Cell-surface markers on haemopoietic precursors. Reagents for the isolation and analysis of progenitor cell subpopulations

Within the last decade, major advances have been made in the analysis of cell-surface marker expression on haemopoietic progenitor cells as a result of the development of multiparameter cell sorting and monoclonal antibody techniques. Although some controversy exists with regard to the actual identification of the stem cell, markers specific for CFU-s and for particular subsets of progenitor cells have not yet been identified. An analysis of cell-surface markers on haemopoietic progenitor cells is complicated by at least three factors. First, it appears that, in mice, the clonal assays do not adequately identify the haemopoietic stem cell. Complete repopulation of all haemopoietic cell compartments in vivo over an extended period of time appears to be the only reliable method for identifying such a cell. Secondly cell-surface marker distribution on haemopoietic progenitors from normal tissues may be indicative of the cycling status of cells. Thus, expression of markers on progenitors from bone marrow or foetal liver which have been perturbed by drugs or viruses may merely reflect a change in their cycling status following drug or viral insult. Thirdly, substantial loss of cells occurs during the purification of particular cell types. For most cell separation procedures, only a minor proportion of the progenitor cells of interest are recovered and these may not be representative of the progenitor population as a whole. During differentiation to mature cells, antigenic determinants present on early progenitor cells may either be progressively lost or amplified. This differential expression of cell-surface molecules has provided a useful tool for the substantial enrichment of haemopoietic subsets, particularly CFU-E and CFU-s. To date, however, most early haemopoietic progenitor cells detected by in vitro CFC assays (day 8 CFC) cannot be completely segregated from one another. The ability to distinguish between such progenitors during the early stages of lineage commitment would provide a more detailed understanding of the relationship between lymphoid precursors, myeloid precursors and stem cells, and would lead to significant advances in developmental biology. Separation of cells at different stages of differentiation within a given lineage would provide an opportunity for studying regulatory mechanisms involved in gene expression in normal cell populations.     

Premature expression of the macrophage colony-stimulating factor receptor on a multipotential stem cell line does not alter differentiation lineages controlled by stromal cells used for coculture

We are interested to know whether expression of a lineage-specific growth factor receptor is deterministic to lineage commitment during hematopoiesis. For this purpose, we introduced the human c-fms gene into the multipotential stem cell clone LyD9 and two myeloid progenitor clones, L-GM3 and L-G3, cells that differentiate in response to granulocyte/macrophage colony-stimulating factor (GM-CSF) and granulocyte (G)-CSF, respectively. Although LyD9 cells have differentiation potential to become macrophages, c-fms transfectants of LyD9 and L-GM3 cells did not differentiate in response to human macrophage (M)-CSF. However, c-fms transfectants of L-G3 cells differentiated to neutrophils in response to human M-CSF. These results indicate that the M-CSF receptor requires a specific signal transduction pathway to exert its differentiational and proliferative effects. Furthermore, the M-CSF receptor can convey a granulocyte-type differentiation signal possibly by cooperating with the G-CSF receptor signal transduction pathway. The c-fms-transfected LyD9 cells as well as the original LyD9 cells differentiated predominantly into GM-CSF- and G-CSF-responsive cells by coculturing with PA6 and ST2 stromal cells, respectively. The results indicate that differentiation lineage is not affected by premature expression of the M-CSF receptor. Instead, the stromal cell used for coculture apparently controls lineage-selective differentiation of the multi-potential stem cell line.     

Exploitation of stem cell plasticity

For many years, adult haemopoietic stem cells (HSCs) have been considered 'plastic' in their proliferative and differentiation capacities. Recently, evidence that supports newer concepts of adult stem cell plasticity has been reported. In particular, stem cells from haemopoietic tissues seem to have 'extraordinary' abilities to generate or switch between haemopoietic and nonhaemopoietic lineages, exhibiting an unexpected degree of developmental or differentiation potential. The mechanisms by which cell fate reprogramming occurs are still poorly understood. Nevertheless, an increasing number of studies is challenging one of the main dogmas in biology, namely that mammalian cell differentiation follows established programmes in a hierarchical fashion, and once committed to a particular somatic cell lineage, cells do not change into another somatic lineage. The 'nonhierarchical', 'reversible' phenotype of stem cells in haemopoietic tissues, if it exists, would be an advantage that could be exploited in regenerative medicine. Here, we review the recent advances in HSC biology and discuss the general concepts of adult stem cell plasticity with respect to these cells and how these might be exploited clinically.     

