技术资料

This study focuses on improving the identification of chicken primordial germ cells (PGCs),which are vital for genetic transmission and biotechnological applications. Traditional markers like SSEA1 and CVH have limitations—SSEA1 lacks specificity,and CVH is intracellular. A monoclonal antibody was generated by injecting chicken PGCs into mice,producing one that specifically binds to PGCs and decreases with cell differentiation. Mass spectrometry identified its target as the MYH9 protein. The resulting αMYH9 antibody effectively labels PGCs at various developmental stages,offering a valuable tool for isolating viable PGCs and advancing avian genetics,agriculture,and biotechnology. View Publication

Colorectal cancer (CRC) is a prevalent malignant tumor globally,ranking third in incidence and second in mortality. Metastasis is the main cause of death in patients with CRC. Solanum nigrum L. (SNL),a traditional Chinese medicinal herb endowed with detoxification,blood circulation enhancement,and anti-swelling properties,has been widely used in folk prescriptions for cancer treatment in China. Solamargine (SM) is the major steroidal alkaloid glycoside purified from SNL. However,its role and mechanism against metastatic CRC are not yet clear. The purpose of this study was to evaluate the inhibitory effect of SM on human hepatic metastatic CRC and investigate its underlying mechanism. CCK-8 assay,colony-formation assay,transwell assay,flow cytometry,tumoursphere formation assay,reverse-transcription quantitative PCR (RT-qPCR),Western blotting,transcriptomic sequencing and ferroptosis analysis were performed to reveal the efficacy and the underlying mechanism of SM in CRC cell lines. In vivo,allograft model,patient-derived xenograft (PDX) model,and liver metastatic model were performed to verify the effect of SM on the growth and metastasis of CRC. SM was found to suppress hepatic metastasis in CRC by effectively targeting key cellular processes,including proliferation,survival,and stemness. RNA sequencing showed that SM could induce ferroptosis,which was confirmed by elevated lipid reactive oxygen species (ROS) and downregulated glutathione peroxidase 4 (GPX4) and glutathione synthetase (GSS) in CRC cells and xenografts. Induction of ferroptosis by SM was regulated by nuclear factor erythroid 2-related factor 2 (Nrf2). Furthermore,downregulation of β-catenin was found to be fundamental for the SM-enabled cancer stem cells (CSCs) elimination and metastasis blockage in CRC. Our results indicated that SM is a promising therapeutic drug to inhibit hepatic metastasis in CRC by inducing ferroptosis and impeding CSCs. The online version contains supplementary material available at 10.1186/s13020-025-01171-5. View Publication

Cell therapy is promising for heart failure treatment,with growing interest in cardiovascular progenitor cells (CPCs) from pluripotent stem cells. A major challenge is managing the immune response,due to their allogeneic source. Regulatory T cells (Treg) offer an alternative to pharmacological immunosuppression by inducing immune tolerance. This study assesses whether Treg therapy can mitigate the xeno-immune response,improving cardiac outcomes in a mouse model of human CPC intramyocardial transplantation. CPCs stimulated immune responses in allogeneic and xenogeneic settings,causing proliferation in T cell subsets. Tregs showed immunosuppressive effects on T lymphocyte populations when co-cultured with CPCs. Post infarction,CPCs were transplanted intramyocardially into an immune-competent mouse model 3 weeks after myocardial infarction. Human or murine Tregs were intravenously administered on transplantation day and three days later. Control groups received CPCs without Tregs or saline (PBS). CPCs with Tregs improved LV systolic function in three weeks,linked to reduced myocardial fibrosis and enhanced angiogenesis. This was accompanied by decreased splenocyte NK cell populations and pro-inflammatory cytokine levels in cardiac tissue. Treg therapy with CPC transplantation enhances cardiac functional and structural outcomes in mice. Though it does not directly avert graft rejection,it primarily affects NKG2D+ cytotoxic cells,indicating systemic immune modulation and remote heart repair benefits. View Publication

The growth factor and small molecule protocol are the two primary approaches for generating human induced pluripotent stem cell-derived hepatocyte-like cells (iPSC-HLCs). We compared the efficacy of the growth factor and small molecule protocols across fifteen different human iPSC lines. Morphological assessment,relative quantification of gene expression,protein expression and proteomic studies were carried out. HLCs derived from the growth factor protocol displayed mature hepatocyte morphological features including a raised,polygonal shape with well-defined refractile borders,granular cytoplasm with lipid droplets and/or vacuoles with multiple spherical nuclei or a large centrally located nucleus; significantly elevated hepatocyte gene and protein expression including AFP,HNF4A,ALBUMIN,and proteomic and metabolic features that are more aligned with a mature phenotype. HLCs derived from the small molecule protocol showed a dedifferentiated,proliferative phenotype that is more akin to liver tumor-derived cell lines. These experimental results suggest that HLCs derived from growth factors are better suited for studies of metabolism,biotransformation,and viral infection. View Publication

