技术资料

Recently,a number of clinical trials used either mesenchymal stem cells (MSCs) or natural killer (NK) cells in an attempt to improve the effectiveness of hematopoietic stem cell transplantation (HSCT). In view of the relevant role of both MSCs and NK cells in HSCT,we have recently explored the result of possible interactions between the 2 cell types. We found that activated NK cells could kill MSCs,whereas MSCs strongly inhibited interleukin-2 (IL-2)-induced NK-cell proliferation. In this study,we further analyzed the inhibitory effect exerted by MSCs on NK cells. We show that MSCs not only inhibit the cytokine-induced proliferation of freshly isolated NK cells but also prevent the induction of effector functions,such as cytotoxic activity and cytokine production. Moreover,we show that this inhibitory effect is related to a sharp down-regulation of the surface expression of the activating NK receptors NKp30,NKp44,and NKG2D. Finally,we demonstrate that indoleamine 2,3-dioxygenase and prostaglandin E2 represent key mediators of the MSC-induced inhibition of NK cells. View Publication

Mesenchymal stem cells (MSC) establish close interactions with bone marrow sinusoids in a putative perivascular niche. These vessels contain a large storage pool of mature nonproliferating neutrophils. Here,we have investigated the effects of human bone marrow MSC on neutrophil survival and effector functions. MSC from healthy donors,at very low MSC:neutrophil ratios (up to 1:500),significantly inhibited apoptosis of resting and interleukin (IL)-8-activated neutrophils and dampened N-formyl-l-methionin-l-leucyl-l-phenylalanine (f-MLP)-induced respiratory burst. The antiapoptotic activity of MSC did not require cell-to-cell contact,as shown by transwell experiments. Antibody neutralization experiments demonstrated that the key MSC-derived soluble factor responsible for neutrophil protection from apoptosis was IL-6,which signaled by activating STAT-3 transcription factor. Furthermore,IL-6 expression was detected in MSC by real-time reverse transcription-polymerase chain reaction and enzyme-linked immunosorbent assay. Finally,recombinant IL-6 was found to protect neutrophils from apoptosis in a dose-dependent manner. MSC had no effect on neutrophil phagocytosis,expression of adhesion molecules,and chemotaxis in response to IL-8,f-MLP,or C5a. These results support the following conclusions: (a) in the bone marrow niche,MSC likely protect neutrophils of the storage pool from apoptosis,preserving their effector functions and preventing the excessive or inappropriate activation of the oxidative metabolism,and (b) a novel mechanism whereby the inflammatory potential of activated neutrophils is harnessed by inhibition of apoptosis and reactive oxygen species production without impairing phagocytosis and chemotaxis has been identified. View Publication

By assessing the contribution of deregulated E2F activity to erythroid defects in Rb null mice,we have identified E2f-2 as being upregulated in end-stage red cells,where we show it is the major pRb-associated E2f and the predominant E2f detected at key target gene promoters. Consistent with its expression pattern,E2f-2 loss restored terminal erythroid maturation to Rb null red cells,including the ability to undergo enucleation. Deletion of E2f-2 also extended the life span of Rb null mice despite persistent defects in placental development,indicating that deregulated E2f-2 activity in differentiating erythroblasts contributes to the premature lethality of Rb null mice. We show that the aberrant entry of Rb null erythroblasts into S phase at times in differentiation when wild-type erythroblasts are exiting the cell cycle is inhibited by E2f-2 deletion. E2f-2 loss induced cell cycle arrest in both wild-type and Rb null erythroblasts and was associated with increased DNA double-strand breaks. These results implicate deregulated E2f-2 in the cell cycle defects observed in Rb null erythroblasts and reveal a novel role for E2f-2 during terminal red blood cell differentiation. The identification of a tissue-restricted role for E2f-2 in erythropoiesis highlights the nonredundant nature of E2f transcription factor activities in cell growth and differentiation. View Publication

