技术资料

Forced expression of MN1 in primitive mouse hematopoietic cells causes acute myeloid leukemia and impairs all-trans retinoic acid-induced granulocytic differentiation. Here,we studied the effects of MN1 on myeloid differentiation and proliferation using primary human CD34(+) hematopoietic cells,lineage-depleted mouse bone marrow cells,and bipotential (granulocytic/monocytic) human acute myeloid leukemia cell lines. We show that exogenous MN1 stimulated the growth of CD34(+) cells,which was accompanied by enhanced survival and increased cell cycle traverse in cultures supporting progenitor cell growth. Forced MN1 expression impaired both granulocytic and monocytic differentiation in vitro in primary hematopoietic cells and acute myeloid leukemia cell lines. Endogenous MN1 expression was higher in human CD34(+) cells compared with both primary and in vitro-differentiated monocytes and granulocytes. Microarray and real-time reverse-transcribed polymerase chain reaction analysis of MN1-overexpressing CD34(+) cells showed down-regulation of CEBPA and its downstream target genes. Reintroduction of conditional and constitutive CEBPA overcame the effects of MN1 on myeloid differentiation and inhibited MN1-induced proliferation in vitro. These results indicate that down-regulation of CEBPA activity contributes to MN1-modulated proliferation and impaired myeloid differentiation of hematopoietic cells. View Publication

The development of embryonic stem cell (ESC) therapies requires the establishment of efficient methods to differentiate ESCs into specific cell lineages. Here,we report the in vitro differentiation of common marmoset (CM) (Callithrix jacchus) ESCs into hematopoietic cells after exogenous gene transfer using vesicular stomatitis virus-glycoprotein-pseudotyped lentiviral vectors. We transduced hematopoietic genes,including tal1/scl,gata1,gata2,hoxB4,and lhx2,into CM ESCs. By immunochemical and morphological analyses,we demonstrated that overexpression of tal1/scl,but not the remaining genes,dramatically increased hematopoiesis of CM ESCs,resulting in multiple blood-cell lineages. Furthermore,flow cytometric analysis demonstrated that CD34,a hematopoietic stem/progenitor cell marker,was highly expressed in tal1/scl-overexpressing embryoid body cells. Similar results were obtained from three independent CM ESC lines. These results suggest that transduction of exogenous tal1/scl cDNA into ESCs is a promising method to induce the efficient differentiation of CM ESCs into hematopoietic stem/progenitor cells. View Publication

SALL4,a human homolog to Drosophila spalt,is a novel zinc finger transcriptional factor essential for development. We cloned SALL4 and its isoforms (SALL4A and SALL4B). Through immunohistochemistry and real-time reverse-transcription-polymerase chain reaction (RT-PCR),we demonstrated that SALL4 was constitutively expressed in human primary acute myeloid leukemia (AML,n = 81),and directly tested the leukemogenic potential of constitutive expression of SALL4 in a murine model. SALL4B transgenic mice developed myelodysplastic syndrome (MDS)-like features and subsequently AML that was transplantable. Increased apoptosis associated with dysmyelopoiesis was evident in transgenic mouse marrow and colony-formation (CFU) assays. Both isoforms could bind to beta-catenin and synergistically enhanced the Wnt/beta-catenin signaling pathway. Our data suggest that the constitutive expression of SALL4 causes MDS/AML,most likely through the Wnt/beta-catenin pathway. Our murine model provides a useful platform to study human MDS/AML transformation,as well as the Wnt/beta-catenin pathway's role in the pathogenesis of leukemia stem cells. View Publication

Kinase domain (KD) mutations of Bcr-Abl interfering with imatinib binding are the major mechanism of acquired imatinib resistance in patients with Philadelphia chromosome-positive leukemia. Mutations of the ATP binding loop (p-loop) have been associated with a poor prognosis. We compared the transformation potency of five common KD mutants in various biological assays. Relative to unmutated (native) Bcr-Abl,the ATP binding loop mutants Y253F and E255K exhibited increased transformation potency,M351T and H396P were less potent,and the performance of T315I was assay dependent. The transformation potency of Y253F and M351T correlated with intrinsic Bcr-Abl kinase activity,whereas the kinase activity of E255K,H396P,and T315I did not correlate with transforming capabilities,suggesting that additional factors influence transformation potency. Analysis of the phosphotyrosine proteome by mass spectroscopy showed differential phosphorylation among the mutants,a finding consistent with altered substrate specificity and pathway activation. Mutations in the KD of Bcr-Abl influence kinase activity and signaling in a complex fashion,leading to gain- or loss-of-function variants. The drug resistance and transformation potency of mutants may determine the outcome of patients on therapy with Abl kinase inhibitors. View Publication

