技术资料

Ageing is the most prominent risk factor for Alzheimer’s disease (AD). However,the cellular mechanisms linking neuronal proteostasis decline to the characteristic aberrant protein deposits in the brains of patients with AD remain elusive. Here we develop transdifferentiated neurons (tNeurons) from human dermal fibroblasts as a neuronal model that retains ageing hallmarks and exhibits AD-linked vulnerabilities. Remarkably,AD tNeurons accumulate proteotoxic deposits,including phospho-tau and amyloid β,resembling those in APP mouse brains and the brains of patients with AD. Quantitative tNeuron proteomics identify ageing- and AD-linked deficits in proteostasis and organelle homeostasis,most notably in endosome–lysosomal components. Lysosomal deficits in aged tNeurons,including constitutive lysosomal damage and ESCRT-mediated lysosomal repair defects,are exacerbated in AD tNeurons and linked to inflammatory cytokine secretion and cell death. Providing support for the centrality of lysosomal deficits in AD,compounds ameliorating lysosomal function reduce amyloid β deposits and cytokine secretion. Thus,the tNeuron model system reveals impaired lysosomal homeostasis as an early event of ageing and AD. Subject terms: Organelles,Protein folding View Publication

Motor axon regeneration following peripheral nerve injury is critical for motor recovery but therapeutic interventions enhancing this are not available. We conduct a phenotypic screen on human motor neurons and identified blebbistatin,a non-muscle myosin II inhibitor,as the most effective neurite outgrowth promotor. Despite its efficacy in vitro,its poor bioavailability limits in vivo application. We,therefore,utilize a blebbistatin analog,NMIIi2,to explore its therapeutic potential for promoting axon regeneration. Local NMIIi2 application directly to injured axons enhances regeneration in human motor neurons. Furthermore,following a sciatic nerve crush injury in male mice,local NMIIi2 administration to the axonal injury site facilitates motor neuron regeneration,muscle reinnervation,and functional recovery. NMIIi2 also promotes axon regeneration in sensory,cortical,and retinal ganglion neurons. These findings highlight the therapeutic potential of topical NMII inhibition for treating axon damage. Subject terms: Regeneration and repair in the nervous system,Movement disorders View Publication

Beckwith-Wiedemann Syndrome (BWS) is an epigenetic overgrowth syndrome caused by methylation changes in the human 11p15 chromosomal locus. Patients with BWS may exhibit hepatomegaly,as well as an increased risk of hepatoblastoma. To understand the impact of these 11p15 changes in the liver,we performed a multiomic study [single nucleus RNA-sequencing (snRNA-seq) + single nucleus assay for transposable-accessible chromatin-sequencing (snATAC-seq)] of both BWS-liver and nonBWS-liver tumor-adjacent tissue. Our approach uncovers hepatocyte-specific enrichment of processes related to peroxisome proliferator—activated receptor alpha (PPARA). To confirm our findings,we differentiated a BWS induced pluripotent stem cell model into hepatocytes. Our data demonstrate the dysregulation of lipid metabolism in BWS-liver,which coincides with observed upregulation of PPARA during hepatocyte differentiation. BWS hepatocytes also exhibit decreased neutral lipids and increased fatty acid β-oxidation. We also observe increased reactive oxygen species byproducts in BWS hepatocytes,coinciding with increased oxidative DNA damage. This study proposes a putative mechanism for overgrowth and cancer predisposition in BWS liver due to perturbed metabolism. Subject terms: Paediatric research,Imprinting View Publication

Red blood cell development from erythroid progenitors requires profound reshaping of metabolism and gene expression. How these transcriptional and metabolic alterations are coupled is unclear. Nprl3 (an inhibitor of mTORC1) has remained in synteny with the α-globin genes for >500 million years,and harbours most of the a-globin enhancers. However,whether Nprl3 serves an erythroid role is unknown. We found that while haematopoietic progenitors require basal Nprl3 expression,erythroid Nprl3 expression is further boosted by the α-globin enhancers. This lineage-specific upregulation is required for sufficient erythropoiesis. Loss of Nprl3 affects erythroblast metabolism via elevating mTORC1 signalling,suppressing autophagy and disrupting glycolysis. Broadly consistent with these murine findings,human NPRL3-knockout erythroid progenitors produce fewer enucleated cells and demonstrate dysregulated mTORC1 signalling in response to nutrient availability and erythropoietin. Therefore,we propose that the anciently conserved linkage of NprI3,α-globin and their associated enhancers has coupled metabolic and developmental control of erythropoiesis. Subject terms: Differentiation,Genomics,Erythropoiesis View Publication

