Roig Andres I, Hight Suzie K, Shay Jerry W
University of Texas Southwestern Medical Center at Dallas, Dallas, TX, USA.
Radiat Res. 2009 Jan;171(1):33-40. doi: 10.1667/RR1415.1.
Astronauts may be at an increased risk for developing colorectal cancer after a prolonged interplanetary mission given the potential for greater carcinogenic effects of radiation to the colon. In addition, with an increase in age, there is a greater incidence of premalignant colon adenomas with age. In the present study, we have compared the effects of radiation on human colon epithelial cells in two-dimensional (2D) monolayer culture, in three-dimensional (3D) culture, and in intact human colon tissue biopsies. Immortalized colon epithelial cells were irradiated at the NASA Space Radiation Laboratory (NSRL) with either 1 Gy 1 GeV/nucleon (56)Fe particles or 1 Gy 1 GeV/nucleon protons and were stained at various times to assess DNA damage and repair responses. The results show more persisting damage at 24 h with iron-particle radiation compared to protons. Similar results were seen in 3D colon epithelial cell cultures in which (56)Fe-particle-irradiated specimens show more persisting damage at 24 h than those irradiated with low-LET gamma rays. We compared these results to those obtained from human colon tissue biopsies irradiated with 1 Gy gamma rays or 1 Gy 1 GeV (56)Fe particles. Observations of radiation-induced DNA damage and repair in gamma-irradiated specimens revealed more pronounced early DNA damage responses in the epithelial cell compartment compared to the stromal cell compartment. After low-LET irradiation, the damage foci mostly disappeared at 24 h. Antibodies to more than one type of DNA repair factor display this pattern of DNA damage, and staining of nonirradiated cells with nonphosphorylated DNA-PKcs shows a predominance of epithelial staining over stromal cells. Biopsy specimens irradiated with high-LET radiations also show a pattern of predominance of the DNA damage response in the highly proliferative epithelial cell compartment. Persistent unrepaired DNA damage in colon epithelial cells and the differing repair responses between the epithelial and mesenchymal compartments in tissues may enhance tumorigenesis by both stem cell transformation and alterations in the radiation-induced permissive tissue microenvironment that may potentiate cancer progression.
鉴于辐射对结肠可能产生更大的致癌作用,长时间的星际任务后,宇航员患结直肠癌的风险可能会增加。此外,随着年龄的增长,结肠腺瘤性息肉的发病率也会更高。在本研究中,我们比较了辐射对二维(2D)单层培养、三维(3D)培养的人结肠上皮细胞以及完整的人结肠组织活检样本的影响。永生化结肠上皮细胞在美国国家航空航天局空间辐射实验室(NSRL)接受1 Gy 1 GeV/核子的(56)Fe粒子或1 Gy 1 GeV/核子的质子照射,并在不同时间进行染色,以评估DNA损伤和修复反应。结果显示,与质子辐射相比,铁粒子辐射在24小时时造成的损伤更持久。在三维结肠上皮细胞培养中也观察到了类似结果,其中(56)Fe粒子照射的样本在24小时时显示出比低线性能量传递(LET)γ射线照射的样本更持久的损伤。我们将这些结果与用1 Gy γ射线或1 Gy 1 GeV(56)Fe粒子照射的人结肠组织活检样本的结果进行了比较。对γ射线照射样本中辐射诱导的DNA损伤和修复的观察表明,与基质细胞区室相比,上皮细胞区室中的早期DNA损伤反应更为明显。低LET辐射后,损伤灶在24小时时大多消失。针对多种DNA修复因子的抗体均显示出这种DNA损伤模式,用非磷酸化DNA-PKcs对未照射细胞进行染色显示,上皮细胞染色比基质细胞更明显。高LET辐射照射的活检样本也显示出在增殖活跃的上皮细胞区室中DNA损伤反应占优势的模式。结肠上皮细胞中持续存在的未修复DNA损伤以及组织中上皮和间充质区室之间不同的修复反应,可能通过干细胞转化以及辐射诱导的允许性组织微环境的改变来增强肿瘤发生,而这种微环境改变可能会促进癌症进展。