技术资料

Deciding to exit pluripotency and undergo differentiation is of singular importance for pluripotent cells,including embryonic stem cells (ESCs). The molecular mechanisms for these decisions to differentiate,as well as reversing those decisions during induced pluripotency (iPS),have focused largely on transcriptomic controls. Here,we explore the role of translational control for the maintenance of pluripotency and the decisions to differentiate. Global protein translation is significantly reduced in hESCs compared to their differentiated progeny. Furthermore,p70 S6K activation is restricted in hESCs compared to differentiated fibroblast-like cells. Disruption of p70 S6K-mediated translation by rapamycin or siRNA knockdown in undifferentiated hESCs does not alter cell viability or expression of the pluripotency markers Oct4 and Nanog. However,expression of constitutively active p70 S6K,but not wild-type p70 S6K,induces differentiation. Additionally,hESCs exhibit high levels of the mTORC1/p70 S6K inhibitory complex TSC1/TSC2 and preferentially express more rapamycin insensitive mTORC2 compared to differentiated cells. siRNA-mediated knockdown of both TSC2 and Rictor elevates p70 S6K activation and induces differentiation of hESCs. These results suggest that hESCs tightly regulate mTORC1/p70 S6K-mediated protein translation to maintain a pluripotent state as well as implicate a novel role for protein synthesis as a driving force behind hESC differentiation. View Publication

Epiblast stem cells (EpiSCs) are pluripotent cells derived from post-implantation late epiblasts in vitro. EpiSCs are incapable of contributing to chimerism,indicating that EpiSCs are less pluripotent and represent a later developmental pluripotency state compared with inner cell mass stage murine embryonic stem cells (mESCs). Using a chemical approach,we found that blockage of the TGFβ pathway or inhibition of histone demethylase LSD1 with small molecule inhibitors induced dramatic morphological changes in EpiSCs toward mESC phenotypes with simultaneous activation of inner cell mass-specific gene expression. However,full conversion of EpiSCs to the mESC-like state with chimerism competence could be readily generated only with the combination of LSD1,ALK5,MEK,FGFR,and GSK3 inhibitors. Our results demonstrate that appropriate synergy of epigenetic and signaling modulations could convert cells at the later developmental pluripotency state to the earlier mESC-like pluripotency state,providing new insights into pluripotency regulation. View Publication

Neutrophil apoptosis is essential for the resolution of inflammation but is delayed by several inflammatory mediators. In such terminally differentiated cells it has been uncertain whether these agents can inhibit apoptosis through transcriptional regulation of anti-death (Bcl-X(L),Mcl-1,Bcl2A1) or BH3-only (Bim,Bid,Puma) Bcl2-family proteins. We report that granulocyte/macrophage colony-stimulating factor (GM-CSF) and tumor necrosis factor (TNF)-α prevent the normal time-dependent loss of Mcl-1 and Bcl2A1 in neutrophils,and we demonstrate that they cause an NF-κB-dependent increase in Bcl-X(L) transcription/translation. We show that GM-CSF and TNF-α increase and/or maintain mRNA levels for the pro-apoptotic BH3-only protein Bid and that GM-CSF has a similar NF-κB-dependent effect on Bim transcription and BimEL expression. The in-vivo relevance of these findings was indicated by demonstrating that GM-CSF is the dominant neutrophil survival factor in lung lavage from patients with ventilator-associated pneumonia,confirming an increase in lung neutrophil Bim mRNA. Finally GM-CSF caused mitochondrial location of Bim and a switch in phenotype to a cell that displays accelerated caspase-9-dependent apoptosis. This study demonstrates the capacity of neutrophil survival agents to induce a paradoxical increase in the pro-apoptotic proteins Bid and Bim and suggests that this may function to facilitate rapid apoptosis at the termination of the inflammatory cycle. View Publication

