Liebermann D A, Hoffman B
Fels Institute for Cancer Research and Molecular Biology, Temple University, School of Medicine, Philadelphia, Pennsylvania 19140.
Stem Cells. 1994 Jul;12(4):352-69. doi: 10.1002/stem.5530120402.
By genetically manipulating hematopoietic cells of the myeloid lineage, including both normal cells and differentiation inducible leukemic cell lines, evidence was obtained to indicate that myeloid differentiation primary response (MyD) genes and proto-oncogenes, which are known to control cell growth, function as positive and negative regulators of terminal hematopoietic cell differentiation, which is associated with inhibition of cell growth, and, ultimately programmed cell death (apoptosis). Interferon regulatory factor-1 (IRF-1), an MyD gene induced by Interleukin 6 (IL-6) or Leukemia Inhibitory factor (LIF), plays a role in growth inhibition associated with terminal differentiation. Leucine zipper transcription factors of the fos/jun family, also identified as MyD genes, function as positive regulators of hematopoietic cell differentiation, increasing the propensity of myeloblastic leukemia cells to be induced for differentiation in vitro, and reducing the aggressiveness of their leukemic phenotype in vivo. The zinc finger transcription factor EGR-1, an MyD gene specifically induced upon macrophage differentiation, was shown to be essential for and to restrict differentiation along the macrophage lineage. Finally, evidence has been accumulating to indicate that the novel MyD genes--MyD116, MyD118 and gadd45 (a member in the MyD118 gene family)--play a role in growth arrest and apoptosis of hematopoietic cells, as well as other cell types. The proto-oncogenes c-myc and c-myb, known to regulate cellular growth, were shown to function as negative regulators of terminal differentiation. Both c-myc and c-myb are normally expressed in proliferating myeloblasts and suppressed following induction of differentiation. Deregulated and continuous expression of c-myc was shown to block terminal myeloid differentiation at an intermediate stage in the progression from immature blasts to mature macrophages, whereas deregulated and continuous expression of c-myb blocked the terminal differentiation program at the immature myeloblast stage. By manipulating myc function in conditional (differentiation inducible) mutant myeloblastic leukemia cell lines, expressing a chimeric mycer transgene, it was shown that there is a window during myeloid differentiation, after the addition of the differentiation inducer, when the terminal differentiation program switches from being dependent on c-myc suppression to becoming c-myc suppression independent, and where activation of c-myc has no apparent effect on mature macrophages. These myeloblastic leukemia cell lines provide a powerful tool to increase our understanding of the role of c-myc in normal hematopoiesis and in leukemogenesis, while also providing a strategy to clone myc target genes.(ABSTRACT TRUNCATED AT 250 WORDS)
通过对髓系血细胞进行基因操作,包括正常细胞和可诱导分化的白血病细胞系,获得的证据表明,已知控制细胞生长的髓系分化初级反应(MyD)基因和原癌基因,作为终末造血细胞分化的正负调节因子发挥作用,这与细胞生长抑制相关,最终导致程序性细胞死亡(凋亡)。干扰素调节因子1(IRF-1)是一种由白细胞介素6(IL-6)或白血病抑制因子(LIF)诱导的MyD基因,在与终末分化相关的生长抑制中发挥作用。fos/jun家族的亮氨酸拉链转录因子,也被鉴定为MyD基因,作为造血细胞分化的正调节因子发挥作用,增加了髓母细胞白血病细胞在体外被诱导分化的倾向,并降低了其白血病表型在体内的侵袭性。锌指转录因子EGR-1是一种在巨噬细胞分化时特异性诱导的MyD基因,已被证明对巨噬细胞谱系的分化至关重要,并限制其分化。最后,越来越多的证据表明,新的MyD基因——MyD116、MyD118和gadd45(MyD118基因家族的成员)——在造血细胞以及其他细胞类型的生长停滞和凋亡中发挥作用。已知调节细胞生长的原癌基因c-myc和c-myb,被证明作为终末分化的负调节因子发挥作用。c-myc和c-myb通常在增殖的髓母细胞中表达,在诱导分化后受到抑制。c-myc的失调和持续表达被证明在从幼稚母细胞到成熟巨噬细胞的进展的中间阶段阻断终末髓系分化,而c-myb的失调和持续表达在幼稚髓母细胞阶段阻断终末分化程序。通过在条件性(可诱导分化)突变髓母细胞白血病细胞系中操纵myc功能,该细胞系表达嵌合的mycer转基因,结果表明在髓系分化过程中,在添加分化诱导剂后,存在一个窗口期,此时终末分化程序从依赖c-myc抑制转变为不依赖c-myc抑制,并且c-myc的激活对成熟巨噬细胞没有明显影响。这些髓母细胞白血病细胞系为增进我们对c-myc在正常造血和白血病发生中的作用的理解提供了一个有力工具,同时也为克隆myc靶基因提供了一种策略。(摘要截短至250字)
