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Transplantation of human-induced pluripotent stem cell (hiPSC)-derived islet organoids is a promising cell replacement therapy for type 1 diabetes (T1D). It is important to improve the efficacy of islet organoids transplantation by identifying new transplantation sites with high vascularization and sufficient accommodation to support graft survival with a high capacity for oxygen delivery. A human-induced pluripotent stem cell line (hiPSCs-L1) was generated constitutively expressing luciferase. Luciferase-expressing hiPSCs were differentiated into islet organoids. The islet organoids were transplanted into the scapular brown adipose tissue (BAT) of nonobese diabetic/severe combined immunodeficiency disease (NOD/SCID) mice as the BAT group and under the left kidney capsule (KC) of NOD/SCID mice as a control group,respectively. Bioluminescence imaging (BLI) of the organoid grafts was performed on days 1,7,14,28,35,42,49,56,and 63 posttransplantation. BLI signals were detected in all recipients,including both the BAT and control groups. The BLI signal gradually decreased in both BAT and KC groups. However,the graft BLI signal intensity under the left KC decreased substantially faster than that of the BAT. Furthermore,our data show that islet organoids transplanted into streptozotocin-induced diabetic mice restored normoglycemia. Positron emission tomography/MRI verified that the islet organoids were transplanted at the intended location in these diabetic mice. Immunofluorescence staining revealed the presence of functional organoid grafts,as confirmed by insulin and glucagon staining. Our results demonstrate that BAT is a potentially desirable site for islet organoid transplantation for T1D therapy. View Publication

There has been a recent drive to replace in vivo studies with in vitro studies in the field of toxicity testing. Therefore,instead of conventional animal or planar cell culture models,there is an urgent need for in vitro systems whose conditions can be strictly controlled,including cell–cell interactions and sensitivity to low doses of chemicals. Neural organoids generated from human-induced pluripotent stem cells (iPSCs) are a promising in vitro platform for modeling human brain development. In this study,we developed a new tool based on various iPSCs to study and predict chemical-induced toxicity in humans. The model displayed several neurodevelopmental features and showed good reproducibility,comparable to that of previously published models. The results revealed that basic fibroblast growth factor plays a key role in the formation of the embryoid body,as well as complex neural networks and higher-order structures such as layered stacking. Using organoid models,pesticide toxicities were assessed. Cells treated with low concentrations of rotenone underwent apoptosis to a greater extent than those treated with high concentrations of rotenone. Morphological changes associated with the development of neural progenitor cells were observed after exposure to low doses of chlorpyrifos. These findings suggest that the neuronal organoids developed in this study mimic the developmental processes occurring in the brain and nerves and are a useful tool for evaluating drug efficacy,safety,and toxicity. View Publication

Adenomyosis is also called internal endometriosis and affects about 20{\%} of reproductive-aged women. It seriously reduces life quality of patients because current drug therapies face with numerous challenges. Long-term clinical application of mifepristone exhibits wonderful therapeutic effects with mild side-effects in many disorders since 1982. Since adenomyosis is a refractory disease,we investigate whether mifepristone can be applied in the treatment of adenomyosis. In this study,we investigated the direct effects of mifepristone on human primary eutopic endometrial epithelial cells and stromal cells in adenomyosis. We found that mifepristone causes cell cycle arrest through inhibiting CDK1 and CDK2 expressions and induces cell apoptosis via the mitochondria-dependent signalling pathway in endometrial epithelial cells and stromal cells of adenomyosis. Furthermore,mifepristone inhibits the migration of endometrial epithelial cells and stromal cells through decreasing CXCR4 expression and restricts the invasion of endometrial epithelial cells via suppression of epithelial-mesenchymal transition in adenomyosis. We also found that mifepristone treatment decreases the uterine volume,CA125 concentration and increases the haemoglobin concentration in serum for adenomyosis patients. Therefore,we demonstrate that mifepristone could serve as a novel therapeutic drug in the treatment of adenomyosis,and therefore,the old dog can do a new trick. View Publication

To characterize mechanisms of CTL inhibition within an ocular tumor microenvironment,tumor-specific CTLs were transferred into mice with tumors developing within the anterior chamber of the eye or skin. Ocular tumors were resistant to CTL transfer therapy whereas skin tumors were sensitive. CTLs infiltrated ocular tumors at higher CTL/tumor ratios than in skin tumors and demonstrated comparable ex vivo effector function to CTLs within skin tumors indicating that ocular tumor progression was not due to decreased CTL accumulation or inhibited CTL function within the eye. CD11b(+)Gr-1(+)F4/80(-) cells predominated within ocular tumors,whereas skin tumors were primarily infiltrated by CD11b(+)Gr-1(-)F4/80(+) macrophages (Ms),suggesting that myeloid derived suppressor cells may contribute to ocular tumor growth. However,CD11b(+) myeloid cells isolated from either tumor site suppressed CTL activity in vitro via NO production. Paradoxically,the regression of skin tumors by CTL transfer therapy required NO production by intratumoral Ms indicating that NO-producing intratumoral myeloid cells did not suppress the effector phase of CTL. Upon CTL transfer,tumoricidal concentrations of NO were only produced by skin tumor-associated Ms though ocular tumor-associated Ms demonstrated comparable expression of inducible NO synthase protein suggesting that NO synthase enzymatic activity was compromised within the eye. Correspondingly,in vitro-activated Ms limited tumor growth when co-injected with tumor cells in the skin but not in the eye. In conclusion,the decreased capacity of Ms to produce NO within the ocular microenvironment limits CTL tumoricidal activity allowing ocular tumors to progress. View Publication