In search for broad-spectrum antivirals,we discover a small molecule inhibitor,RMC-113,that potently suppresses the replication of multiple RNA viruses including SARS-CoV-2 in human lung organoids. We demonstrate selective inhibition of the lipid kinases PIP4K2C and PIKfyve by RMC-113 and target engagement by its clickable analog. Lipidomics analysis reveals alteration of SARS-CoV-2-induced phosphoinositide signature by RMC-113 and links its antiviral effect with functional PIP4K2C and PIKfyve inhibition. We identify PIP4K2C’s roles in SARS-CoV-2 entry,RNA replication,and assembly/egress,validating it as a druggable antiviral target. Integrating proteomics,single-cell transcriptomics,and functional assays,reveals that PIP4K2C binds SARS-CoV-2 nonstructural protein 6 and regulates virus-induced autophagic flux impairment. Promoting viral protein degradation by reversing autophagic flux impairment is a mechanism of antiviral action of RMC-113. These findings reveal virus-induced autophagy regulation via PIP4K2C,an understudied kinase,and propose dual PIP4K2C and PIKfyve inhibition as a candidate strategy to combat emerging viruses. Subject terms: SARS-CoV-2,Target identification,Autophagy View Publication

Huntington’s disease (HD) is a neurodegenerative disorder caused by the expansion of CAG repeats in the HTT gene,which results in a long polyglutamine tract in the huntingtin protein (HTT). One of the earliest key molecular mechanisms underlying HD pathogenesis is transcriptional dysregulation,which is already present in the developing brain. In this study,we searched for networks of deregulated RNAs crucial for initial transcriptional changes in HD- and HTT-deficient neuronal cells. RNA-seq (including small RNAs) was used to analyze a set of isogenic human neural stem cells. The results were validated using additional methods,rescue experiments,and in the medium spiny neuron-like cells. We observed numerous changes in gene expression and substantial dysregulation of miRNA expression in HD and HTT -knockout ( HTT -KO) cell lines. The overlapping set of genes upregulated in both HD and HTT -KO cells was enriched in genes associated with DNA binding and the regulation of transcription. We observed substantial upregulation of the following transcription factors: TWIST1,SIX1,TBX1,TBX15,MSX2,MEOX2 and FOXD1 . Moreover,we identified miRNAs that were consistently deregulated in HD and HTT -KO cells,including miR-214,miR-199,and miR-9. These miRNAs may function in the network that regulates TWIST1 and HTT expression via a regulatory feed-forward loop in HD. On the basis of overlapping changes in the mRNA and miRNA profiles of HD and HTT -KO cell lines,we propose that transcriptional deregulation in HD at early neuronal stages is largely caused by a deficiency of properly functioning HTT rather than a typical gain-of-function mechanism. The online version contains supplementary material available at 10.1186/s13578-025-01443-5. View Publication

Genome‐wide association studies have implicated complement in Alzheimer's disease (AD). The CR1*2 variant of complement receptor 1 (CR1; CD35),confers increased AD risk. We confirmed CR1 expression on glial cells; however,how CR1 variants influence AD risk remains unclear. Induced pluripotent stem cell‐derived microglia and astrocytes were generated from donors homozygous for the common CR1 variants (CR1*1/CR1*1;CR1*2/CR1*2). CR1 expression was quantified and phagocytic activity assessed using diverse targets ( Escherichia coli bioparticles,amyloid β aggregates,and synaptoneurosomes),with or without serum opsonization. Expression of CR1*1 was significantly higher than CR1*2 on glial lines. Phagocytosis for all targets was markedly enhanced following serum opsonization,attenuated by Factor I‐depletion,demonstrating CR1 requirement for C3b processing. CR1*2‐expressing glia showed significantly enhanced phagocytosis of all opsonized targets compared to CR1*1‐expressing cells. CR1 is critical for glial phagocytosis of opsonized targets. CR1*2,despite lower expression,enhances glial phagocytosis,providing mechanistic explanation of increased AD risk. Induced pluripotent stem cell (iPSC)‐derived glia from individuals expressing the Alzheimer's disease (AD) risk variant complement receptor (CR) 1*2 exhibit lower CR1 expression compared to those from donors expressing the non‐risk form CR1*1. The iPSC‐derived glia from individuals expressing the AD risk variant CR1*2 exhibit enhanced phagocytic activity for opsonized bacterial particles,amyloid‐β aggregates and human synaptoneurosomes compared to those from donors expressing the non‐risk form CR1*1. We suggest that expression of the CR1*2 variant confers risk of AD by enhancing the phagocytic capacity of glia for opsonized targets. View Publication