Haematopoietic and osteogenic bone marrow stem cells

This article discusses the concept of a common stem cell for bone marrow stromal cells and haematopoietic cells. Until recently it was generally accepted that bone marrow contains two types of stem cells. One is the haemopoietic stem cell; the second one, the mesenchymal stem cell or stromal stem cell, gives rise to the stromal compartment of the marrow. The mesenchymal stem cells can differentiate into osteoblasts, chondroblasts, adipocytes, fibroblasts, and smooth muscle cells. Although the interplay between haemopoietic and stromal cells is well established, no transition of cells from the haemopoietic compartment into cells of the stromal compartment has been demonstrated. Recent data, based on grafting of genetically-marked haemopoietic cells points to the possibility of the generation of adipocytes from haemopoietic stem cells. These findings support the hypothesis postulating a common precursor cell for both bone and bone marrow.There is evidence that osteoblasts can differentiate into adipocytes, and that mesenchymal cells derived from subcutaneous adipose tissue can differentiate into osteogenic cells. The possibility of transdifferentiation of adipocytes into osteoblasts has also been demonstrated.     

Stem cells: what's happening? Current concepts and recent advances

Allogeneic haemopoietic stem cells, as alternative to bone marrow transplantation and platelet therapy remains the focus of the current area of research/development in transfusion science/medicine. This brief progress report on "Stem Cells: What's Happening?" is focused on the advances and some unresolved problems associated with cellular therapy and haemopoietic progenitor cells from various sources.     

Asymmetrical lymphoid and myeloid lineage commitment in multipotent hematopoietic progenitors

The mechanism of lineage commitment from hematopoietic stem cells (HSCs) is not well understood. Although commitment to either the lymphoid or the myeloid lineage is popularly viewed as the first step of lineage restriction from HSCs, this model of hematopoietic differentiation has recently been challenged. The previous identification of multipotent progenitors (MPPs) that can produce lymphocytes and granulocyte/macrophages (GMs) but lacks erythroid differentiation ability suggests the existence of an alternative HSC differentiation program. Contribution to different hematopoietic lineages by these MPPs under physiological conditions, however, has not been carefully examined. In this study, we performed a refined characterization of MPPs by subfractionating three distinct subsets based on Flt3 and vascular cell adhesion molecule 1 expression. These MPP subsets differ in their ability to give rise to erythroid and GM lineage cells but are equally potent in lymphoid lineage differentiation in vivo. The developmental hierarchy of these MPP subsets demonstrates the sequential loss of erythroid and then GM differentiation potential during early hematopoiesis. Our results suggest that the first step of lineage commitment from HSCs is not simply a selection between the lymphoid and the myeloid lineage.     

Interest of cord blood stem cells.

Interest in cord blood stem cells was raised because of the possibility, now realised, of their use in clinical transplantation. The availability of only limited numbers of stem cells in cord blood compared to bone marrow or peripheral blood apheresis after cell mobilisation, led to experimental approaches that first aimed to characterise and then manipulate the stem cells present in cord blood. Their phenotypical and functional characteristics are not identical to those of stem cells in the bone marrow or those cells mobilised into the circulation. The cells selected for phenotype plus Go status show the higher capacity to generate progenitor cells in vitro and will offer the opportunity for mechanistic studies of stem cell self-renewal and proliferation. Another important field of exploration is to investigate the capacity of stem cells in cord blood for differentiation to tissues other than haemopoietic and to establish whether haemopoietic and non-haemopoietic lineages originate in truly multipotential cells or in cells coexisting in cord blood, which have already been limited to differentiation into specific tissue.     