This study was designed to investigate one component of the Wnt/beta-catenin signaling pathway that has been implicated in stem cell self-renewal. Retroviral-mediated introduction of stable beta-catenin to primitive murine bone marrow cells allowed the expansion of multipotential c-Kit(low)Sca-1(low/-)CD19(-) CD11b/Mac-1(-)Flk-2(-)CD43(+)AA4.1(+)NK1.1(-)CD3(-)CD11c(-)Gr-1(-)CD45R/B220(+) cells in the presence of stromal cells and cytokines. They generated myeloid,T,and B lineage lymphoid cells in culture,but had no T lymphopoietic potential when transplanted. Stem cell factor and IL-6 were found to be minimal requirements for long-term,stromal-free propagation,and a beta-catenin-transduced cell line was maintained for 5 mo with these defined conditions. Although multipotential and responsive to many normal stimuli in culture,it was unable to engraft several types of irradiated recipients. These findings support previous studies that have implicated the canonical Wnt pathway signaling in regulation of multipotent progenitors. In addition,we demonstrate how it may be experimentally manipulated to generate valuable cell lines. View Publication

The Notch1-RBP-Jkappa and the transcription factor Runx1 pathways have been independently shown to be indispensable for the establishment of definitive hematopoiesis. Importantly,expression of Runx1 is down-regulated in the para-aortic splanchnopleural (P-Sp) region of Notch1- and Rbpsuh-null mice. Here we demonstrate that Notch1 up-regulates Runx1 expression and that the defective hematopoietic potential of Notch1-null P-Sp cells is successfully rescued in the OP9 culture system by retroviral transfer of Runx1. We also show that Hes1,a known effector of Notch signaling,potentiates Runx1-mediated transactivation. Together with the recent findings in zebrafish,Runx1 is postulated to be a cardinal down-stream mediator of Notch signaling in hematopoietic development throughout vertebrates. Our findings also suggest that Notch signaling may modulate both expression and transcriptional activity of Runx1. View Publication

Mouse embryonic fibroblasts (MEFs) deficient for pocket proteins (i.e.,pRB/p107-,pRB/p130-,or pRB/p107/p130-deficient MEFs) have lost proper G(1) control and are refractory to Ras(V12)-induced senescence. However,pocket protein-deficient MEFs expressing Ras(V12) were unable to exhibit anchorage-independent growth or to form tumors in nude mice. We show that depending on the level of pocket proteins,loss of adhesion induces G(1) and G(2) arrest,which could be alleviated by overexpression of the TBX2 oncogene. TBX2-induced transformation occurred only in the absence of pocket proteins and could be attributed to downregulation of the p53/p21(CIP1) pathway. Our results show that a balance between the pocket protein and p53 pathways determines the level of transformation of MEFs by regulating cyclin-dependent kinase activities. Since transformation of human fibroblasts also requires ablation of both pathways,our results imply that the mechanisms underlying transformation of human and mouse cells are not as different as previously claimed. View Publication

Reduced microcirculation and diminished expression of growth factors contribute to wound healing impairment in diabetes. Placenta growth factor (PlGF),an angiogenic mediator promoting pathophysiological neovascularization,is expressed during cutaneous wound healing and improves wound closure by enhancing angiogenesis. By using streptozotocin-induced diabetic mice,we here demonstrate that PlGF induction is strongly reduced in diabetic wounds. Diabetic transgenic mice overexpressing PlGF in the skin displayed accelerated wound closure compared with diabetic wild-type littermates. Moreover,diabetic wound treatment with an adenovirus vector expressing the human PlGF gene (AdCMV.PlGF) significantly accelerated the healing process compared with wounds treated with a control vector. The analysis of treated wounds showed that PlGF gene transfer improved granulation tissue formation,maturation,and vascularization,as well as monocytes/macrophages local recruitment. Platelet-derived growth factor,fibroblast growth factor-2,and vascular endothelial growth factor mRNA levels were increased in AdCMV.PlGF-treated wounds,possibly enhancing PlGF-mediated effects. Finally,PlGF treatment stimulated cultured dermal fibroblast migration,pointing to a direct role of PlGF in accelerating granulation tissue maturation. In conclusion,our data indicate that reduced PlGF expression contributes to impaired wound healing in diabetes and that PlGF gene transfer to diabetic wounds exerts therapeutic activity by promoting different aspects of the repair process. View Publication

