另一个干细胞生态位:慢性髓系白血病细胞对甲磺酸伊马替尼的敏感性如何在“缺氧”环境中被调节

E. Rovida, Ilaria Marzi, M. Cipolleschi, P. Dello Sbarba
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引用次数: 20

摘要

这是一个回顾(绝不是全面的)干细胞生态位如何从一个抽象的概念演变成一个复杂的系统,在细胞和分子水平上实现了一些实验数据,包括代谢线索,我们特别关注。该概念于1978年提出,用于模拟适合宿主造血干细胞(hsc)的骨髓部位,并促进其自我更新,同时抑制克隆扩增和分化。低氧张力对体外HSC维持的影响的研究使我们假设壁龛位于骨髓内氧张力低于其他地方的区域。我们将这些区域命名为缺氧干细胞龛,尽管对于维持造血干细胞的环境来说,低氧张力被认为是生理上的。造血干细胞后来被证明可以在低氧条件下循环,这使得这种循环能够维持干细胞的潜能。在白血病细胞群(包括慢性髓性白血病(CML))中也检测到能够耐受极低氧孵育的细胞亚群。在这些亚群中,致癌的Bcr/Abl蛋白被完全抑制,而Bcr/Abl信使核糖核酸则没有,这表明抗低氧的CML细胞在培养过程中不依赖于Bcr/Abl,但仍具有遗传性白血病。因此,在低氧条件下选择的CML白血病干细胞对Bcr/Abl抑制剂甲磺酸伊马替尼是难治的。Bcr/Abl蛋白的抑制实际上是在葡萄糖短缺和低氧作用共同作用时确定的,这表明缺血样条件是白血病干细胞对甲磺酸伊马替尼难耐的驱动因素。这些研究指出,“缺血”干细胞壁龛是维持CML最小残留疾病的一种新情况。讨论了“缺血”与“缺氧”干细胞生态位之间可能的功能关系。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
One more stem cell niche: how the sensitivity of chronic myeloid leukemia cells to imatinib mesylate is modulated within a “hypoxic” environment
This is a review (by no means comprehensive) of how the stem cell niche evolved from an abstract concept to a complex system, implemented with a number of experimental data at the cellular and molecular levels, including metabolic cues, on which we focused in particular. The concept was introduced in 1978 to model bone marrow sites suited to host hematopoietic stem cells (HSCs) and favor their self-renewal, while restraining clonal expansion and commitment to differentiation. Studies of the effects of low oxygen tension on HSC maintenance in vitro led us to hypothesize niches were located within bone marrow areas where oxygen tension is lower than elsewhere. We named these areas hypoxic stem cell niches, although a low oxygen tension is to be considered physiological for the environment where HSCs are maintained. HSCs were later shown to have the option of cycling in low oxygen, which steers this cycling to the maintenance of stem cell potential. Cell subsets capable of withstanding incubation in very low oxygen were also detected within leukemia cell populations, including chronic myeloid leukemia (CML). The oncogenetic Bcr/Abl protein is completely suppressed in these subsets, whereas Bcr/Abl messenger ribonucleic acid is not, indicating that CML cells resistant to low oxygen are independent of Bcr/Abl for persistence in culture but remain genetically leukemic. Accordingly, leukemia stem cells of CML selected in low oxygen are refractory to the Bcr/Abl inhibitor imatinib mesylate. Bcr/Abl protein suppression turned out to be actually determined when glucose shortage complicated the effects of low oxygen, indicating that ischemia-like conditions are the driving force of leukemia stem cell refractoriness to imatinib mesylate. These studies pointed to “ischemic” stem cell niches as a novel scenario for the maintenance of minimal residual disease of CML. A possible functional relationship of the “ischemic” with the “hypoxic” stem cell niche is discussed.
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