Myelodysplasia-associated autoimmunity: clinical and pathophysiologic concepts

Myelodysplastic syndrome (MDS), an acquired clonal disorder of haemopoietic progenitor cells, is characterized by haemopoietic insufficiency associated with cytopenias, leading to serious morbidity plus the additional risk of leukaemic transformation. In MDS an acquired insult to the haemopoietic stem cell leads to impaired differentiation and myelodysplasia. However, there is increasing evidence that the marrow failure of MDS is immune-mediated. A model of MDS pathophysiology suggests that transformation of normal stem cells induces an autoimmune T-cell response with the bone marrow as the target organ. This autoimmune attack results in chronic overproduction of pro-apoptotic cytokines, especially tumour necrosis factor alpha (TNFalpha). In addition, several reports have revealed that approximately 10% of MDS patients have clinical autoimmune disorders. This review illustrates the cellular/molecular mechanisms and the implication of the tumour suppressor gene interferon regulatory factor-1 (IRF-1) in the pathophysiology of MDS-associated autoimmune deregulation.     

Maintenance of T cell specification and differentiation requires recurrent notch receptor-ligand interactions

Notch signaling has been shown to play a pivotal role in inducing T lineage commitment. However, T cell progenitors are known to retain other lineage potential long after the first point at which Notch signaling is required. Thus, additional requirements for Notch signals and the timing of these events relative to intrathymic differentiation remain unknown. Here, we address this issue by culturing subsets of CD4 CD8 double negative (DN) thymocytes on control stromal cells or stromal cells expressing Delta-like 1 (Dll1). All DN subsets were found to require Notch signals to differentiate into CD4+ CD8+ T cells. Using clonal analyses, we show that CD44+ CD25+ (DN2) cells, which appeared committed to the T cell lineage when cultured on Dll1-expressing stromal cells, nonetheless gave rise to natural killer cells with a progenitor frequency similar to that of CD44+ CD25- (DN1) thymocytes when Notch signaling was absent. These data, together with the observation that Dll1 is expressed on stromal cells throughout the thymic cortex, indicates that Notch receptor-ligand interactions are necessary for induction and maintenance of T cell lineage specification at both the DN1 and DN2 stages of T cell development, suggesting that the Notch-induced repression of the B cell fate is temporally separate from Notch-induced commitment to the T lineage.     

Therapeutic potential of adult progenitor cells in cardiovascular disease

Cardiovascular diseases are responsible for high morbidity/mortality rates worldwide. Advances in patient care have significantly reduced deaths from acute myocardial infarction. However, the cardiac remodeling processes induced after ischaemia are responsible for a worsening in the heart condition, which in many cases ends up in failure. In the last decade, a novel therapy based on stem cell transplantation is being intensively studied in animal models and some stem cell types (i.e., skeletal myoblasts and bone marrow-derived cells) are already being tested in clinical trials. A novel stem cell population isolated from the bone marrow, termed multipotent adult progenitor cells was characterised a few years ago by its ability to differentiate, at the single cell level, towards cells derived from the three embryonic germ layers. Later on, other pluripotent cell populations have been also derived from the bone marrow. In this overview, the authors outline different stem cell sources that have been tested for their cardiovascular potential and put the regenerative potential of multipotent adult progenitor cells in animal models of acute and chronic myocardial infarction into perspective.     

Therapeutic potential of adult progenitor cells in cardiovascular disease

Cardiovascular diseases are responsible for high morbidity/mortality rates worldwide. Advances in patient care have significantly reduced deaths from acute myocardial infarction. However, the cardiac remodeling processes induced after ischaemia are responsible for a worsening in the heart condition, which in many cases ends up in failure. In the last decade, a novel therapy based on stem cell transplantation is being intensively studied in animal models and some stem cell types (i.e., skeletal myoblasts and bone marrow-derived cells) are already being tested in clinical trials. A novel stem cell population isolated from the bone marrow, termed multipotent adult progenitor cells was characterised a few years ago by its ability to differentiate, at the single cell level, towards cells derived from the three embryonic germ layers. Later on, other pluripotent cell populations have been also derived from the bone marrow. In this overview, the authors outline different stem cell sources that have been tested for their cardiovascular potential and put the regenerative potential of multipotent adult progenitor cells in animal models of acute and chronic myocardial infarction into perspective.     

