技术资料

BackgroundCancer stem cells (CSCs) are considered the ‘seeds’ of recurrence after chemotherapy,but eliminating CSCs remains notoriously challenging. This study aims to examine whether cell cycle checkpoint kinase 1 (CHK1) blockade can abrogate the stemness of ovarian cancer (OC) cells,making them easier targets of anti-tumor immunity. Methods: Prexasertib was used to block CHK1 in OC cell lines and xenografts,and its cytotoxicity was assessed in vitro and in vivo. In vitro tumor-sphere formation assays and stemness markers were used to evaluate cell stemness. PD-L1 expressions were examined via qRT-PCR,Western blot,flow cytometry,and immunohistochemistry. Prexasertib in combination with anti-PD-L1 antibody Atezolizumab was tested in immune-proficient mice bearing OC xenografts in terms of effects on tumor growth,tumor cell stemness,and tumor infiltrating lymphocytes via tumor volume monitoring,immunohistochemistry,and flow cytometry. Results: Prexasertib effectively inhibited CHK1 phosphorylation,exhibited significant anti-tumor effects in vitro and in vivo,accompanied by decreased OC cell stemness. CHK1 was highly expressed in tumor spheres versus tumor cells cultured in 2D system,and Prexasertib treatment suppressed sphere formation and reduced the ALDH+ cell fraction. Unexpectedly,Prexasertib upregulated PD-L1 expression in tumor cells. In vivo,combining Prexasertib with Atezolizumab led to more remarkable remission of tumors,when compared with Prexasertib or Atezolizumab alone. Meanwhile,the tumor-infiltrating CD8+ T cells significantly increased in the combination group,while exhausted T cells decreased; the treatments did not affect CD4+ cell infiltration. Conclusions: Dual targeting of CHK1 and PD-L1 may improve OC treatment by simultaneously suppressing stemness and enhancing anti-tumor immunity. View Publication

Since the COVID-19 pandemic,there has been a documented rise in the incidence of neurological manifestations among individuals complicated with encephalitis or myelitis. The spectrum of neurological symptoms associated with HCoVs infections is expanding. However,the infection characteristics and pathogenesis of seasonal HCoVs to the central nervous system remain obscure. No pharmacological agents have demonstrated the capacity to specifically and efficaciously mitigate the neurological symptoms induced by HCoVs infections to date. Methods: We developed human cerebral organoids (HCOs) derived from human induced pluripotent stem cells and established a blood–brain barrier (BBB) HCOs co-culture model. We subjected these models to seasonal human coronavirus (HCoV) infections to investigate the viral characteristics within the central nervous system (CNS). Utilizing RNA sequencing,we conducted a preliminary exploration of the mechanisms underlying virus-induced inflammatory responses in the CNS. Furthermore,we assessed the efficacy of antiviral and anti-inflammatory drugs using the HCO model. Results: Our results showed that among seasonal coronaviruses,HCoV-OC43 replicates efficiently within the organoids,primarily targeting neurons and astrocytes,and disrupts the barrier function of the BBB. RNA sequencing analysis revealed that HCoV-OC43 infection triggers an inflammatory response through the TNF and NF-κB signaling pathways,leading to cell death,impaired neuronal function,and disrupted interneuron signaling. Interestingly,Bardoxolone methyl (CDDO-Me) demonstrated antiviral effects comparable to remdesivir,reducing both inflammation and cell death. Conclusions: Conclusively,HCOs infected with HCoV-OC43 offer valuable insights into the pathogenesis of HCoVs in central nervous system (CNS),and might serve as a tool for developing novel therapeutic strategies for HCoVs infections,including COVID-19,especially on exploring treatment candidates.Graphical abstract View Publication

Antibody–drug conjugates (ADCs) represent a promising strategy in cancer therapy,enabling the targeted delivery of cytotoxic agents to tumor cells. In this study,we developed and characterized novel ADCs combining the anti-EGFR monoclonal therapeutic antibody Cetuximab (Cet) with two aminobisphosphonates (N-BPs) analogues of zoledronic acid (ZA): DC310 and the aminothiazole DC315. These conjugates aim to enhance antitumor efficacy of Cet in colorectal cancer (CRC) by both directly inhibiting tumor cell growth and activating Vδ2 T lymphocytes. We optimized the drug-antibody ratio (DAR),achieving significantly higher DARs compared to previously reported Cet-ZA conjugate,particularly with Cet-DC315 (DAR ≈ 23). Both ADCs retained selective EGFR binding in CRC cell lines and patient-derived organoids (PDO). Functionally,Cet-DC315 markedly inhibited proliferation of EGFR⁺ CRC cell lines in conventional cultures and 3D spheroids. Furthermore,Cet-DC-315 uniquely induced expansion and cytotoxic activation of Vδ2 T cells in co-cultures with CRC cell lines,PDO,and primary tumor samples. These findings suggest that ADCs incorporating novel N-BPs such as DC315 represent a potent approach for dual antitumor targeting through direct cytostatic effects and immune activation,offering a potential therapeutic advantage in the treatment of EGFR+ colorectal cancer. View Publication