Small populations within an increasing array of solid tumors,labeled cancer stem cells (CSC) or tumor-initiating cells (TIC),have the ability to differentiate,self-renew,and replicate the original tumor in vivo. To date,these cells have been distinguished from the bulk-tumor population by the expression pattern of cell-surface proteins (e.g.,CD24,CD44,CD133) and cellular activities,such as the efflux of Hoechst dye or aldehyde dehydrogenase activity. Recent data have shown that these markers are inducible by exposure to anticancer agents; this finding highlights not only the potential fluidity of the CSC compartment,but also the functionality of these markers. The involvement of CD44 in invasion,adhesion,and metastasis,or the role of CD24 in modulation of src,FAK,and GLI1 are examples of these relevant roles. Instead of looking solely at the marker expression in these populations,we hope to clarify the biologically significant roles these markers and activities play in tumor progression,metastases,and as possible targets for therapy. View Publication

Inhibition of antigen-dependent B-cell receptor (BCR) signaling is considered a promising therapeutic approach in chronic lymphocytic leukemia (CLL),but experimental in vivo evidence to support this view is still lacking. We have now investigated whether inhibition of BCR signaling with the selective Syk inhibitor fostamatinib disodium (R788) will affect the growth of the leukemias that develop in the Eμ-TCL1 transgenic mouse model of CLL. Similarly to human CLL,these leukemias express stereotyped BCRs that react with autoantigens exposed on the surface of senescent or apoptotic cells,suggesting that they are antigen driven. We show that R788 effectively inhibits BCR signaling in vivo,resulting in reduced proliferation and survival of the malignant B cells and significantly prolonged survival of the treated animals. The growth-inhibitory effect of R788 occurs despite the relatively modest cytotoxic effect in vitro and is independent of basal Syk activity,suggesting that R788 functions primarily by inhibiting antigen-dependent BCR signals. Importantly,the effect of R788 was found to be selective for the malignant clones,as no disturbance in the production of normal B lymphocytes was observed. Collectively,these data provide further rationale for clinical trials with R788 in CLL and establish the BCR-signaling pathway as an important therapeutic target in this disease. View Publication

Chemical compounds have emerged as powerful tools for modulating ESC functions and deriving induced pluripotent stem cells (iPSCs),but documentation of compound-induced efficient directed differentiation in human ESCs (hESCs) and human iPSC (hiPSCs) is limited. By screening a collection of chemical compounds,we identified compound C (also denoted as dorsomorphin),a protein kinase inhibitor,as a potent regulator of hESC and hiPSC fate decisions. Compound C suppresses mesoderm,endoderm,and trophoectoderm differentiation and induces rapid and high-efficiency neural conversion in both hESCs and hiPSCs,88.7% and 70.4%,respectively. Interestingly,compound C is ineffective in inducing neural conversion in mouse ESCs (mESCs). Large-scale kinase assay revealed that compound C targets at least seven transforming growth factor beta (TGF-β) superfamily receptors,including both type I and type II receptors,and thereby blocks both the Activin and bone morphogenesis protein (BMP) signaling pathways in hESCs. Dual inhibition of Activin and BMP signaling accounts for the effects of compound C on hESC differentiation and neural conversion. We also identified muscle segment homeobox gene 2 (MSX2) as a downstream target gene of compound C and a key signaling intermediate of the BMP pathway in hESCs. Our findings provide a single-step cost-effective method for efficient derivation of neural progenitor cells in adherent culture from human pluripotent stem cells. Therefore,it will be uniquely suitable for the production of neural progenitor cells in large scale and should facilitate the use of stem cells in drug screening and regenerative medicine and study of early human neural development. View Publication