Origin of endothelial progenitors in human postnatal bone marrow

This study demonstrates that a CD34(-), vascular endothelial cadherin(-) (VE-cadherin(-)), AC133(+), and fetal liver kinase(+) (Flk1(+)) multipotent adult progenitor cell (MAPC) that copurifies with mesenchymal stem cells from postnatal human bone marrow (BM) is a progenitor for angioblasts. In vitro, MAPCs cultured with VEGF differentiate into CD34(+), VE-cadherin(+), Flk1(+) cells - a phenotype that would be expected for angioblasts. They subsequently differentiate into cells that express endothelial markers, function in vitro as mature endothelial cells, and contribute to neoangiogenesis in vivo during tumor angiogenesis and wound healing. This in vitro model of preangioblast-to-endothelium differentiation should prove very useful in studying commitment to the angioblast and beyond. In vivo, MAPCs can differentiate in response to local cues into endothelial cells that contribute to neoangiogenesis in tumors. Because MAPCs can be expanded in culture without obvious senescence for more than 80 population doublings, they may be an important source of endothelial cells for cellular pro- or anti-angiogenic therapies.     

Notch信号通路与间充质干细胞分化

间充质干细胞(MSC)是具有多向分化能力的成体干细胞,在体外培养中可以被诱导分化为骨、软骨、脂肪、肌肉细胞;另外,MSC也可跨系分化为神经细胞、心肌细胞、肝脏细胞等多种其他组织细胞。Notch信号通路广泛存在于各种动物细胞中,在调节细胞分化、增殖和凋亡中发挥重要作用,它的配体和受体都是细胞膜表面蛋白,因此是介导细胞间通讯的一种重要方式。现有研究表明:在MSC多条分化途径中都有Notch通路存在。本文针对Notch信号通路在MSC分化中的影响做一综述。     

Keystone symposia - stem cells

The Keystone Symposia stem cell conference focused on the biological nature of self-renewing cell populations that exist in special regulatory niches and form other cell types that enable maintenance of tissue function, repair and, in some cases, regeneration. Adult stem cells are present in most, if not all tissues, and their regulation as renewing populations, the nature of the niche and the factors driving decisions for differentiation in primary pathways remain the dominant interest in the field. The more vexed question concerning possible transdifferentiation of adult stem cells from one tissue type to another has become focused on the role of fusion and whether this is a recapitulation of normal processes in embryonic and adult development. The possible linkage of cancer phenotypes with stem cells and downstream progenitor cell types through loss of regulatory influences in renewal, expansion and lineage commitment is a rapidly growing interest. Pluripotent embryonic stem (ES) cells and their maintenance and directed differentiation into a variety of tissue types remains an optimistic field of research in which some debate exists about true pluripotency of adult stem cells. The role of epigenetic influences on differentiation and development has drawn on data from nuclear transfer studies in cloning the whole organism and in ES cell production. The formation of germ cells and their renewal and differentiation was also a major interest of the symposium.     

Evidence that gammadelta versus alphabeta T cell fate determination is initiated independently of T cell receptor signaling

Two types of T cells, alphabeta and gammadelta, develop in vertebrates. How these two T cell lineages arise from a common thymic T progenitor is poorly understood. Differentiation of alphabeta lineage T cells requires the surrogate alpha chain (pTalpha), which associates with the T cell receptor (TCR) beta chain to form the pre-TCR. gammadelta lineage development does not appear to involve an obligatory surrogate chain, but instead requires productive rearrangement and expression of both TCR gamma and delta genes. It has been proposed that the quality of signals transmitted by the pre-TCR and gammadelta TCR are distinct and that these "instructive" signals determine the lineage fate of an uncommitted progenitor cell. Here we show that the thymic T progenitor cells (CD25(+)CD44(+)c-kit(+)CD3(-)CD4(-)CD8(-) thymocytes, termed pro-T cells) from young adult mice that have yet to express TCRs can be subdivided based on interleukin 7 receptor (IL-7R) expression. These subsets exhibit differential potential to develop into gammadelta versus alphabeta lineage (CD4+CD8+ cells) in the thymus. Upon intrathymic injection, IL-7R(neg-lo) pro-T cells generated a 13-fold higher ratio of alphabeta lineage to gammadelta lineage cells than did IL-7R(+) pro-T cells. Much of this difference was due to a fivefold greater potential of IL-7R(+) pro-T cells to develop into TCR-gammadelta T cells. Evidence indicates that this biased developmental potential is not a result of enhanced TCR-gamma gene rearrangement/expression in IL-7R(+) pro-T cells. These results indicate that the pro-T cells are heterogeneous in developmental potential before TCR gene rearrangement and suggest that in some precursor cells the initial lineage commitment is independent of TCR-mediated signals.     