BACKGROUND Adoptive T-cell transfer has become an attractive therapeutic approach for hematological malignancies but shows poor activity against large and heterogeneous solid tumors. Interleukin-12 (IL-12) exhibits potent antitumor efficacy against solid tumors,but its clinical application has been stalled because of toxicity. Here,we aimed to develop a safe approach to IL-12 T-cell therapy for eliminating large solid tumors. METHODS We generated a cell membrane-anchored IL-12 (aIL12),a tumor-targeted IL-12 (ttIL12),and a cell membrane-anchored and ttIL-12 (attIL12) and a cell membrane-anchored and tumor-targeted ttIL-12 (attIL12) armed T cells,chimeric antigen receptor-T cells,and T cell receptor-T (TCR-T) cells with each. We compared the safety and efficacy of these armed T cells in treating osteosarcoma patient-derived xenograft tumors and mouse melanoma tumors after intravenous infusions of the armed T cells. RESULTS attIL12-T cell infusion showed remarkable antitumor efficacy in human and mouse large solid tumor models. Mechanistically,attIL12-T cells targeted tumor cells expressing cell-surface vimentin,enriching effector T cell and interferon $\gamma$ production in tumors,which in turn stimulates dendritic cell maturation for activating secondary T-cell responses and tumor antigen spreading. Both attIL12- and aIL12-T-cell transfer eliminated peripheral cytokine release and the associated toxic effects. CONCLUSIONS This novel approach sheds light on the safe application of IL-12-based T-cell therapy for large and heterogeneous solid tumors. View Publication

Highlights•Preformation of aggregates tuned by cell density enable cultivation of hiPSCs in scale-down shear environments.•Scale-down systems utilizing preformation protocols achieve comparable fold expansion with commercial systems.•Expression of pluripotency markers and functional differentiation capacity is maintained following passage in scale-down culture.•Successful application of hiPSC protocols at < 20 mL scales enable rapid and cost-effective research into cell phenotype under dynamic conditions. Human induced pluripotent stem cell (hiPSC) derived therapeutics require clinically relevant quantities of high-quality cell populations for applications in regenerative medicine. The lack of efficacy exhibited across clinical trials suggests deeper understanding of the networks governing phenotype is needed. Further,costs limit study throughput in characterizing the artificial niche relative to outcomes. We present herein an optimized strategy to enable high-throughput hiPSC expansion at <20 mL research scale. We assessed viability of single cell inoculation and aggregate preformation to facilitate proliferation. We modeled aggregate characteristics against agitation rate. Our results demonstrate tunable control with fold expansion comparable to commercial systems. Marker quantification and teratoma assay confirm functional pluripotency. This approach constitutes a scalable protocol to accelerate hiPSC research,and a significant step in advancing the rate of progress in elucidating links to derivative functionality. This work will enable statistically rigorous studies targeting hiPSC and downstream phenotype for clinical manufacturing. Graphical abstractImplementation of adapted protocols enable scale-down systems as a tool for high-throughput iPSC biomanufacturing research,in platforms conducive to scale-up for clinical manufacturing.Image,graphical abstract View Publication

Small non‐coding microRNAs (miRNAs) play essential roles in Alzheimer's disease (AD) pathogenesis. Repressor element 1‐silencing transcription factor (REST) is involved in AD,though its regulation remains unclear. We performed real‐time quantitative polymerase chain reaction (qPCR) in autopsied brain tissues to determine miR‐153‐3p and AD associations. A reporter‐based assay measured the activity of REST mRNA 3′‐untranslated region (3′‐UTR). Induced pluripotent stem cells (iPSC)‐derived neurons and human cell lines were applied to determine miR‐153‐3p regulation of endogenous proteins. Elevation of miR‐153‐3p is associated with a reduced probability of AD,while elevated REST is associated with a greater probability of AD. The 3′‐UTR functional assay pinpointed the miR‐153‐3p binding sites. miR‐153‐3p treatment reduced REST,amyloid precursor protein (APP),and α‐synuclein (SNCA) 3′‐UTR activities and protein levels. miR‐153‐3p treatment altered REST and neuronal differentiation in iPSC‐derived neuronal stem cells. RNA‐sequencing and proteomics revealed miR‐153‐3p‐associated networks. miR‐153‐3p reduces REST,APP,and SNCA expression,pointing toward its therapeutic and biomarker potential in neurodegenerative diseases. With the increased emphasis on comorbidities of Alzheimer's disease (AD) and other neurodegenerative diseases,we identified that miR‐153‐3p,as a master regulator,reduced a group of neurodegeneration related proteins: REST,amyloid precursor protein (APP) and α‐synuclein (SNCA) levels. The elevation of miR‐153‐3p levels is associated with reduced probability of AD in posterior cingulate cortex (PCC),while REST,by contrast,is associated with a greater probability of AD. miR‐153‐3p treatment alters REST protein levels and neuronal differentiation in induced pluripotent stem cells (iPSC) derived neuronal cells. RNA sequencing proteomics and interactome analysis revealed the role of miR‐153‐3p in axonal guidance. View Publication