BACKGROUND: ALDH-bright (ALDH(br)) cell populations sorted from freshly collected umbilical cord blood (UCB) on the basis of their high aldehyde dehydrogenase (ALDH) activity are highly enriched for HPC. HPC with low ALDH activity (ALDH(dim)) are primarily short-term progenitors,whereas progenitors that initiate long-term cultures or establish long-term grafts in xenograft models are ALDH(br). We examined the multilineage hematopoietic and platelet progenitor activities of ALDH(br) cells recovered from cryopreserved UCB units typically employed in the practice of clinical transplantation. METHODS: Frozen UCB units were thawed,washed,immunomagnetically depleted of cells expressing glycophorin A and CD14,reacted for flow cytometric detection of ALDH,and sorted to yield ALDH(br) and ALDH(dim) populations. We measured surface Ag expression and viability of cells in the ALDH(br) and ALDH(dim) populations by flow cytometry and hematopoietic (CFC-H) and megakaryocytic (CFC-Mk) colony-forming cells in each population. RESULTS: ALDH(br) populations isolated from thawed UCB cells were highly enriched for CD34(+) and CD133(+) cells. Flow-sorted ALDH(br) populations were enriched 1116-fold in CFC-H,10-fold in multilineage GEMM colonies and 2015-fold in CFC-Mk compared with the ALDH(dim) population. All progenitors giving rise to large Mk colonies were derived from ALDH(br) populations. DISCUSSION: ALDH(br) populations recovered from thawed,banked UCB with the method we describe have HPC activity and may be useful in the clinic to facilitate reconstitution of erythroid,myeloid and megakaryocytic blood elements. View Publication

The mechanisms that regulate hematopoietic stem cell (HSC) fate decisions between proliferation and multilineage differentiation are unclear. Members of the Wnt family of ligands that activate the canonical Wnt signaling pathway,which utilizes beta-catenin to relay the signal,have been demonstrated to regulate HSC function. In this study,we examined the role of noncanonical Wnt signaling in regulating HSC fate. We observed that noncanonical Wnt5a inhibited Wnt3a-mediated canonical Wnt signaling in HSCs and suppressed Wnt3a-mediated alterations in gene expression associated with HSC differentiation,such as increased expression of myc. Wnt5a increased short- and long-term HSC repopulation by maintaining HSCs in a quiescent G(0) state. From these data,we propose that Wnt5a regulates hematopoiesis by the antagonism of the canonical Wnt pathway,resulting in a pool of quiescent HSCs. View Publication

The mechanisms underlying deregulation of HOX gene expression in AML are poorly understood. The ParaHox gene CDX2 was shown to act as positive upstream regulator of several HOX genes. In this study,constitutive expression of Cdx2 caused perturbation of leukemogenic Hox genes such as Hoxa10 and Hoxb8 in murine hematopoietic progenitors. Deletion of the N-terminal domain of Cdx2 abrogated its ability to perturb Hox gene expression and to cause acute myeloid leukemia (AML) in mice. In contrast inactivation of the putative Pbx interacting site of Cdx2 did not change the leukemogenic potential of the gene. In an analysis of 115 patients with AML,expression levels of CDX2 were closely correlated with deregulated HOX gene expression. Patients with normal karyotype showed a 14-fold higher expression of CDX2 and deregulated HOX gene expression compared with patients with chromosomal translocations such as t(8:21) or t(15;17). All patients with AML with normal karyotype tested were negative for CDX1 and CDX4 expression. These data link the leukemogenic potential of Cdx2 to its ability to dysregulate Hox genes. They furthermore correlate the level of CDX2 expression with HOX gene expression in human AML and support a potential role of CDX2 in the development of human AML with aberrant Hox gene expression. View Publication

The histo-blood group i and I antigens have been characterized as straight and branched repeats of N-acetyllactosamine,respectively,and the conversion of the straight-chain i to the branched-chain I structure on red cells is regulated to occur after birth. It has been demonstrated that the human I locus expresses 3 IGnT transcripts,IGnTA,IGnTB,and IGnTC,and that the last of these is responsible for the I branching formation on red cells. In the present investigation,the K-562 cell line was used as a model to show that the i-to-I transition in erythroid differentiation is determined by the transcription factor CCAAT/enhancer binding protein alpha (C/EBPalpha),which enhances transcription of the IGnTC gene,consequently leading to formation of the I antigen. Further investigation suggested that C/EBPalpha IGnTC-activation activity is modulated at a posttranslational level,and that the phosphorylation status of C/EBPalpha may have a crucial effect. Results from studies using adult and cord erythropoietic cells agreed with those derived using the K-562 cell model,with lentiviral expression of C/EBPalpha in CD34(+) hemopoietic cells demonstrating the determining role of C/EBPalpha in the induction of the IGnTC gene as well as in I antigen expression. View Publication