Conventional human embryonic stem cells (hESCs) are capable of self-renewal and simultaneously poised for differentiation. But the mechanisms underlying this primed pluripotent state,which endows them with elevated responsiveness to differentiation cues,remain largely underexplored. Especially,little is known about the pivotal transcription factors (TFs) that orchestrate hESCs towards primed pluripotency. Here,we report a function of TF ZNF263 in pluripotency priming. Genetic and functional assays reveal that ZNF263 directly initiates the incipient expression of early differentiation genes and concurrently dampens the core pluripotency circuitry in hESCs,greatly tilting the balance from pluripotency maintenance to lineage priming. Importantly,ZNF263 deficiency markedly impairs pluripotency dissolution and multi-lineage differentiation in hESCs,particularly toward ectoderm. Moreover,single-cell transcriptomic profiling reveals that ZNF263 promotes the priming of cell fate commitment in hESCs,suggesting its indispensable requirement for pluripotency priming and lineage commitment continuum. Together,we demonstrate the role of ZNF263 in establishing the primed pluripotent state in hESCs and facilitating their differentiation into primary germ layer lineages. Human embryonic stem cells are simultaneously capable of self-renewal and poised for differentiation. Here,the authors show a role for the ZNF263 transcription factor promotes primed pluripotency and facilitates differentiation into primary germ layer lineages. View Publication

Phosphatidylinositol 3-kinase delta (PI3KCD) is a critical signaling enzyme for B cell development,activation,function and immune regulation. Gain-of-function mutations in PI3KCD result in the congenital immunodeficiency known as Activated PI3KCD Syndrome (APDS). APDS patients are prone to repeated infections and other serious clinical manifestations. Here,we determine how B cell-intrinsic expression of the APDS-associated PI3KCDE1021K mutation impacts immune responses to the protozoan parasite Trypanosoma congolense. PI3KCDE1021K/B mice exhibit a significant expansion of IL10-expressing B cells within the spleen and peritoneal cavity,which was associated with impaired control of T. congolense infection. Despite the generation of robust germinal center,plasma cell and antibody responses,PI3KCDE1021K/B mice show elevation in the first wave of parasitemia and increased mortality. We further characterize the phenotype of the expanded IL10-producing B cell population in PI3KCDE1021K/B mice,which show hallmarks of innate-like regulatory B cells (Breg) and expression of multiple inhibitory molecules. This Breg expansion is associated with reduced IFNγ/IL10 ratio,reduced TNFα production and impaired activation of myeloid cells,likely compromising the innate response to infection. These findings highlight the profound impact of dysregulated PI3KCD activity on regulatory B cells that can functionally impair innate immune responses controlling a systemic parasite protozoan disease. Author summaryB cells and antibodies play a critical role in the immune response to Trypanosome parasites. Molecular signaling networks within B cells can control the type of response generated during infection. Here,we studied how a genetic variant in the signaling enzyme PI3KCD,previously linked to human immune deficiencies,impacts B cell responses to Trypanosome infection. We find that mice expressing the PI3KCDE1021K mutation in their B cells show impaired control of Trypanosome infection,and alterations in several aspects of the immune response. Specifically,we noted these mice poorly control parasite growth within the first week of infection,a timeframe where specific antibody responses have not yet been generated. We noted an altered balance between pro-inflammatory and anti-inflammatory cytokine mediators produced within the first week of infection. This was associated with high numbers of regulatory B cells expressing multiple molecules capable of inhibiting other cells of the immune system. We further found that these mice show functional alterations in other critical immune cell types,such as macrophages and T cells. These findings highlight the impact of dysregulated PI3KCD activity on regulatory B cells that can impair immune responses controlling a systemic parasite protozoan disease. View Publication

