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慢性缺氧会损害 DNA 双链断裂的修复,从而导致遗传不稳定性。

Chronic hypoxia compromises repair of DNA double-strand breaks to drive genetic instability.

机构信息

Ontario Cancer Institute, Princess Margaret Hospital (University Health Network), Toronto, Ontario, Canada.

出版信息

J Cell Sci. 2012 Jan 1;125(Pt 1):189-99. doi: 10.1242/jcs.092262. Epub 2012 Jan 20.

DOI:10.1242/jcs.092262
PMID:22266907
Abstract

Hypoxic cells have been linked to genetic instability and tumor progression. However, little is known about the exact relationship between DNA repair and genetic instability in hypoxic cells. We therefore tested whether the sensing and repair of DNA double-strand breaks (DNA-dsbs) is altered in irradiated cells kept under continual oxic, hypoxic or anoxic conditions. Synchronized G0-G1 human fibroblasts were irradiated (0-10 Gy) after initial gassing with 0% O(2) (anoxia), 0.2% O(2) (hypoxia) or 21% O(2) (oxia) for 16 hours. The response of phosphorylated histone H2AX (γ-H2AX), phosphorylated ataxia telangiectasia mutated [ATM(Ser1981)], and the p53 binding protein 1 (53BP1) was quantified by intranuclear DNA repair foci and western blotting. At 24 hours following DNA damage, residual γ-H2AX, ATM(Ser1981) and 53BP1 foci were observed in hypoxic cells. This increase in residual DNA-dsbs under hypoxic conditions was confirmed using neutral comet assays. Clonogenic survival was also reduced in chronically hypoxic cells, which is consistent with the observation of elevated G1-associated residual DNA-dsbs. We also observed an increase in the frequency of chromosomal aberrations in chronically hypoxic cells. We conclude that DNA repair under continued hypoxia leads to decreased repair of G1-associated DNA-dsbs, resulting in increased chromosomal instability. Our findings suggest that aberrant DNA-dsb repair under hypoxia is a potential factor in hypoxia-mediated genetic instability.

摘要

缺氧细胞与遗传不稳定性和肿瘤进展有关。然而,对于 DNA 修复与缺氧细胞遗传不稳定性之间的确切关系知之甚少。因此,我们检测了在持续有氧、缺氧或无氧条件下照射的细胞中,DNA 双链断裂(DNA-dsbs)的感应和修复是否发生改变。同步化的 G0-G1 人成纤维细胞在初始用 0% O2(缺氧)、0.2% O2(缺氧)或 21% O2(氧)充气 16 小时后进行照射(0-10 Gy)。通过核内 DNA 修复焦点和蛋白质印迹法来定量磷酸化组蛋白 H2AX(γ-H2AX)、磷酸化 ataxia telangiectasia 突变(ATM(Ser1981))和 p53 结合蛋白 1(53BP1)的反应。在 DNA 损伤后 24 小时,在缺氧细胞中观察到残留的 γ-H2AX、ATM(Ser1981)和 53BP1 焦点。使用中性彗星测定法证实了缺氧条件下残留的 DNA-dsbs 的增加。慢性缺氧细胞的克隆存活能力也降低,这与观察到的 G1 相关残留 DNA-dsbs 增加一致。我们还观察到慢性缺氧细胞中染色体畸变的频率增加。我们得出结论,持续缺氧下的 DNA 修复导致 G1 相关 DNA-dsbs 的修复减少,从而导致染色体不稳定性增加。我们的发现表明,缺氧下异常的 DNA-dsb 修复是缺氧介导遗传不稳定性的潜在因素。

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