Brain organoids have been proposed as suitable human brain model candidates for a variety of applications. However,the lack of appropriate maturation limits the transferability of such functional tools. Here,we present a method to facilitate neuronal maturation by integrating astrocyte-secreted factors into hPSC-derived 2D and 3D neural culture systems. We demonstrate that protein- and nutrient-enriched astrocyte-conditioned medium (ACM) accelerates neuronal differentiation with enlarged neuronal layer and the overproduction of deep-layer cortical neurons. We captured the elevated changes in the functional activity of neuronal networks within ACM-treated organoids using comprehensive electrophysiological recordings. Furthermore,astrocyte-secreted cues can induce lipid droplet accumulation in neural cultures,offering protective effects in neural differentiation to withstand cellular stress. Together,these data indicate the potential of astrocyte secretions to promote neural maturation. Subject terms: Neurological models,Neuronal development View Publication

The airway epithelium represents a central barrier against pathogens and toxins while playing a crucial role in modulating the immune response within the upper respiratory tract. Understanding these mechanisms is particularly relevant for red foxes ( Vulpes vulpes ),which serve as reservoirs for various zoonotic pathogens like rabies or the fox tapeworm ( Echinococcus multilocularis ). The study aimed to develop,establish,and validate an air-liquid interface (ALI) organoid model of the fox respiratory tract using primary airway epithelial cells isolated from the tracheas and main bronchi of hunted red foxes. The resulting ALI cultures exhibited a structurally differentiated,pseudostratified epithelium,characterised by ciliated cells,mucus secretion,and tight junctions,as confirmed through histological and immunohistochemical analysis. Functional assessments using a paracellular permeability assay and measurement of transepithelial electrical resistance,demonstrated a tight epithelial barrier. The potential of model’s utility for studying innate immune responses to respiratory infections was validated by exposing the cultures to lipopolysaccharide,phorbol-12-myristate-13-acetate and ionomycin,and nematode somatic antigens. Quantitative PCR revealed notable changes in the expression of pro-inflammatory cytokines TNF and IL-33. This in vitro model represents a significant advancement in respiratory research for non-classical species that may act as important wildlife reservoirs for a range of zoonotic pathogens. View Publication

Overall survival of acute myeloid leukemia (AML) remains limited. Inhibitors of the master mitotic kinase PLK1 have emerged as promising therapeutics,demonstrating efficacy in an undefined subset of patients with AML. However,the clinical success of PLK1 inhibitors remains hindered by a lack of predictive biomarkers. The Fanconi anemia (FA) pathway,a tumor-suppressive network comprised of at least 22 genes,is frequently mutated in sporadic AML. In this study,we demonstrate that FA pathway disruption sensitizes AML cells to PLK1 inhibition. Mechanistically,we identify novel interactions between PLK1 and both FANCA and FANCD2 at mitotic centromeres. We demonstrate that PLK1 inhibition impairs recruitment of FANCD2 to mitotic centromeres,induces damage to mitotic chromosomes,and triggers mitotic collapse in FANCA-deficient cells. Our findings indicate that PLK1 inhibition targets mitotic vulnerabilities specific to FA pathway–deficient cells and implicate FA pathway mutations as potential biomarkers for the identification of patients likely to benefit from PLK1 inhibitors. This work demonstrates that FA pathway mutations,which are frequently observed in sporadic AML,induce hypersensitivity to PLK1 inhibition,providing rationale for a novel synthetic lethal therapeutic strategy for this patient population. View Publication

Multiple sclerosis (MS) is a chronic inflammatory disease characterized by immune‐mediated demyelination of the central nervous system,resulting in extensive neurological deficit and remyelination impairment. We have previously found that interleukin‐four induced one (IL4I1) protein modulates CNS inflammation and enhances remyelination in mouse models of experimental demyelination. However,it remained unclear if IL4I1 regulates lymphocyte activity in MS. To assess the therapeutic potential of IL4I1 in MS,we investigated the impact of IL4I1 treatment on human lymphocytes from peripheral blood mononuclear cells (PBMCs) obtained from healthy individuals and MS patients. We found that IL4I1 increased the relative densities of Th2 and regulatory T‐cells,while reducing Th17 cell density in healthy control (HC) samples. Furthermore,IL4I1‐treated lymphocytes promoted CNS remyelination when grafted into demyelinated spinal cord lesions in mice. We found that baseline endogenous IL4I1 expression was reduced in people with MS. However,unlike HCs,IL4I1 treatment had no significant effect on IL17 or TOB1 expression in lymphocytes derived from MS patients. These results suggest that IL4I1 skews CD4 + T‐cells to a regulatory state in healthy human lymphocytes,which may be essential for promoting remyelination. However,IL4I1 appears unable to exert its influence on lymphocytes in MS,indicating that impaired IL4I1‐mediated activity may underlie MS pathology. View Publication

