参考文献

Retinoid-related molecules (RRM) are novel agents with tumor-selective cytotoxic/antiproliferative activity,a different mechanism of action from classic retinoids and no cross-resistance with other chemotherapeutics. ST1926 and CD437 are prototypic RRMs,with the former currently undergoing phase I clinical trials. We show here that ST1926,CD437,and active congeners cause DNA damage. Cellular and subcellular COMET assays,H2AX phosphorylation (gamma-H2AX),and scoring of chromosome aberrations indicate that active RRMs produce DNA double-strand breaks (DSB) and chromosomal lesions in NB4,an acute myeloid leukemia (AML) cell line characterized by high sensitivity to RRMs. There is a direct quantitative correlation between the levels of DSBs and the cytotoxic/antiproliferative effects induced by RRMs. NB4.437r blasts,which are selectively resistant to RRMs,do not show any sign of DNA damage after treatment with ST1926,CD437,and analogues. DNA damage is the major mechanism underlying the antileukemic activity of RRMs in NB4 and other AML cell lines. In accordance with the S-phase specificity of the cytotoxic and antiproliferative responses of AML cells to RRMs,increases in DSBs are maximal during the S phase of the cell cycle. Induction of DSBs precedes inhibition of DNA replication and is associated with rapid activation of ataxia telangectasia mutated,ataxia telangectasia RAD3-related,and DNA-dependent protein kinases with subsequent stimulation of the p38 mitogen-activated protein kinase. Inhibition of ataxia telangectasia mutated and DNA-dependent protein kinases reduces phosphorylation of H2AX. Cells defective for homologous recombination are particularly sensitive to ST1926,indicating that this process is important for the protection of cells from the RRM-dependent DNA damage and cytotoxicity. View Publication

PURPOSE The radiosensitivity of the normal intestinal epithelium is the major limiting factor for definitive radiotherapy against abdominal malignancies. Radiosensitizers,which can be used without augmenting radiation toxicity to normal tissue,are still an unmet need. Inhibition of proteosomal degradation is being developed as a major therapeutic strategy for anticancer therapy as cancer cells are more susceptible to proteasomal inhibition-induced cytotoxicity compared with normal cells. Auranofin,a gold-containing antirheumatoid drug,blocks proteosomal degradation by inhibiting deubiquitinase inhibitors. In this study,we have examined whether auranofin selectively radiosensitizes colon tumors without promoting radiation toxicity in normal intestine. EXPERIMENTAL DESIGN The effect of auranofin (10 mg/kg i.p.) on the radiation response of subcutaneous CT26 colon tumors and the normal gastrointestinal epithelium was determined using a mouse model of abdominal radiation. The effect of auranofin was also examined in a paired human colonic organoid system using malignant and nonmalignant tissues from the same patient. RESULTS Both in the mouse model of intestinal injury and in the human nonmalignant colon organoid culture,auranofin pretreatment prevented radiation toxicity and improved survival with the activation of p53/p21-mediated reversible cell-cycle arrest. However,in a mouse model of abdominal tumor and in human malignant colonic organoids,auranofin inhibited malignant tissue growth with inhibition of proteosomal degradation,induction of endoplasmic reticulum stress/unfolded protein response,and apoptosis. CONCLUSIONS Our data suggest that auranofin is a potential candidate to be considered as a combination therapy with radiation to improve therapeutic efficacy against abdominal malignancies. View Publication

Accumulating data have shown that targeting breast cancer stem cells (CSCs) is an auspicious way for anticancer therapies. This study demonstrated that the antirheumatic drug auranofin is a potent CSC inhibitor with anti-CSC action on breast cancer. This research focused on investigating the effect of auranofin on breast cancer and CSCs and its cellular mechanism. Mammosphere formation,colony formation,levels of CD44 high /CD24 low,and aldehyde dehydrogenase 1 expression in the cells were evaluated after auranofin treatment. The anti-CSC properties of auranofin were further examined by gel shift assay and cytokine detection. Auranofin suppressed cell growth,colony formation,migration,and mammosphere formation and triggered apoptosis in breast cancer. Auranofin decreased the CD44 high /CD24 low - and aldehyde dehydrogenase-expressed subpopulations,as well as the Stat3-DNA interaction and phosphorylated Stat3 level. Auranofin also decreased the extracellular levels of interleukin-8 (IL-8) in the mammosphere media. Auranofin suppressed the Stat3/IL-8 signal and killed CSCs; therefore,it may be a potential target for CSCs. View Publication