5-Ethynyl-2′-deoxyuridine (EdU) has revolutionized DNA replication and cell cycle analyses through fast,efficient click chemistry detection. However,commercial EdU kits suffer from high costs,proprietary formulations,limited antibody multiplexing capabilities,and difficulties with larger biological specimens. Here,we present OpenEMMU (Open-source EdU Multiplexing Methodology for Understanding DNA replication dynamics),an optimized,affordable,and user-friendly click chemistry platform utilizing off-the-shelf reagents. OpenEMMU enhances efficiency,brightness,and multiplexing capabilities of EdU staining with both non-conjugated and conjugated antibodies across diverse cell types,including T cell activation and proliferation assays. We validated its effectiveness for the fluorescent imaging of nascent DNA synthesis in developing embryos and organs,including embryonic heart,forelimbs,and 3D hiPSC-derived cardiac organoids. OpenEMMU also enabled the deep-tissue 3D imaging of DNA synthesis in zebrafish larvae and under replication stress in embryos at high spatial resolution. This approach opens new avenues for understanding organismal development,cell proliferation,and DNA replication dynamics with unprecedented precision and flexibility. Subject areas: Biochemistry,Cell biology,Developmental biology,Computational bioinformatics View Publication

Ovarian cancer (OV) has the highest mortality rate among gynecological cancers. As OV progresses,tumor cells spread outside the ovaries to the peritoneal and abdominal cavities,forming cell clusters that float in the ascitic fluid caused by peritonitis carcinomatosa,leading to further dissemination and metastasis. These cell clusters are enriched with cancer stem cells (CSCs) which are responsible for treatment resistance,recurrence,and metastasis. Therefore,targeting CSCs is a potentially effective approach for treating OV. However,understanding how CSCs acquire treatment resistance and identifying targets against CSCs remains challenging. In this study,we demonstrate that 3D-spheroids of OV cell lines exhibit higher stemness than conventional adherent cells. Metabolomics profiling studies have revealed that 3D-spheroids maintain a high-energy state through increased glucose utilization in the citric acid cycle (TCA),efficient nucleotide phosphorylation,and elevated phosphocreatine as an energy buffer. We also found that nicotinamide phosphoribosyltransferase (NAMPT),the rate-limiting enzyme for NAD + production,is highly expressed in OV. Furthermore,the approach based on NAMPT dependence rather than histology found NAMPT to be a potential therapeutic target against CSCs,while also serving as a prognostic indicator in OV. Moreover,we identified a previously unrecognized anti-tumor mechanism whereby disulfiram,an aldehyde dehydrogenase (ALDH) inhibitor,synergistically inhibited mitochondrial function when combined with NAMPT inhibitors - leading to cell cycle arrest in G2/M. Finally,the combination of a NAMPT inhibitor and disulfiram showed significant anti-tumor effects and extended survival in an animal model. Our findings demonstrate the potential of spheroids as a preclinical model for targeting OV CSCs and also indicate that the combination of NAMPT inhibitors and disulfiram is a promising therapeutic strategy to overcome recurrent OV. Subject terms: Ovarian cancer,Metabolomics,Apoptosis,Cancer stem cells View Publication

Three-dimensional (3D) human brain tissue models derived from induced pluripotent stem cells (iPSCs) have transformed the study of neural development and disease in vitro. While cerebral organoids offer high structural complexity,their large size often leads to necrotic core formation,limiting reproducibility and challenging the integration of microglia. Here,we present a detailed,reproducible protocol for generating multi-cell type 3D neurospheres that incorporate neurons,astrocytes,and optionally microglia,all derived from the same iPSCs. While neurons and astrocytes differentiate spontaneously from neural precursor cells,generated by dual SMAD-inhibition (blocking BMP and TGF-b signaling),microglia are generated in parallel and can infiltrate the mature neurosphere tissue after plating neurospheres into 48-well plates. The system supports a range of downstream applications,including functional confocal live imaging of GCaMP6f after adeno-associated virus (AAV) transduction of neurospheres or immunofluorescence staining after fixation. Our approach has been successfully implemented across multiple laboratories,demonstrating its robustness and translational potential for studying neuron–glia interactions and modeling neurodegenerative processes. View Publication