Program in Immunology, Ludwig Center at Stanford, Institute of Stem Cell Biology and Regenerative Medicine, Stanford University School of Medicine, Stanford, California, USA.
Stem Cells. 2011 Nov;29(11):1774-82. doi: 10.1002/stem.719.
Hematopoietic stem cells (HSCs) must exhibit tight regulation of both self-renewal and differentiation to maintain homeostasis of the hematopoietic system as well as to avoid aberrations in growth that may result in leukemias or other disorders. In this study, we sought to understand the molecular basis of lineage determination, with particular focus on factors that influence megakaryocyte/erythrocyte-lineage commitment, in hematopoietic stem and progenitor cells. We used intracellular flow cytometry to identify two novel hematopoietic progenitor populations within the mouse bone-marrow cKit(+) Lineage (-) Sca1(+) (KLS) Flk2 (+) compartment that differ in their protein-level expression of GATA1, a critical megakaryocyte/erythrocyte-promoting transcription factor. GATA1-high repopulating cells exhibited the cell surface phenotype KLS Flk2(+ to int), CD150(int), CD105(+), cMPL(+), and were termed "FSE cells." GATA1-low progenitors were identified as KLS Flk2(+), CD150(-), and cMPL(-), and were termed "Flk(+) CD150(-) cells." FSE cells had increased megakaryocyte/platelet potential in culture and transplant settings and exhibited a higher clonal frequency of colony-forming unit-spleen activity compared with Flk(+) CD150(-) cells, suggesting functional consequences of GATA1 upregulation in promoting megakaryocyte and erythroid lineage priming. Activation of ERK and AKT signal-transduction cascades was observed by intracellular flow cytometry in long-term HSCs and FSE cells, but not in Flk(+) CD150(-) cells in response to stimulation with thrombopoietin, an important megakaryocyte-promoting cytokine. We provide a mechanistic rationale for megakaryocyte/erythroid bias within KLS Flk2(+) cells, and demonstrate how assessment of intracellular factors and signaling events can be used to refine our understanding of lineage commitment during early definitive hematopoiesis.
造血干细胞(HSCs)必须严格调控自我更新和分化,以维持造血系统的稳态,并避免生长异常,从而导致白血病或其他疾病。在这项研究中,我们试图了解谱系决定的分子基础,特别关注影响巨核细胞/红细胞谱系定向的因素,在造血干细胞和祖细胞中。我们使用细胞内流式细胞术来鉴定小鼠骨髓中 cKit(+)谱系(-)Sca1(+)(KLS)Flk2(+)区室中的两个新的造血祖细胞群体,它们在关键的巨核细胞/红细胞促进转录因子 GATA1 的蛋白水平表达上有所不同。GATA1 高重编程细胞表现出细胞表面表型 KLS Flk2(+到 int)、CD150(int)、CD105(+)、cMPL(+),并被称为“FSE 细胞”。GATA1 低祖细胞被鉴定为 KLS Flk2(+)、CD150(-)和 cMPL(-),并被称为“Flk(+)CD150(-)细胞”。FSE 细胞在培养和移植环境中具有增加的巨核细胞/血小板潜能,并且在集落形成单位-脾活性的克隆频率方面表现出更高的功能,这表明 GATA1 上调在促进巨核细胞和红细胞谱系启动方面的功能后果。通过细胞内流式细胞术观察到 ERK 和 AKT 信号转导级联在长期 HSCs 和 FSE 细胞中的激活,但在 Flk(+)CD150(-)细胞中未观察到,这是对血小板生成素的刺激,血小板生成素是一种重要的巨核细胞促进细胞因子。我们为 KLS Flk2(+)细胞中的巨核细胞/红细胞偏倚提供了一种机制基础,并证明了如何评估细胞内因子和信号事件,以细化我们对早期定型造血过程中的谱系定向的理解。