Parechovirus ahumpari 3 (HPeV-3) is among the main agents causing severe neonatal neurological infections such as encephalitis and meningitis. However,the underlying molecular mechanisms and changes to the host cellular landscape leading to neurological disease has been understudied. Through quantitative proteomic analysis of HPeV-3 infected neural organoids,we identified unique metabolic changes following HPeV-3 infection that indicate immunometabolic dysregulation. Protein and pathway analyses showed significant alterations in neurotransmission and potentially,neuronal excitotoxicity. Elevated levels of extracellular glutamate,lactate dehydrogenase (LDH),and neurofilament light (NfL) confirmed glutamate excitotoxicity to be a key mechanism contributing to neuronal toxicity in HPeV-3 infection and can lead to apoptosis induced by caspase signaling. These insights are pivotal in delineating the metabolic landscape following severe HPeV-3 CNS infection and may identify potential host targets for therapeutic interventions. View Publication

DNA repair mechanisms in human primary cells,including error-free repair,and,recurrent nuclease cleavage events,remain largely uncharacterised. We elucidate gene-editing related repair processes using Cleavage and Lesion Evaluation via Absolute Real-time dPCR (CLEAR-time dPCR),an ensemble of multiplexed dPCR assays that quantifies genome integrity at targeted sites. Utilising CLEAR-time dPCR we track active DSBs,small indels,large deletions,and other aberrations in absolute terms in clinically relevant edited cells,including HSPCs,iPSCs,and T-cells. By quantifying up to 90% of loci with unresolved DSBs,CLEAR-time dPCR reveals biases inherent to conventional mutation screening assays. Furthermore,we accurately quantify DNA repair precision,revealing prevalent scarless repair after blunt and staggered end DSBs and recurrent nucleases cleavage. This work provides one of the most precise analyses of DNA repair and mutation dynamics,paving the way for mechanistic studies to advance gene therapy,designer editors,and small molecule discovery. Quantifying genomic aberrations resulting from designer nucleases activity is essential for gene therapy clinical translation. Here,the authors present a modular digital PCR technique that profiles DNA repair precision and cut-repair cycles at the edited loci,exposing current evaluation biases. View Publication

We used high-resolution optical mapping (~50 µm) to investigate potential arrhythmia mechanisms following transplantation of engineered cardiac tissue. We induced myocardial infarction in 6 immunosuppressed pigs and implanted cardiac spheroids into the border zone. One week later,600-µm-thick cardiac slices containing implanted spheroids were harvested and electrical propagation was imaged. Histology showed low connexin-43 expression,scar,and misaligned muscle fibers at the graft-host interface. We observed propagation from host-to-graft in 10 slices from 3 pigs. Host-graft electrical bridges were spaced by millimeters. Propagation was ~4-fold slower in the graft than host. One graft beat spontaneously,but activation did not propagate from graft-to-host in this,or any other slice. We did not observe reentry,but slow in-graft conduction and sparse electrical bridges provided opportunity for reentry induction. These data reveal potential for reentrant or focal arrhythmias 1 week post-implant,which may resolve with maturation of the graft and the graft-host interface. View Publication

USH2A mutations are the leading cause of autosomal recessive retinitis pigmentosa (RP),a progressive blinding disease marked by photoreceptor degeneration. Animal models fail to recapitulate the features of USH2A RP seen in humans,and its earliest pathogenic events remain unknown. Here,we established a human model of USH2A RP using retinal organoids derived from patient induced pluripotent stem cells and CRISPR-Cas9-engineered isogenic-USH2A−/− induced pluripotent stem cells. Methods: We assessed organoids for cellular,molecular,and morphological defects using serial live imaging and whole organoid and fixed section analyses. Results: Both patient-derived and isogenic-USH2A−/− organoids showed preferential rod photoreceptor loss followed by widespread degeneration,consistent with the clinical phenotype. Additionally,isogenic-USH2A−/− organoids showed early defects in proliferation and structure. Conclusions: Our findings suggest that molecular changes precede overt photoreceptor loss in USH2A RP,and pathogenesis may begin before clinical symptoms emerge. By defining early and late disease features,we provide new insight on the developmental origins of USH2A RP to guide therapeutic strategies. View Publication