Systemic lupus erythematosus (SLE) is characterized by increased vascular risk due to premature atherosclerosis independent of traditional risk factors. We previously proposed that IFN-α plays a crucial role in premature vascular damage in SLE. IFN-α alters the balance between endothelial cell apoptosis and vascular repair mediated by endothelial progenitor cells (EPCs) and myeloid circulating angiogenic cells (CACs). In this study,we demonstrate that IFN-α promotes an antiangiogenic signature in SLE and control EPCs/CACs,characterized by transcriptional repression of IL-1α and β,IL-1R1,and vascular endothelial growth factor A,and upregulation of IL-1R antagonist and the decoy receptor IL-1R2. IL-1β promotes significant improvement in the functional capacity of lupus EPCs/CACs,therefore abrogating the deleterious effects of IFN-α. The beneficial effects from IL-1 are mediated,at least in part,by increases in EPC/CAC proliferation,by decreases in EPC/CAC apoptosis,and by preventing the skewing of CACs toward nonangiogenic pathways. IFN-α induces STAT2 and 6 phosphorylation in EPCs/CACs,and JAK inhibition abrogates the transcriptional antiangiogenic changes induced by IFN-α in these cells. Immunohistochemistry of renal biopsies from patients with lupus nephritis,but not anti-neutrophil cytoplasmic Ab-positive vasculitis,showed this pathway to be operational in vivo,with increased IL-1R antagonist,downregulation of vascular endothelial growth factor A,and glomerular and blood vessel decreased capillary density,compared with controls. Our study introduces a novel putative pathway by which type I IFNs may interfere with vascular repair in SLE through repression of IL-1-dependent pathways. This could promote atherosclerosis and loss of renal function in this disease. View Publication

Hematopoiesis is tightly controlled by transcription regulatory networks,but how and when specific transcription factors control lineage commitment are still largely unknown. Within the hematopoietic stem cell (Lin(-)Sca-1(+)c-Kit(+)) compartment these lineage-specific transcription factors are expressed at low levels but are up-regulated with the process of lineage specification. CCAAT/enhancer binding protein α (C/EBPα) represents one of these factors and is involved in myeloid development and indispensable for formation of granulocytes. To track the cellular fate of stem and progenitor cells,which express C/EBPα,we developed a mouse model expressing Cre recombinase from the Cebpa promoter and a conditional EYFP allele. We show that Cebpa/EYFP(+) cells represent a significant subset of multipotent hematopoietic progenitors,which predominantly give rise to myeloid cells in steady-state hematopoiesis. C/EBPα induced a strong myeloid gene expression signature and down-regulated E2A-induced regulators of early lymphoid development. In addition,Cebpa/EYFP(+) cells compose a fraction of early thymic progenitors with robust myeloid potential. However,Cebpa/EYFP(+) multipotent hematopoietic progenitors and early thymic progenitors retained the ability to develop into erythroid and T-lymphoid lineages,respectively. These findings support an instructive but argue against a lineage-restrictive role of C/EBPα in multipotent hematopoietic and thymic progenitors. View Publication

Human natural killer (NK) cells express an abundant level of 2B4 and CD2 on their surface. Their counter-receptors,CD48 and CD58,are also expressed on the NK cell surface,raising a question about the functional consequences of potential 2B4/CD48 and CD2/CD58 interactions. Using blocking antibodies specific to each receptor,we demonstrated that both 2B4/CD48 and CD2/CD58 interactions were essential for the development of NK effector functions: cytotoxicity and cytokine secretion. However,only 2B4/CD48,but not CD2/CD58,interactions were shown to be critical for the optimal NK cell proliferation in response to interleukin (IL)-2. IL-2-activated NK cells cultured in the absence of 2B4/CD48 or CD2/CD58 interactions were severely impaired for their ability to induce intracellular calcium mobilization and subsequent ERK activation upon tumor target exposure,suggesting that the early signaling pathway of NK receptors leading to impaired cytolysis and interferon (IFN)-γ secretion was inhibited. Nevertheless,these defects did not fully account for the reduced proliferation of NK cells in the absence of 2B4/CD48 interactions,because anti-CD2 or anti-CD58 monoclonal antibody (mAb)-treated NK cells,showing defective signaling and effector functions,displayed normal proliferation upon IL-2 stimulation. These results propose the signaling divergence between pathways leading to cell proliferation and cytotoxicity/cytokine release,which can be differentially regulated by 2B4 and CD2 during IL-2-driven NK cell activation. Collectively,these results reveal the importance of homotypic NK-to-NK cell cross-talk through 2B4/CD48 and CD2/CD58 pairs and further present their differential and overlapping roles in human NK cells. View Publication