Pediatric high-grade astrocytomas (HGAs) account for 15-20% of all pediatric central nervous system tumors. These neoplasms predominantly involve the supratentorial hemispheres or the pons--diffuse intrinsic pontine gliomas (DIPG). Assumptions that pediatric HGAs are biologically similar to adult HGAs have recently been challenged,and the development of effective therapeutic modalities for DIPG and supratentorial HGA hinges on a better understanding of their biological properties. Here,20 pediatric HGAs (9 DIPGs and 11 supratentorial HGAs) were subject to gene expression profiling following approval by the research ethics board at our institution. Many of these tumors showed expression signatures composed of genes that promote G1/S and G2/M cell cycle progression. In particular,Aurora kinase B (AURKB) was consistently and highly overexpressed in 6/9 DIPGs and 8/11 HGAs. Array data were validated using quantitative real-time PCR and immunohistochemistry,as well as cross-validation of our data set with previously published series. Inhibition of Aurora B activity in DIPG and in pediatric HGA cell lines resulted in growth arrest accompanied by morphological changes,cell cycle aberrations,nuclear fractionation and polyploidy as well as a reduction in colony formation. Our data highlight Aurora B as a potential therapeutic target in DIPG. View Publication

Autism Spectrum Disorder (ASD) is a neurodevelopmental condition that affects communication,social interaction,and behavior. Calcium (Ca2+) signaling dysregulation has been frequently highlighted in genetic studies as a contributing factor to aberrant developmental processes in ASD. Herein,we used ASD and control induced pluripotent stem cells (iPSCs) to investigate transcriptomic and functional Ca2+ dynamics at various stages of differentiation to cortical neurons. Idiopathic ASD and control iPSC lines underwent the dual SMAD inhibition differentiation protocol to direct their fate toward cortical neurons. Samples from multiple time points along the course of differentiation were processed for bulk RNA sequencing,spanning the following sequential stages: the iPSC stage,neural induction (NI) stage,neurosphere (NSP) stage,and differentiated cortical neuron (Diff) stage. Our transcriptomic analyses suggested that the numbers of Ca2+ signaling-relevant differentially expressed genes between ASD and control samples were higher in the iPSC and Diff stages. Accordingly,samples from the iPSC and Diff stages were processed for Ca2+ imaging studies. Results revealed that iPSC-stage ASD samples displayed elevated maximum Ca2+ levels in response to ATP compared to controls. By contrast,in the Diff stage,ASD neurons showed reduced maximum Ca2+ levels in response to ATP but increased maximum Ca2+ levels in response to KCl and DHPG relative to controls. Considering the distinct functional signaling contexts of these stimuli,this differential profile of receptor- and ionophore-mediated Ca2+ response suggests that aberrant calcium homeostasis underlies the pathophysiology of ASD neurons. Our data provides functional evidence for Ca2+ signaling dysregulation during neurogenesis in idiopathic ASD. View Publication

Multiple sclerosis (MS) is caused by T cells that are reactive for brain antigens. In experimental autoimmune encephalomyelitis,the animal model for MS,myelin-reactive T cells initiate the autoimmune process when entering the nervous tissue and become reactivated upon local encounter of their cognate CNS antigen. Thereby,the strength of the T-cellular reactivation process within the CNS tissue is crucial for the manifestation and the severity of the clinical disease. Recently,B cells were found to participate in the pathogenesis of CNS autoimmunity,with several diverse underlying mechanisms being under discussion. We here report that B cells play an important role in promoting the initiation process of CNS autoimmunity. Myelin-specific antibodies produced by autoreactive B cells after activation in the periphery diffused into the CNS together with the first invading pathogenic T cells. The antibodies accumulated in resident antigen-presenting phagocytes and significantly enhanced the activation of the incoming effector T cells. The ensuing strong blood-brain barrier disruption and immune cell recruitment resulted in rapid manifestation of clinical disease. Therefore,myelin oligodendrocyte glycoprotein (MOG)-specific autoantibodies can initiate disease bouts by cooperating with the autoreactive T cells in helping them to recognize their autoantigen and become efficiently reactivated within the immune-deprived nervous tissue. View Publication