Immunosenescence describes the gradual remodeling of immune responses,leading to disturbed immune homeostasis and increased susceptibility of older adults for infections,neoplasia and autoimmunity. Decline in cellular immunity is associated with intrinsic changes in the T cell compartment,but can be further pushed by age-related changes in cells regulating T cell immunity. Myeloid-derived suppressor cells (MDSCs) are potent inhibitors of T cell activation and function,whose induction requires chronic inflammation. Since aging is associated with low grade inflammation (inflammaging) and increased myelopoiesis,age-induced changes in MDSC induction and function in relation to T cell immunity were analyzed. MDSC numbers and functions were compared between “healthy” young and old adults,who were negatively diagnosed for severe acute and chronic diseases known to induce MDSC accumulation. MDSCs were either isolated from peripheral blood or generated in vitro from blood-derived CD14 cells. Aging was associated with significantly increased MDSC numbers in the monocytic- (M-) and polymorphonuclear (PMN-) MDSC subpopulations. MDSCs could be induced more efficiently from CD14 cells of old donors and these MDSCs inhibited CD3/28-induced T cell proliferation significantly better than MDSCs induced from young donors. Serum factors of old donors supported MDSC induction comparable to serum factors from young donors,but increased immunosuppressive activity of MDSCs was only achieved by serum from old donors. Elevated immunosuppressive activity of MDSCs from old donors was associated with major metabolic changes and increased intracellular levels of neutral and oxidized lipids known to promote immunosuppressive functions. Independent of age,MDSC-mediated suppression of T cell proliferation required direct MDSC– T cell contact. Besides their increased ability to inhibit activation-induced T cell proliferation,MDSCs from old donors strongly shift the immune response towards Th2 immunity and might thereby further contribute to impaired cell-mediated immunity during aging. These results indicate that immunosenescence of innate immunity comprises accumulation and functional changes in the MDSC compartment,which directly impacts T cell functions and contribute to age-associated impaired T cell immunity. Targeting MDSCs during aging might help to maintain functional T cell responses and increase the chance of healthy aging. The online version contains supplementary material available at 10.1186/s12979-025-00524-w. View Publication

Chronic myeloid leukemia (CML) is a myeloproliferative neoplasm characterized by the uncontrolled proliferation of white blood cells. Tyrosine kinase inhibitors (TKIs) are the standard treatment; however,resistance to BCR::ABL1 mutations remains challenging. WEE1,a checkpoint kinase involved in mitosis and DNA repair,is a potential therapeutic target for CML treatment. Ponatinib-resistant CML cells were screened to identify candidates for overcoming drug resistance. The efficacy of the ABL TKI asciminib and the WEE1 inhibitor MK-1775 was evaluated using proliferation and colony formation assays. Public database analysis ( GSE100026 ) assessed WEE1/PKMYT1 expression in CML. In vitro screening identified MK-1775 as a promising therapeutic candidate. WEE1/PKMYT1 expression was elevated in CML cells compared to healthy cells. Both asciminib and MK-1775 inhibited CML cell proliferation after 72 h,with enhanced cytotoxicity when combined. Co-treatment reduced colony formation and induced G2/M arrest,whereas an increase in the sub-G1 cell population indicated apoptosis. Furthermore,the combination treatment disrupted the mitochondrial membrane potential. The combination of asciminib and WEE1 inhibition demonstrated greater efficacy than either drug alone,suggesting a novel therapeutic strategy for treating CML. These findings provide insights into overcoming TKI resistance and highlight a promising approach for future clinical applications. The online version contains supplementary material available at 10.1007/s12672-025-03036-7. View Publication

