The elements of stem cell self-renewal: a genetic perspective

Every day, the body produces billions of new blood cells. Each of these is derived from a rare cell in the bone marrow called the hematopoietic stem cell (HSC). Because most mature blood cells have a limited lifespan, the ability of HSCs to self-renew and replenish the mature cell compartment is critical to sustaining life. While great progress has been made in isolating HSCs and defining their functional and phenotypic characteristics, the molecular mechanisms that regulate their self-renewal remain a mystery. Over the last few years, alterations in HSC frequency and self-renewal capacity in transgenic and knock-out mice have led to the identification of novel mediators of HSC homeostasis in vivo. These genetically modified mice have revealed that maintenance of survival, proliferation, quiescence, and normal telomere length all contribute to the self-renewal of HSCs. They also highlight the need to test in context of the normal microenvironment the role of signaling molecules such as Notch and Wnt, which have emerged recently as important regulators of HSC self-renewal. The emerging picture these data provide of the regulation of self-renewal in HSCs has provided a better understanding of the basic biology of stem cells and holds promise for designing strategies to improve bone marrow transplantation.     

Synergistic use of adult and embryonic stem cells to study human hematopoiesis

Embryonic stem cells (ESCs) and adult stem cells both provide important resources to define the mechanisms of hematopoietic cell development. To date, studies that utilize hematopoietic stem cells (HSCs) isolated from sites such as bone marrow or umbilical cord blood have been the primary means to identify molecular and phenotypic characteristics of blood cell populations able to mediate long-term hematopoietic engraftment. Although these HSCs are very useful clinically, they are difficult to expand in culture. Now, basic research on human ESCs provides opportunities for novel investigations into the mechanisms of HSC self-renewal. Eventually, the long history of basic and clinical research with adult hematopoietic cell transplantation could translate to establish human ESCs as a suitable alternative starting cell source for clinical hematopoietic reconstitution.     

造血干细胞生物学——研究与展望

造血干细胞（hematopoietic stem cell,HSC）是目前研究方法最为多样、研究技术手段最为成熟的一类组织干细胞,并且已经被成功运用于临床上对白血病以及先天性免疫缺陷等疾病的治疗。近年来,通过对一系列“转基因”与“基因敲除”小鼠模型的分析,人们对造血干细胞在胚胎早期发育过程中的发生与起源、造血干细胞“自我更新”与“定向分化”的调节机制、骨髓中造血干细胞的微环境（niche）对造血干细胞功能维持的调控,以及造血干细胞与白血病干细胞之间的相互关系等诸多方面都取得了很大的进展。如何实现造血干细胞的体外长期培养与扩增,实现胚胎干细胞（embryonic stem cell,ESC）或诱导多能干细胞（induced pluripotent stem cell,iPS细胞）向造血干细胞进行有效的定向分化,以及探索造血干细胞在病理状态（如癌症、贫血、衰老等）或应激状态下（如炎症与感染、组织损伤、代谢异常等）的功能变化,都将会是今后造血干细胞研究的重要方向。     

Identification of a hierarchy of multipotent hematopoietic progenitors in human cord blood

Mouse hematopoiesis is initiated by long-term hematopoietic stem cells (HSC) that differentiate into a series of multipotent progenitors that exhibit progressively diminished self-renewal ability. In human hematopoiesis, populations enriched for HSC activity have been identified, as have downstream lineage-committed progenitors, but multipotent progenitor activity has not been uniquely isolated. Previous reports indicate that human HSC are enriched in Lin-CD34+CD38- cord blood and bone marrow and express CD90. We demonstrate that the Lin-CD34+CD38- fraction of cord blood and bone marrow can be subdivided into three subpopulations: CD90+CD45RA-, CD90-CD45RA-, and CD90-CD45RA+. Utilizing in vivo transplantation studies and complementary in vitro assays, we demonstrate that the Lin-CD34+CD38-CD90+CD45RA- cord blood fraction contains HSC and isolate this activity to as few as 10 purified cells. Furthermore, we report the first prospective isolation of a population of candidate human multipotent progenitors, Lin-CD34+CD38-CD90-CD45RA- cord blood.     