Normal prion protein (PrP(c)),an essential substrate for development of prion disease,is widely distributed in hematopoietic cells. Recent evidence that variant Creutzfeldt-Jakob disease can be transmitted by transfusion of red cell preparations has highlighted the need for a greater understanding of the biology of PrP(c) in blood and blood-forming tissues. Here,we show that in contrast to another glycosylphosphoinositol-anchored protein CD59,PrP(c) at the cell surface of cultured human erythroblasts is rapidly internalized through the endosomal pathway,where it colocalizes with the tetraspanin CD63. In the plasma membrane,PrP(c) colocalizes with the tetraspanin CD81. Cross-linking with anti-PrP(c) or anti-CD81 causes clustering of PrP(c) and CD81,suggesting they can share the same microdomain. These data are consistent with a role for tetraspanin-enriched microdomains in trafficking of PrP(c). These results,when taken together with recent evidence that exosomes released from cells as a result of endosomal-mediated recycling to the plasma membrane contain prion infectivity,provide a pathway for the propagation of prion diseases. View Publication

The transcription factor Runx1/AML1 is an important regulator of hematopoiesis and is critically required for the generation of the first definitive hematopoietic stem cells (HSCs) in the major vasculature of the mouse embryo. As a pivotal factor in HSC ontogeny,its transcriptional regulation is of high interest but is largely undefined. In this study,we used a combination of comparative genomics and chromatin analysis to identify a highly conserved 531-bp enhancer located at position + 23.5 in the first intron of the 224-kb mouse Runx1 gene. We show that this enhancer contributes to the early hematopoietic expression of Runx1. Transcription factor binding in vivo and analysis of the mutated enhancer in transient transgenic mouse embryos implicate Gata2 and Ets proteins as critical factors for its function. We also show that the SCL/Lmo2/Ldb-1 complex is recruited to the enhancer in vivo. Importantly,transplantation experiments demonstrate that the intronic Runx1 enhancer targets all definitive HSCs in the mouse embryo,suggesting that it functions as a crucial cis-regulatory element that integrates the Gata,Ets,and SCL transcriptional networks to initiate HSC generation. View Publication

Specific mutations in the human gene encoding the Wiskott-Aldrich syndrome protein (WASp) that compromise normal auto-inhibition of WASp result in unregulated activation of the actin-related protein 2/3 complex and increased actin polymerizing activity. These activating mutations are associated with an X-linked form of neutropenia with an intrinsic failure of myelopoiesis and an increase in the incidence of cytogenetic abnormalities. To study the underlying mechanisms,active mutant WASp(I294T) was expressed by gene transfer. This caused enhanced and delocalized actin polymerization throughout the cell,decreased proliferation,and increased apoptosis. Cells became binucleated,suggesting a failure of cytokinesis,and micronuclei were formed,indicative of genomic instability. Live cell imaging demonstrated a delay in mitosis from prometaphase to anaphase and confirmed that multinucleation was a result of aborted cytokinesis. During mitosis,filamentous actin was abnormally localized around the spindle and chromosomes throughout their alignment and separation,and it accumulated within the cleavage furrow around the spindle midzone. These findings reveal a novel mechanism for inhibition of myelopoiesis through defective mitosis and cytokinesis due to hyperactivation and mislocalization of actin polymerization. View Publication

We show here that the process of megakaryocytic differentiation requires the presence of the recently discovered protein tescalcin. Tescalcin is dramatically upregulated during the differentiation and maturation of primary megakaryocytes or upon PMA-induced differentiation of K562 cells. This upregulation requires sustained signaling through the ERK pathway. Overexpression of tescalcin in K562 cells initiates events of spontaneous megakaryocytic differentiation,such as expression of specific cell surface antigens,inhibition of cell proliferation,and polyploidization. Conversely,knockdown of this protein in primary CD34+ hematopoietic progenitors and cell lines by RNA interference suppresses megakaryocytic differentiation. In cells lacking tescalcin,the expression of Fli-1,Ets-1,and Ets-2 transcription factors,but not GATA-1 or MafB,is blocked. Thus,tescalcin is essential for the coupling of ERK cascade activation with the expression of Ets family genes in megakaryocytic differentiation. View Publication

Human embryonic stem cells,because of their unique combination of long-term self-renewal properties and pluripotency,are providing new avenues of investigation of stem cell biology and human development and show promise in providing a new source of human cells for transplantation therapies and pharmaceutical testing. Current methods of propagating these cells using combinations of mouse fibroblast feeder cultures and bovine serum components are inexpensive and,in general,useful. However,the systematic investigation of the regulation of self-renewal and the production of safer sources of cells for transplantation depends on the elimination of animal products and the use of defined culture conditions. Both goals are served by the development of serum-free culture methods for human embryonic stem cells. View Publication