技术资料

Human embryonic stem (hES) cells show an atypical cell-cycle regulation characterized by a high proliferation rate and a short G1 phase. In fact,a shortened G1 phase might protect ES cells from external signals inducing differentiation,as shown for certain stem cells. It has been suggested that self-renewal and pluripotency are intimately linked to cell-cycle regulation in ES cells,although little is known about the overall importance of the cell-cycle machinery in maintaining ES cell identity. An appealing model to address whether the acquisition of stem cell properties is linked to cell-cycle regulation emerged with the ability to generate induced pluripotent stem (iPS) cells by expression of defined transcription factors. Here,we show that the characteristic cell-cycle signature of hES cells is acquired as an early event in cell reprogramming. We demonstrate that induction of cell proliferation increases reprogramming efficiency,whereas cell-cycle arrest inhibits successful reprogramming. Furthermore,we show that cell-cycle arrest is sufficient to drive hES cells toward irreversible differentiation. Our results establish a link that intertwines the mechanisms of cell-cycle control with the mechanisms underlying the acquisition and maintenance of ES cell identity. View Publication

Various combinations of antibodies directed to cell surface markers have been used to isolate human and rhesus macaque hematopoietic stem cells (HSCs). These protocols result in poor enrichment or require multiple complex steps. Recently,a simple phenotype for HSCs based on cell surface markers from the signaling lymphocyte activation molecule (SLAM) family of receptors has been reported in the mouse. We examined the possibility of using the SLAM markers to facilitate the isolation of highly enriched populations of HSCs in humans and rhesus macaques. We isolated SLAM (CD150(+)CD48(-)) and non-SLAM (not CD150(+)CD48(-)) cells from human umbilical cord blood CD34(+) cells as well as from human and rhesus macaque mobilized peripheral blood CD34(+) cells and compared their ability to form colonies in vitro and reconstitute immune-deficient (nonobese diabetic/severe combined immunodeficiency/interleukin-2 γc receptor(null),NSG) mice. We found that the CD34(+) SLAM population contributed equally or less to colony formation in vitro and to long-term reconstitution in NSG mice compared with the CD34(+) non-SLAM population. Thus,SLAM family markers do not permit the same degree of HSC enrichment in humans and rhesus macaques as in mice. View Publication

The identity of T-cell progenitors that seed the thymus has remained controversial,largely because many studies differ over whether these progenitors retain myeloid potential. Contradictory reports diverge in their use of various in vitro and in vivo assays. To consolidate these discordant findings,we compared the myeloid potential of 2 putative thymus seeding populations,common lymphoid progenitors (CLPs) and multipotent progenitors (MPPs),and the earliest intrathymic progenitor (DN1),using 2 in vitro assays and in vivo readouts. These assays gave contradictory results: CLP and DN1 displayed surprisingly robust myeloid potential on OP9-DL1 in vitro stromal cocultures but displayed little myeloid potential in vivo,as well as in methylcellulose cultures. MPP,on the other hand,displayed robust myeloid potential in all settings. We conclude that stromal cocultures reveal cryptic,but nonphysiologic,myeloid potentials of lymphoid progenitors,providing an explanation for contradictory findings in the field and underscoring the importance of using in vivo assays for the determination of physiologic lineage potentials. View Publication

The balance of bone morphogenic protein (BMP),transforming growth factor-β (TGFβ)/activin/nodal,and Wnt signals regulates the early lineage segregation of human embryonic stem cells (ESCs). Here we demonstrate that a combination of small-molecule inhibitors of BMP (Dorsomorphin) and TGFβ/activin/nodal (SB431542) signals promotes highly efficient neural induction from both human ESCs and induced pluripotent stem cells (iPSCs). The combination of small molecules had effects on both cell survival and purity of neural differentiation,under conditions of stromal (PA6) cell coculture and feeder-free floating aggregation culture,for all seven pluripotent stem cell lines that we studied,including three ESC and four iPSC lines. Small molecule compounds are stable and cost effective,so our findings provide a promising strategy for controlled production of neurons in regenerative medicine. View Publication