The complex hematopoietic effects of placental growth factor (PlGF) prompted us to test in mice and nonhuman primates the mobilization of peripheral blood progenitor cells (PBPCs) elicited by recombinant mouse PlGF-2 (rmPlGF-2) and recombinant human PlGF-1 (rhPlGF-1). PBPC mobilization was evaluated by assaying colony-forming cells (CFCs),high-proliferative potential-CFCs (HPP-CFCs),and long-term culture-initiating cells (LTC-ICs). In mice,both rmPlGF-2 and rhPlGF-1 used as single agents failed to mobilize PBPCs,whereas the combination of rhPlGF-1 and granulocyte colony-stimulating factor (rhG-CSF) increased CFCs and LTC-ICs per milliliter of blood by four- and eightfold,respectively,as compared with rhG-CSF alone. rhPlGF-1 plus rhG-CSF significantly increased matrix metalloproteinase-9 plasma levels over rhG-CSF alone,suggesting a mechanistic explanation for rhPlGF-1/rhG-CSF synergism. In rhesus monkeys,rhPlGF-1 alone had no mobilization effect,whereas rhPlGF-1 (260 microg/kg per day) plus rhG-CSF (100 microg/kg per day) increased rhG-CSF-elicited mobilization of CFCs,HPP-CFCs,and LTC-ICs per milliliter of blood by 5-,7-,and 15-fold,respectively. No specific toxicity was associated with the administration of rhPlGF-1 alone or in combination. In conclusion,our data demonstrate that rhPlGF-1 significantly increases rhG-CSF-elicited hematopoietic mobilization and provide a preclinical rationale for evaluating rhPlGF-1 in the clinical setting. View Publication

Megakaryocytopoiesis gives rise to platelets by proliferation and differentiation of lineage-specific progenitors,identified in vitro as Colony Forming Unit-Megakaryocytes (CFU-Mk). The aim of this study was to refine and optimize the in vitro Standard Operating Procedure (SOP) of the CFU-Mk assay for detecting drug-induced thrombocytopenia and to prevalidate a model for predicting the acute exposure levels that cause maximum tolerated decreases in the platelets count,based on the correlation with the maximal plasma concentrations (C max) in vivo. The assay was linear under the SOP conditions,and the in vitro endpoints (percentage of colonies growing) were reproducible within and across laboratories. The protocol performance phase was carried out testing 10 drugs (selected on the base of their recognised or potential in vivo haematotoxicity,according to the literature). Results showed that a relationship can be established between the maximal concentration in plasma (C max) and the in vitro concentrations that inhibited the 10-50-90 percent of colonies growth (ICs). When C max is lower than IC10,it is possible to predict that the chemicals have no direct toxicity effect on CFU-Mk and could not induce thrombocytopenia due to bone marrow damage. When the C max is higher than IC90 and/or IC50,thrombocytopenia can occur due to direct toxicity of chemicals on CFU-Mk progenitors. View Publication

Fanconi anemia (FA) is an inherited recessive DNA repair disorder mainly characterized by bone marrow failure and cancer predisposition. Studies in mosaic FA patients have shown that reversion of one inherited germ-line mutation resulting in a functional allele in one or a few hematopoietic stem cells (HSCs) can lead to the proliferation advantage of corrected cells,thus over time normalizing the hematologic status of the patient. In contrast to these observations,it is still unclear whether ex vivo genetic correction of FA HSCs also provides a similar proliferation advantage to FA HSCs. Using an FA mouse model with a marked hematopoietic phenotype,the FA-D1 (Brca2(Delta27/Delta27)) mice,we demonstrate that the lentivirus-mediated gene therapy of FA HSCs results in the progressive expansion of genetically corrected clones in mild-conditioned FA-D1 recipients. Consistent with these data,hematopoietic progenitors from FA recipients progressively became mitomycin C resistant and their chromosomal instability was reverted. No evidence of myelodysplasia,leukemias,or abnormal clonal repopulation was observed at multiple time points in primary or secondary recipients. Our results demonstrate that ectopic expression of BRCA2 confers a beneficial in vivo proliferation advantage to FA-D1 HSCs that enables the full hematopoietic repopulation of FA recipients with genetically corrected cells. View Publication

Splice-site mutations in the beta-globin gene can lead to aberrant transcripts and decreased functional beta-globin,causing beta-thalassemia. Triplex-forming DNA oligonucleotides (TFOs) and peptide nucleic acids (PNAs) have been shown to stimulate recombination in reporter gene loci in mammalian cells via site-specific binding and creation of altered helical structures that provoke DNA repair. We have designed a series of triplex-forming PNAs that can specifically bind to sequences in the human beta-globin gene. We demonstrate here that these PNAs,when cotransfected with recombinatory donor DNA fragments,can promote single base-pair modification at the start of the second intron of the beta-globin gene,the site of a common thalassemia-associated mutation. This single base pair change was detected by the restoration of proper splicing of transcripts produced from a green fluorescent protein-beta-globin fusion gene. The ability of these PNAs to induce recombination was dependent on dose,sequence,cell-cycle stage,and the presence of a homologous donor DNA molecule. Enhanced recombination,with frequencies up to 0.4%,was observed with use of the lysomotropic agent chloroquine. Finally,we demonstrate that these PNAs were effective in stimulating the modification of the endogenous beta-globin locus in human cells,including primary hematopoietic progenitor cells. This work suggests that PNAs can be effective tools to induce heritable,site-specific modification of disease-related genes in human cells. View Publication