Chronic compressive cervical spinal cord injury (cCSCI),a debilitating condition,lacks effective treatment options. Addressing this gap,our study introduces a novel rat model of cCSCI developed through spinal cord compression via synthetic polyether sheet implantation,closely mimicking human pathology. We evaluated the model’s fidelity utilizing a comprehensive series of behavioral,electrophysiological,and histological assessments. Our research also explored the therapeutic potential of oligodendrogenic neural progenitor cells (oNPCs) derived from induced pluripotent stem cells. Transplanted oNPCs successfully integrated into the host spinal cord,differentiated into neurons,astrocytes,and oligodendrocytes,and demonstrated a remarkable capacity for enhancing neuroplasticity. Electrophysiological analyses revealed significant improvements in motor evoked potentials and a rectification of the excitability imbalance posttransplantation,indicating substantial recovery of motor circuits. Histological findings complemented these results,showing enhanced remyelination and a reduction in excitatory transmitter expression in the residual gray matter. Functionally,the transplantation of oNPCs led to marked improvements in grip strength,locomotor abilities,and sensory functions,surpassing those seen with standard treatments. This study not only provides a novel and reliable rat model of cCSCI for further research but also highlights the potential of oNPCs as a transformative approach for spinal cord injury therapy,suggesting their significant role in neural regeneration and repair. View Publication

Management of chronic kidney disease (CKD) remains a major challenge due limited therapeutic options to reverse fibrosis,which is a critical feature in CKD. Partial epithelial-to-mesenchymal transition (EMT) of tubular epithelial cells (TECs) is a key driver of fibrosis,and has become an important focus for kidney protection strategies. Blood platelets,a major source of circulating transforming growth factor beta (TGF-β),are implicated in pathogenesis of CKD,but their involvement in EMT and kidney fibrosis remains uncertain. Methods: We used two mouse models of renal fibrosis—diabetic kidney disease (DKD) and unilateral ureter obstruction (UUO)—to examine the connection between platelets,partial EMT,and fibrosis. Platelet inhibition or depletion was performed to assess EMT,cell cycle arrest,and fibrosis. In vitro,platelets were applied to TECs and kidney organoids. To determine the role of TGF-β signaling,we used TGF-βRI inhibitor. Expression of EMT,and fibrosis markers,as well as TGF-β1 signaling,were analyzed using western blot,reverse transcription quantitative PCR (RT-qPCR),enzyme-linked immunosorbent assay (ELISA),and immunostaining. Results: In both animal models,platelet inhibition or depletion resulted in reduced expression of cell cycle arrest marker p21,partial EMT and fibrosis. In vitro,activated platelets stimulated cell cycle arrest,EMT,and fibrosis in TECs and kidney organoids. Chronically injured TECs experience cell-cycle arrest which promote a paracrine EMT program in TECs,jointly leading to fibrosis. This platelet-mediated effect on cell cycle arrest and EMT was driven by TGF-β1 signaling,as selective inhibition of the TGF-β receptor rescued these dysfunctional phenotypes. Conclusions: Our study demonstrates that platelets activate the TGF-β1 pathway,leading to cell cycle arrest,EMT and renal fibrosis. These findings suggest that antiplatelet therapies may have potential renoprotective effects by protecting tubular homeostasis,attenuating partial EMT and fibrosis. View Publication

Bipolar disorder (BD) is a complex psychiatric condition usually requiring long-term treatment. Lithium (Li) remains the most effective mood stabilizer for BD,yet it benefits only a subset of patients,and its precise mechanism of action remains elusive. Exome sequencing has identified AKAP11 (A-kinase anchoring protein 11) as a shared risk gene for BD and schizophrenia (SCZ). Given that both the AKAP11-Protein Kinase A (PKA) complex and Li target and inhibit Glycogen Synthase Kinase-3 beta (GSK3β),we hypothesize that Li may partially normalize the transcriptomic and/or epigenomic alterations observed in heterozygous AKAP11-knockout (Het-AKAP11-KO) iPSC-derived neurons. In this study,we employed genome-wide approaches to assess the effects of Li on the transcriptome and epigenome of human iPSC-derived Het-AKAP11-KO neuronal culture. We show that chronic Li treatment in this cellular model upregulates key pathways that were initially downregulated by Het-AKAP11-KO,several of which have also been reported as downregulated in synapses of BD and SCZ post-mortem brain tissues. Moreover,we demonstrated that Li treatment partially rescues certain transcriptomic alterations resulting from Het-AKAP11-KO,bringing them closer to the WT state. We suggest two possible mechanisms underlying these transcriptomic effects: (1) Li modulates histone H3K27ac levels at intergenic and intronic enhancers,influencing enhancer activity and transcription factor binding,and (2) Li enhances GSK3β serine 9 phosphorylation,impacting WNT/β-catenin signaling and downstream transcription. These findings underscore Li’s potential as a therapeutic agent for BD and SCZ patients carrying AKAP11 loss-of-function variants or exhibiting similar pathway alterations to those observed in Het-AKAP11-KO models. View Publication