Calcium-regulated heat-stable protein 1 (CARHSP1) has been identified as a cold shock domain (CSD) protein family member,participating in the regulation of ribosomal translation,mRNA degradation,and the rate of transcription termination. However,there is an extremely limited understanding of the function of CARHSP1 as an RNA binding protein (RBP) in prostate cancer (PCa). The expression pattern of CARHSP1 and the correlation between the CARHSP1 expression and clinical prognosis in PCa patients were analyzed by using multiple public databases. In vitro and in vivo functional assays were conducted to assess the role of CARHSP1. The mechanisms of CARHSP1 function on IL-17RA were identified by RNA pull-down and RNA stability assays. A co-culture model of Jurkat cells and PCa cells was established to investigate the potential role of CARHSP1 in tumor immunity of PCa. CARHSP1 was highly expressed in PCa,and correlated with advanced characteristics of PCa and unfavorable prognosis in PCa patients. Moreover,knockdown of CARHSP1 significantly dampened the capacity of proliferation,migration,invasion,and immune evasion of PCa cells in vitro and in vivo. Mechanistically,the RNA-binding protein CARHSP1 selectively bound to the mRNA of IL-17RA,resulting in the increased expression of both IL-17RA mRNA and protein. Downregulating expression of CARHSP1 shortened the half-life of IL-17RA mRNA and reduced its expression. Subsequently,the downstream pathways of IL-17RA,JAK-STAT3 signaling pathway and NF-κB signaling pathway,were activated by CARHSP1 and contributed to the malignant phenotype of PCa cells. In conclusion,our results demonstrated that the increased expression of CARHSP1 in PCa is correlated with advanced clinical characteristics and unfavorable prognosis,and CARHSP1 may promote the progression of PCa through enhancing the mRNA stability of IL-17RA and activating its downstream pathways. These results suggest that CARHSP1 is an important regulator of tumor microenvironment in PCa,and CARHSP1-IL-17RA axis could be potential novel therapeutic targets for PCa. The online version contains supplementary material available at 10.1186/s13578-025-01371-4. View Publication

Pancreatic cancer is one of the most malignant cancers,and limited therapeutic options are available. The induction of ferroptosis is considered to be a novel,promising strategy that has potential in cancer treatment,and ferroptosis inducers may be new options for eradicating malignant cancers that are resistant to traditional drugs. The exact mechanism underlying the function of sorcin in the initiation and progression of pancreatic cancer remains unclear. The expression of sorcin in cancer tissues was assessed by analyzing TCGA,GEO and immunohistochemical staining data,and the function of sorcin in the induction of ferroptosis in pancreatic cancer cells was investigated. The mechanism underlying the function of sorcin was revealed through proteomics,co-IP,Ch-IP,and luciferase assays. Natural product screening was subsequently performed to screen for products that interact with sorcin to identify new ferroptosis inducers. We first showed that sorcin expression was positively correlated with the survival and tumor stages of patients with pancreatic cancer,and we revealed that sorcin inhibited ferroptosis through its noncalcium binding function. Furthermore,we discovered that sorcin interacted with PAX5 in the cytoplasm and inhibited PAX5 nuclear translocation,which in turn decreased FBXL12 protein expression and then reduced ALDH1A1 ubiquitination,thus inhibiting ferroptosis. Moreover,an in-house natural product screen revealed that celastrol inhibited the interaction of sorcin and PAX5 by directly binding to the Cys194 residue of the sorcin protein; disruption of the sorcin-PAX5 interaction promoted the nuclear translocation of PAX5,induced the expression of FBXL12,increased the ubiquitylation of ALDH1A1,and eventually induced ferroptosis in pancreatic cancer cells. In this study,we revealed the mechanism of action of sorcin,which is a druggable target for inducing ferroptosis,we identified celastrol as a novel agent that induces ferroptosis,and we showed that disrupting the sorcin-PAX5 interaction is a promising therapeutic strategy for treating pancreatic cancer. The online version contains supplementary material available at 10.1186/s13045-025-01680-8. View Publication