The nonreceptor tyrosine kinase c-Src is frequently over-expressed or hyperactivated in various human cancers and contributes to cancer progression in cooperation with up-regulated growth factor receptors. However,Src-selective anticancer drugs are still in clinical trials. To identify more effective inhibitors of c-Src-mediated cancer progression,we developed a new screening platform using Csk-deficient cells that can be transformed by c-Src. We found that purvalanol A,developed as a CDK inhibitor,potently suppressed the anchorage-independent growth of c-Src-transformed cells,indicating that the activation of CDKs contributes to the c-Src transformation. We also found that purvalanol A suppressed the c-Src activity as effectively as the Src-selective inhibitor PP2,and that it reverted the transformed morphology to a nearly normal shape with less cytotoxicity than PP2. Purvalanol A induced a strong G2-M arrest,whereas PP2 weakly acted on the G1-S transition. Furthermore,when compared with PP2,purvalanol A more effectively suppressed the growth of human colon cancer HT29 and SW480 cells,in which Src family kinases and CDKs are activated. These findings demonstrate that the coordinated inhibition of cell cycle progression and tyrosine kinase signaling by the multi-selective purvalanol A is effective in suppressing cancer progression associated with c-Src up-regulation. View Publication

Combined analyses of gene networks and DNA sequence variation can provide new insights into the aetiology of common diseases that may not be apparent from genome-wide association studies alone. Recent advances in rat genomics are facilitating systems-genetics approaches. Here we report the use of integrated genome-wide approaches across seven rat tissues to identify gene networks and the loci underlying their regulation. We defined an interferon regulatory factor 7 (IRF7)-driven inflammatory network (IDIN) enriched for viral response genes,which represents a molecular biomarker for macrophages and which was regulated in multiple tissues by a locus on rat chromosome 15q25. We show that Epstein-Barr virus induced gene 2 (Ebi2,also known as Gpr183),which lies at this locus and controls B lymphocyte migration,is expressed in macrophages and regulates the IDIN. The human orthologous locus on chromosome 13q32 controlled the human equivalent of the IDIN,which was conserved in monocytes. IDIN genes were more likely to associate with susceptibility to type 1 diabetes (T1D)-a macrophage-associated autoimmune disease-than randomly selected immune response genes (P = 8.85 × 10(-6)). The human locus controlling the IDIN was associated with the risk of T1D at single nucleotide polymorphism rs9585056 (P = 7.0 × 10(-10); odds ratio,1.15),which was one of five single nucleotide polymorphisms in this region associated with EBI2 (GPR183) expression. These data implicate IRF7 network genes and their regulatory locus in the pathogenesis of T1D. View Publication

Two critical concerns in clinical cord blood transplantation are the initial time to engraftment and the subsequent restoration of immune function. These studies measured the impact of progenitor cell dose on both the pace and strength of hematopoietic reconstitution by transplanting nonobese diabetic/severe combined immunodeficiency/interleukin-2 receptor-gamma-null (NSγ) mice with lineage-depleted aldehyde dehydrogenase-bright CD34(+) human cord blood progenitors. The progress of each transplant was monitored over an extended time course by repeatedly analyzing the peripheral blood for human hematopoietic cells. In vivo human hematopoietic development was complete. After long-term transplantation assays (≥ 19 weeks),human T-cell development was documented within multiple tissues in 16 of 32 NSγ mice. Human T-cell differentiation was active within NSγ thymuses,as documented by the presence of CD4(+) CD8(+) T-cell progenitors as well as T-cell receptor excision circles. It is important to note that although myeloid and B-cell engraftment was detected as early as 4 weeks after transplantation,human T-cell development was exclusively late onset. High progenitor cell doses were associated with a robust human hematopoietic chimerism that accelerated both initial time to engraftment and subsequent T-cell development. At lower progenitor cell doses,the chimerism was weak and the human hematopoietic lineage development was frequently incomplete. View Publication