Piwi Genes Are Dispensable for Normal Hematopoiesis in Mice

Hematopoietic stem cells (HSC) must engage in a life-long balance between self-renewal and differentiation to sustain hematopoiesis. The highly conserved PIWI protein family regulates proliferative states of stem cells and their progeny in diverse organisms. A Human piwi gene (for clarity, the non-italicized “piwi” refers to the gene subfamily), HIWI (PIWIL1), is expressed in CD34⁺ stem/progenitor cells and transient expression of HIWI in a human leukemia cell line drastically reduces cell proliferation, implying the potential function of these proteins in hematopoiesis. Here, we report that one of the three piwi genes in mice, Miwi2 (Piwil4), is expressed in primitive hematopoetic cell types within the bone marrow. Mice with a global deletion of all three piwi genes, Miwi, Mili, and Miwi2, are able to maintain long-term hematopoiesis with no observable effect on the homeostatic HSC compartment in adult mice. The PIWI-deficient hematopoetic cells are capable of normal lineage reconstitution after competitive transplantation. We further show that the three piwi genes are dispensable during hematopoietic recovery after myeloablative stress by 5-FU. Collectively, our data suggest that the function of the piwi gene subfamily is not required for normal adult hematopoiesis.     

Hematopoietic stem cells

Considerable effort has been made in recent years in defining the embryonic origin of the hematopoietic stem cell (HSC). Using transgenic mouse models, a number of genes that regulate the formation, self-renewal, or differentiation of HSCs have been identified. Of particular interest, it has recently been shown that key regulators of definitive blood formation played a crucial role in adult HSC development. Specifically, the use of some of these regulatory molecules has dramatically improved the potential of adult HSC expansion. Furthermore, the elucidation of the molecular phenotype of the HSC has just begun. Finally, unexpected degrees of HSC developmental or differentiation plasticity have emerged. In this review, we will summarize the recent advances made in the human HSC field, and we will examine the impacts these discoveries may have clinically and on our understanding of the organization of the human hematopoietic system.     

Deciphering the hierarchy of angiohematopoietic progenitors from human pluripotent stem cells

Identification of sequential progenitors leading to blood formation from pluripotent stem cells (PSCs) will be essential for understanding the molecular mechanisms of hematopoietic lineage specification and for development of technologies for in vitro production of hematopoietic stem cells (HSCs). It is well established that during development, blood and endothelial cells in the extraembryonic and embryonic compartments are formed in parallel from precursors with angiogenic and hematopoietic potentials. However, the identity and hierarchy of these precursors in human PSC (hPSC) cultures remain obscure. Using developmental stage-specific mesodermal and endothelial markers and functional assays, we recently identified discrete populations of angiohematopoietic progenitors from hPSCs, including mesodermal precursors and hemogenic endothelial cells with primitive and definitive hematopoietic potentials. In addition, we discovered a novel population of multipotent hematopoietic progenitors with an erythroid phenotype, which retain angiogenic potential. Here we introduce our recent findings and discuss their implication for defining putative HSC precursor and factors required for activation of self-renewal potential in hematopoietic cells emerging from endothelium.     

Purification and functional assay of pluripotent hematopoietic stem cells

Hematolymphopoietic stem cells (HSC) have the capacity for extensive self-renewal and pluripotent myelolymphoid differentiation. Recent studies have emphasized the heterogeneity of human HSC subsets in terms of proliferative and self-renewal capacity. In the NOD-SCID (nonobese diabetic-severe combined immunodeficient) mouse xenograft assay, most CD34+38- stem cell clones proliferate at early times, but then disappear, whereas only few clones persist: possibly, the latter ones consist of long-term engrafting CD34+38- HSC expressing the KDR receptor (i.e. the vascular endothelial growth factor receptor II). In this regard, isolation of the small KDR+ subset from the CD34+ hematopoietic progenitors (and possibly from the CD34-lin- population) may provide a novel and effective approach for the purification of long-term proliferating HSC. More importantly, KDR+ HSC isolation will pave the way to cellular/molecular characterization and improved functional manipulation of HSC/HSC subsets, as well as to innovative approaches for HSC clinical utilization, specifically transplantation, transfusion medicine and gene therapy.