Separation of Notch1 promoted lineage commitment and expansion/transformation in developing T cells.

Notch1 signaling is required for T cell development. We have previously demonstrated that expression of a dominant active Notch1 (ICN1) transgene in hematopoietic stem cells (HSCs) leads to thymic-independent development of CD4(+)CD8(+) double-positive (DP) T cells in the bone marrow (BM). To understand the function of Notch1 in early stages of T cell development, we assessed the ability of ICN1 to induce extrathymic T lineage commitment in BM progenitors from mice that varied in their capacity to form a functional pre-T cell receptor (TCR). Whereas mice repopulated with ICN1 transduced HSCs from either recombinase deficient (Rag-2(-/)-) or Src homology 2 domain--containing leukocyte protein of 76 kD (SLP-76)(-/)- mice failed to develop DP BM cells, recipients of ICN1-transduced Rag-2(-/)- progenitors contained two novel BM cell populations indicative of pre-DP T cell development. These novel BM populations are characterized by their expression of CD3 epsilon and pre-T alpha mRNA and the surface proteins CD44 and CD25. In contrast, complementation of Rag-2(-/)- mice with a TCR beta transgene restored ICN1-induced DP development in the BM within 3 wk after BM transfer (BMT). At later time points, this population selectively and consistently gave rise to T cell leukemia. These findings demonstrate that Notch signaling directs T lineage commitment from multipotent progenitor cells; however, both expansion and leukemic transformation of this population are dependent on T cell-specific signals associated with development of DP thymocytes.     

Animal xenograft models for evaluation of gene transfer into human hematopoietic stem cells

Animal xenograft models of gene therapy have become increasingly popular to study the effects of various transduction strategies on human hematopoietic stem cells (HSC). Xenograft models provide an in vivo setting in which to monitor the duration and effects of vector expression in the progeny of the transduced stem and progenitor cells. Also, the ability of HSC to home to the bone marrow and differentiate into multilineage progeny following ex vivo manipulation can only be tested in a transplantation system. The current review will discuss the murine xenograft models that have been used recently to determine optimized methods for gene transfer into normal human hematopoietic stem cells.     

Derivation and Characterization of Hepatic Progenitor Cells from Human Embryonic Stem Cells

The derivation of hepatic progenitor cells from human embryonic stem (hES) cells is of value both in the study of early human liver organogenesis and in the creation of an unlimited source of donor cells for hepatocyte transplantation therapy. Here, we report for the first time the generation of hepatic progenitor cells derived from hES cells. Hepatic endoderm cells were generated by activating FGF and BMP pathways and were then purified by fluorescence activated cell sorting using a newly identified surface marker, N-cadherin. After co-culture with STO feeder cells, these purified hepatic endoderm cells yielded hepatic progenitor colonies, which possessed the proliferation potential to be cultured for an extended period of more than 100 days. With extensive expansion, they co-expressed the hepatic marker AFP and the biliary lineage marker KRT7 and maintained bipotential differentiation capacity. They were able to differentiate into hepatocyte-like cells, which expressed ALB and AAT, and into cholangiocyte-like cells, which formed duct-like cyst structures, expressed KRT19 and KRT7, and acquired epithelial polarity. In conclusion, this is the first report of the generation of proliferative and bipotential hepatic progenitor cells from hES cells. These hES cell–derived hepatic progenitor cells could be effectively used as an in vitro model for studying the mechanisms of hepatic stem/progenitor cell origin, self-renewal and differentiation.