeutics. Furthermore,we designed novel patient-specific ASOs for two additional patients with DMD (siblings) with a deep intronic variant in the DMD gene that gives rise to a novel splice acceptor site,incorporation of a cryptic exon and premature transcript termination. We showed that treatment of patient-derived cardiac organoids with patient-specific ASOs results in restoration of DMD expression and reversal of disease-associated phenotypes. The approach outlined here provides the foundation for an expedited path towards the design and preclinical evaluation of personalized ASO therapeutics for a broad range of rare diseases. A scalable platform for generating patient-specific organoids for testing personalized oligonucleotide therapeutics is described. View Publication

SummaryKCNQ1/Kv7,a low-voltage-gated K+ channel,regulates cardiac rhythm and glucose homeostasis. While KCNQ1 mutations are associated with long-QT syndrome and type2 diabetes,its function in human pancreatic cells remains controversial. We identified a homozygous KCNQ1 mutation (R397W) in an individual with permanent neonatal diabetes melitus (PNDM) without cardiovascular symptoms. To decipher the potential mechanism(s),we introduced the mutation into human embryonic stem cells and generated islet-like organoids (SC-islets) using CRISPR-mediated homology-repair. The mutation did not affect pancreatic differentiation,but affected channel function by increasing spike frequency and Ca2+ flux,leading to insulin hypersecretion. With prolonged culturing,the mutant islets decreased their secretion and gradually deteriorated,modeling a diabetic state,which accelerated by high glucose levels. The molecular basis was the downregulated expression of voltage-activated Ca2+ channels and oxidative phosphorylation. Our study provides a better understanding of the role of KCNQ1 in regulating insulin secretion and ?-cell survival in hereditary diabetes pathology. Graphical abstract Highlights•A permanent neonatal diabetes melitus patient carries a homozygous KCNQ1 mutation•KCNQ1R397W is loss of function and shows atypical electrophysiology in hESC-islets•Under high glucose,elevated Ca2+ flux leads to insulin hypersecretion•Mutant cells gradually switch phenotype,deteriorate,accelerated by high glucose Biological sciences; Endocrinology; Endocrinology; Health sciences; Internal medicine; Medical specialty; Medicine; Natural sciences; Physiology View Publication

Quantification of subcellular structures such as nuclei and cytoplasmic proteins using staining methods based on fluorescent dyes or fluorescently tagged antibodies are widely used in scientific research. Accurate high-throughput quantitation of these assays can be time consuming and challenging. Here,we present our FIJI based Semi-Automated counting Macro termed SAM,and we validate its accuracy against manual counting and other automated counting methods. By introducing this automated quantification tool,we aim to contribute to the ongoing efforts to enhance the reliability,efficiency,and standardization of immunostaining analysis in the field of diabetes research and beyond.Supplementary InformationThe online version contains supplementary material available at 10.1038/s41598-025-12144-x. View Publication