Type I IFNs are key mediators of immune defense against viruses and bacteria. Type I IFNs were also previously implicated in protection against fungal infection,but their roles in antifungal immunity have not been thoroughly investigated. A recent study demonstrated that bacterial and fungal β-glucans stimulate IFN-β production by dendritic cells (DCs) following detection by the Dectin-1 receptor,but the effects of β-glucan-induced type I IFNs have not been defined. We investigated whether type I IFNs regulate CD8 T cell activation by fungal β-glucan particle-stimulated DCs. We demonstrate that β-glucan-stimulated DCs induce CD8 T cell proliferation,activation marker (CD44 and CD69) expression,and production of IFN-γ,IL-2,and granzyme B. Moreover,we show that type I IFNs support robust CD8 T cell activation (proliferation and IFN-γ and granzyme B production) by β-glucan-stimulated DCs in vitro and in vivo due to autocrine effects on the DCs. Specifically,type I IFNs promote Ag presentation on MHC I molecules,CD86 and CD40 expression,and the production of IL-12 p70,IL-2,IL-6,and TNF-α by β-glucan-stimulated DCs. We also demonstrate a role for autocrine type I IFN signaling in bacterial LPS-induced DC maturation,although,in the context of LPS stimulation,this mechanism is not so critical for CD8 T cell activation (promotes IFN-γ production but not proliferation or granzyme B production). This study provides insight into the mechanisms underlying CD8 T cell activation during infection,which may be useful in the rational design of vaccines directed against pathogens and tumors. View Publication

Circulating tumor cells (CTCs) are important clinical indicators for prognosis and treatment efficacy. However,CTC investigation is hampered by their low number,making the establishment of permanent CTC lines very challenging. We derived and characterized nine CTC lines using blood samples from a patient with metastatic colorectal cancer collected before and after chemotherapy and targeted therapy,and during cancer progression. These cell lines displayed an intermediate epithelial/mesenchymal phenotype,stem-cell like characteristics,angiogenesis potential,an osteomimetic signature and the capacity to escape from the immune system. Moreover,they showed changes in mRNA and protein expression (e.g.,DEFA6,ABCB1 and GAL),whereas analysis of chromosomal copy number aberrations revealed no significant variation over time. These data indicate that although CTC lines derived from sequential blood samples during therapy have common traits,treatment-resistant CTC clones with distinct phenotypic characteristics are selected over time. View Publication

Autologous feeder cells have been developed by various methods to minimize the presence of xenogenic entities in human embryonic stem cell (hESC) cultures. However,there was no systematic comparison of supportive effects of the feeder cells on hESC growth,nor comparison to the supportive effects of various feeder-free culture systems and standard mouse feeder cells. In this study,we aimed to compare the supportive abilities of autologous feeders derived either directly from H9 hESCs (H9 dF) or from outgrowth of embryoid body predifferentiated in suspension from H9 hESCs (H9 ebF). Mouse feeder system and matrigel-mTeSR1 feeder-free system were used as controls. H9 ebF was found to secrete more basic fibroblast growth factor in the conditioned medium than H9 dF did. The undifferentiated state of H9 hESCs was sustained more stably on H9 ebF than on H9 dF,and the differentiation potential of H9 hESCs on H9 ebF was higher than on H9 dF. We concluded that H9 ebF was an optimal autologous feeder to maintain the long-term undifferentiated state of hESCs in our current culture system. This study helps to standardize the autologous culture of hESCs. It also suggests a more definite direction for future development of xeno-free culture system for hESCs. View Publication

Induced pluripotent stem cell (iPSC)-derived mesenchymal stem cells (iMSCs) have greater potential for generating chondrocytes without hypertrophic and fibrotic phenotypes compared to bone marrow-derived mesenchymal stem/stromal cells (BMSCs). However,there is a lack of research demonstrating the use of autologous iMSCs for repairing articular chondral lesions in large animal models. In this study,we aimed to evaluate the effectiveness of autologous miniature pig (minipig) iMSC-chondrocyte (iMSC-Ch)-laden implants in comparison to autologous BMSC-chondrocyte (BMSC-Ch)-laden implants for cartilage repair in porcine femoral condyles. iMSCs and BMSCs were seeded into fibrin glue/nanofiber constructs and cultured with chondrogenic induction media for 7 days before implantation. To assess the regenerative capacity of the cells,19 skeletally mature Yucatan minipigs were randomly divided into microfracture control,acellular scaffold,iMSC,and BMSC subgroups. A cylindrical defect measuring 7 mm in diameter and 0.6 mm in depth was created on the articular cartilage surface without violating the subchondral bone. The defects were then left untreated or treated with acellular or cellular implants. Both cellular implant-treated groups exhibited enhanced joint repair compared to the microfracture and acellular control groups. Immunofluorescence analysis yielded significant findings,showing that cartilage treated with iMSC-Ch implants exhibited higher expression of COL2A1 and minimal to no expression of COL1A1 and COL10A1,in contrast to the BMSC-Ch-treated group. This indicates that the iMSC-Ch implants generated more hyaline cartilage-like tissue compared to the BMSC-Ch implants. Our findings contribute to filling the knowledge gap regarding the use of autologous iPSC derivatives for cartilage repair in a translational animal model. Moreover,these results highlight their potential as a safe and effective therapeutic strategy. The online version contains supplementary material available at 10.1186/s13287-025-04215-7. View Publication