Cell-fate transitions involve the integration of genomic information encoded by regulatory elements,such as enhancers,with the cellular environment. However,identification of genomic sequences that control human embryonic development represents a formidable challenge. Here we show that in human embryonic stem cells (hESCs),unique chromatin signatures identify two distinct classes of genomic elements,both of which are marked by the presence of chromatin regulators p300 and BRG1,monomethylation of histone H3 at lysine 4 (H3K4me1),and low nucleosomal density. In addition,elements of the first class are distinguished by the acetylation of histone H3 at lysine 27 (H3K27ac),overlap with previously characterized hESC enhancers,and are located proximally to genes expressed in hESCs and the epiblast. In contrast,elements of the second class,which we term 'poised enhancers',are distinguished by the absence of H3K27ac,enrichment of histone H3 lysine 27 trimethylation (H3K27me3),and are linked to genes inactive in hESCs and instead are involved in orchestrating early steps in embryogenesis,such as gastrulation,mesoderm formation and neurulation. Consistent with the poised identity,during differentiation of hESCs to neuroepithelium,a neuroectoderm-specific subset of poised enhancers acquires a chromatin signature associated with active enhancers. When assayed in zebrafish embryos,poised enhancers are able to direct cell-type and stage-specific expression characteristic of their proximal developmental gene,even in the absence of sequence conservation in the fish genome. Our data demonstrate that early developmental enhancers are epigenetically pre-marked in hESCs and indicate an unappreciated role of H3K27me3 at distal regulatory elements. Moreover,the wealth of new regulatory sequences identified here provides an invaluable resource for studies and isolation of transient,rare cell populations representing early stages of human embryogenesis. View Publication

Chimeric oncoproteins resulting from fusion of MLL to a wide variety of partnering proteins cause biologically distinctive and clinically aggressive acute leukemias. However,the mechanism of MLL-mediated leukemic transformation is not fully understood. Dot1,the only known histone H3 lysine 79 (H3K79) methyltransferase,has been shown to interact with multiple MLL fusion partners including AF9,ENL,AF10,and AF17. In this study,we utilize a conditional Dot1l deletion model to investigate the role of Dot1 in hematopoietic progenitor cell immortalization by MLL fusion proteins. Western blot and mass spectrometry show that Dot1-deficient cells are depleted of the global H3K79 methylation mark. We find that loss of Dot1 activity attenuates cell viability and colony formation potential of cells immortalized by MLL oncoproteins but not by the leukemic oncoprotein E2a-Pbx1. Although this effect is most pronounced for MLL-AF9,we find that Dot1 contributes to the viability of cells immortalized by other MLL oncoproteins that are not known to directly recruit Dot1. Cells immortalized by MLL fusions also show increased apoptosis,suggesting the involvement of Dot1 in survival pathways. In summary,our data point to a pivotal requirement for Dot1 in MLL fusion protein-mediated leukemogenesis and implicate Dot1 as a potential therapeutic target. View Publication

Current treatment options for advanced and hormone refractory prostate cancer are limited and responses to commonly used androgen pathway inhibitors are often unsatisfactory. Our recent results indicated that sodium ionophore monensin is one of the most potent and cancer-specific inhibitors in a systematic sensitivity testing of most known drugs and drug-like molecules in a panel of prostate cancer cell models. Because monensin has been extensively used in veterinary applications to build muscle mass in cattle,the link to prostate cancer and androgen signaling was particularly interesting. Here,we showed that monensin effects at nanomolar concentrations are linked to induction of apoptosis and potent reduction of androgen receptor mRNA and protein in prostate cancer cells. Monensin also elevated intracellular oxidative stress in prostate cancer cells as evidenced by increased generation of intracellular reactive oxygen species and by induction of a transcriptional profile characteristic of an oxidative stress response. Importantly,the antiproliferative effects of monensin were potentiated by combinatorial treatment with the antiandrogens and antagonized by antioxidant vitamin C. Taken together,our results suggest monensin as a potential well-tolerated,in vivo compatible drug with strong proapoptotic effects in prostate cancer cells,and synergistic effects with antiandrogens. Moreover,our data suggest a general strategy by which the effects of antiandrogens could be enhanced by combinatorial administration with agents that increase oxidative stress in prostate cancer cells. View Publication

T-cell-mediated processes play an essential role in the pathogenesis of several inflammatory skin diseases such as atopic dermatitis,allergic contact dermatitis and psoriasis. The aim of this study was to investigate the role of the IL-2-inducible tyrosine kinase (Itk),an enzyme acting downstream of the T-cell receptor (TCR),in T-cell-dependent skin inflammation using three approaches. Itk knockout mice display significantly reduced inflammatory symptoms in mouse models of acute and subacute contact hypersensitivity (CHS) reactions. Systemic administration of a novel small molecule Itk inhibitor,Compound 44,created by chemical optimization of an initial high-throughput screening hit,inhibited Itk's activity with an IC50 in the nanomolar range. Compound 44 substantially reduced proinflammatory immune responses in vitro and in vivo after systemic administration in two acute CHS models. In addition,our data reveal that human Itk,comparable to its murine homologue,is expressed mainly in T cells and is increased in lesional skin from patients with atopic dermatitis and allergic contact dermatitis. Finally,silencing of Itk by RNA interference in primary human T cells efficiently blocks TCR-induced lymphokine secretion. In conclusion,Itk represents an interesting new target for the therapy of T-cell-mediated inflammatory skin diseases. View Publication