Neuroblastoma (NB) is the most common extracranial solid tumor in children characterized by poor immune infiltration and resistance to adaptive immunity,contributing to its limited response to immunotherapy. A key mechanism underlying immune evasion in cancer is autophagy,a cellular process that plays many roles in cancer by supporting tumor survival and regulating immune interactions. In this study,we investigate the impact of autophagy inhibition on NB tumor growth,immune modulation,and the efficacy of immunotherapy. Using both murine and human NB cell lines,we demonstrate that genetic and pharmacological inhibition of autophagy significantly reduces 3D spheroid growth and upregulates major histocompatibility complex class I (MHC-I) expression. In vivo studies further confirm that targeting autophagy suppresses tumor progression and promotes immune infiltration into the tumor. Notably,we observe a significant increase in CD8 + T cell recruitment and activation,suggesting that autophagy inhibition reshapes the immune landscape of NB,rendering it more susceptible to immune-mediated clearance. Crucially,autophagy inhibition also sensitizes NB cells to T cell-mediated cytotoxicity and enhances the therapeutic efficacy of GD2.CAR T-cell therapy. In vitro co-culture assays reveal increased CAR T cell-mediated tumor killing upon autophagy blockade,while in vivo models show prolonged tumor control and improved survival in treated mice compared to CAR T-cell therapy alone. These findings highlight autophagy as a key regulator of immune evasion in NB and suggest that its inhibition could serve as a promising therapeutic strategy to enhance immune recognition and improve the efficacy of immunotherapy. The online version contains supplementary material available at 10.1186/s13046-025-03453-0. View Publication

Our previous studies demonstrated that FOSL1 promotes glioblastoma (GBM) progression and stemness through pathways such as STAT3 and NF-κB signaling. Recently,we identified that FOSL1 physically interacts with the nuclear E3 ligase TRIM21. This study investigates the role of TRIM21 in GBM,including its interaction with FOSL1,its regulation of FOSL1 transactivation,and its ubiquitination-mediated degradation of tumor suppressor p27. Immunoprecipitation assays were used to evaluate the interactions between TRIM21,FOSL1,and p27. TRIM21 expression was manipulated through overexpression and siRNA-mediated knockdown to assess its effects on p27 levels and ubiquitination. TCGA and CGGA datasets were analyzed to explore correlations between TRIM21 expression,glioma subtypes,and patient survival. Glioma cell proliferation (MTT and colony formation) and invasion (transwell assays) were evaluated following TRIM21 manipulation. Immunohistochemistry on glioma patient tissue microarray (TMA) assessed TRIM21 expression and its association with FOSL1,IDH status,and glioma grade. The role of nuclear TRIM21 in FOSL1 promoter transactivation was analyzed via AP-1 binding sites. TCGA and CGGA revealed that TRIM21 is highly expressed in GBM,particularly in the mesenchymal subtypes,and correlates with poor survival outcomes. Functional assays demonstrated that TRIM21 enhances glioma cell proliferation and invasion. Immunohistochemistry confirmed elevated TRIM21 levels in gliomas,positively correlating with FOSL1 expression and glioma grade,and inversely correlating with IDH1 wild-type status. Mechanistically,TRIM21 physically interacts with FOSL1 and p27,driving tumorigenesis by transactivating FOSL1 via AP-1 binding sites and promoting p27 ubiquitination and degradation. These functions are mediated through TRIM21’s RING domain for p27 degradation and its PRYSPRY domain for FOSL1 regulation. TRIM21 functions as an oncogene in GBM by degrading the tumor suppressor p27 and promoting FOSL1 transactivation. These findings highlight TRIM21 as a promising therapeutic target in GBM. The online version contains supplementary material available at 10.1186/s12964-025-02325-6. View Publication

Nanoplastics (NPs) are emerging environmental pollutants that pose growing concerns due to their potential health risks. However,the effects of inhaled NP exposure during pregnancy on fetal brain development remain poorly understood. In this study,we investigated the impact of maternal exposure to polypropylene nanoplastics (PP-NPs) on fetal brain development and neurobehavioral outcomes in a mouse model and further explored its mechanism in human cerebral organoids. Maternal exposure to PP-NPs significantly impaired neuronal differentiation and proliferation in the fetal cortex. Neurobehavioral assessments revealed significant deficits in offspring following maternal exposure,including impaired spatial memory,reduced motor coordination,and heightened anxiety-like behavior. Furthermore,human brain organoids exposed to PP-NPs exhibited reduced growth and neuronal differentiation,with significant downregulation of key neuronal markers such as TUJ1,MAP2,and PAX6. Transcriptomic analysis identified alterations in gene expression,particularly in neuroactive ligand-receptor interaction pathway. Molecular docking and fluorescence co-localization analysis further suggested CYSLTR1 and PTH1R as key molecular targets of PP-NPs. These findings provide novel insights into the toxicological effects of NPs on the developing brain and emphasize the need for preventive measures to protect fetal neurodevelopment during pregnancy. The online version contains supplementary material available at 10.1186/s12951-025-03561-1. View Publication