Maintenance of genomic integrity is essential for adult tissue homeostasis and defects in the DNA-damage response (DDR) machinery are linked to numerous pathologies including cancer. Here,we present evidence that the DDR exerts tumor suppressor activity in gliomas. We show that genes encoding components of the DDR pathway are frequently altered in human gliomas and that loss of elements of the ATM/Chk2/p53 cascade accelerates tumor formation in a glioma mouse model. We demonstrate that Chk2 is required for glioma response to ionizing radiation in vivo and is necessary for DNA-damage checkpoints in the neuronal stem cell compartment. Finally,we observed that the DDR is constitutively activated in a subset of human GBMs,and such activation correlates with regions of hypoxia. View Publication

BACKGROUND: The radiation-induced bystander effect" (RIBE) was shown to occur in a number of experimental systems both in vitro and in vivo as a result of exposure to ionizing radiation (IR). RIBE manifests itself by intercellular communication from irradiated cells to non-irradiated cells which may cause DNA damage and eventual death in these bystander cells. It is known that human stem cells (hSC) are ultimately involved in numerous crucial biological processes such as embryologic development; maintenance of normal homeostasis; aging; and aging-related pathologies such as cancerogenesis and other diseases. However� View Publication

Studies in embryonic development have guided successful efforts to direct the differentiation of human embryonic and induced pluripotent stem cells (PSCs) into specific organ cell types in vitro. For example,human PSCs have been differentiated into monolayer cultures of liver hepatocytes and pancreatic endocrine cells that have therapeutic efficacy in animal models of liver disease and diabetes,respectively. However,the generation of complex three-dimensional organ tissues in vitro remains a major challenge for translational studies. Here we establish a robust and efficient process to direct the differentiation of human PSCs into intestinal tissue in vitro using a temporal series of growth factor manipulations to mimic embryonic intestinal development. This involved activin-induced definitive endoderm formation,FGF/Wnt-induced posterior endoderm pattering,hindgut specification and morphogenesis,and a pro-intestinal culture system to promote intestinal growth,morphogenesis and cytodifferentiation. The resulting three-dimensional intestinal 'organoids' consisted of a polarized,columnar epithelium that was patterned into villus-like structures and crypt-like proliferative zones that expressed intestinal stem cell markers. The epithelium contained functional enterocytes,as well as goblet,Paneth and enteroendocrine cells. Using this culture system as a model to study human intestinal development,we identified that the combined activity of WNT3A and FGF4 is required for hindgut specification whereas FGF4 alone is sufficient to promote hindgut morphogenesis. Our data indicate that human intestinal stem cells form de novo during development. We also determined that NEUROG3,a pro-endocrine transcription factor that is mutated in enteric anendocrinosis,is both necessary and sufficient for human enteroendocrine cell development in vitro. PSC-derived human intestinal tissue should allow for unprecedented studies of human intestinal development and disease. View Publication

Although microbial infections can alter steady-state hematopoiesis,the mechanisms that drive such changes are not well understood. We addressed a role for IFN-γ signaling in infection-induced bone marrow suppression and anemia in a murine model of human monocytic ehrlichiosis,an emerging tick-borne disease. Within the bone marrow of Ehrlichia muris-infected C57BL/6 mice,we observed a reduction in myeloid progenitor cells,as defined both phenotypically and functionally. Infected mice exhibited a concomitant increase in developing myeloid cells within the bone marrow,an increase in the frequency of circulating monocytes,and an increase in splenic myeloid cells. The infection-induced changes in progenitor cell phenotype were critically dependent on IFN-γ,but not IFN-α,signaling. In mice deficient in the IFN-γ signaling pathway,we observed an increase in myeloid progenitor cells and CDllb(lo)Gr1(lo) promyelocytic cells within the bone marrow,as well as reduced frequencies of mature granulocytes and monocytes. Furthermore,E. muris-infected IFN-γR-deficient mice did not exhibit anemia or an increase in circulating monocytes,and they succumbed to infection. Gene transcription studies revealed that IFN-γR-deficient CDllb(lo)Gr1(lo) promyelocytes from E. muris-infected mice exhibited significantly reduced expression of irf-1 and irf-8,both key transcription factors that regulate the differentiation of granulocytes and monocytes. Finally,using mixed bone marrow chimeric mice,we show that IFN-γ-dependent infection-induced myelopoiesis occurs via the direct effect of the cytokine on developing myeloid cells. We propose that,in addition to its many other known roles,IFN-γ acts to control infection by directly promoting the differentiation of myeloid cells that contribute to host defense. View Publication