Center for Radiological Research, Columbia University Medical Center, New York, New York 10032.
Radiat Res. 2015 Mar;183(3):315-24. doi: 10.1667/RR13860.1. Epub 2015 Mar 4.
The biological risks associated with low-dose-rate (LDR) radiation exposures are not yet well defined. To assess the risk related to DNA damage, we compared the yields of two established biodosimetry end points, γ-H2AX and micronuclei (MNi), in peripheral mouse blood lymphocytes after prolonged in vivo exposure to LDR X rays (0.31 cGy/min) vs. acute high-dose-rate (HDR) exposure (1.03 Gy/min). C57BL/6 mice were total-body irradiated with 320 kVP X rays with doses of 0, 1.1, 2.2 and 4.45 Gy. Residual levels of total γ-H2AX fluorescence in lymphocytes isolated 24 h after the start of irradiation were assessed using indirect immunofluorescence methods. The terminal deoxynucleotidyl transferase dUTP nick end labeling (TUNEL) assay was used to determine apoptotic cell frequency in lymphocytes sampled at 24 h. Curve fitting analysis suggested that the dose response for γ-H2AX yields after acute exposures could be described by a linear dependence. In contrast, a linear-quadratic dose-response shape was more appropriate for LDR exposure (perhaps reflecting differences in repair time after different LDR doses). Dose-rate sparing effects (P < 0.05) were observed at doses ≤2.2 Gy, such that the acute dose γ-H2AX and TUNEL-positive cell yields were significantly larger than the equivalent LDR yields. At the 4.45 Gy dose there was no difference in γ-H2AX expression between the two dose rates, whereas there was a two- to threefold increase in apoptosis in the LDR samples compared to the equivalent 4.45 Gy acute dose. Micronuclei yields were measured at 24 h and 7 days using the in vitro cytokinesis-blocked micronucleus (CBMN) assay. The results showed that MNi yields increased up to 2.2 Gy with no further increase at 4.45 Gy and with no detectable dose-rate effect across the dose range 24 h or 7 days post exposure. In conclusion, the γ-H2AX biomarker showed higher sensitivity to measure dose-rate effects after low-dose LDR X rays compared to MNi formation; however, confounding factors such as variable repair times post exposure, increased cell killing and cell cycle block likely contributed to the yields of MNi with accumulating doses of ionizing radiation.
低剂量率(LDR)辐射相关的生物风险尚未得到充分定义。为了评估与 DNA 损伤相关的风险,我们比较了两种已建立的生物剂量学终点γ-H2AX 和微核(MNi)在体内暴露于 LDR X 射线(0.31 cGy/min)后外周血小鼠淋巴细胞中的产量,与急性高剂量率(HDR)暴露(1.03 Gy/min)相比。C57BL/6 小鼠全身接受 320 kVP X 射线照射,剂量分别为 0、1.1、2.2 和 4.45 Gy。照射开始后 24 小时分离的淋巴细胞中总γ-H2AX 荧光的残留水平使用间接免疫荧光法进行评估。末端脱氧核苷酸转移酶 dUTP 缺口末端标记(TUNEL)测定法用于测定 24 小时时淋巴细胞中凋亡细胞的频率。曲线拟合分析表明,急性暴露后γ-H2AX 产量的剂量反应可以用线性关系来描述。相比之下,LDR 暴露更适合线性二次剂量反应形状(可能反映了不同 LDR 剂量后修复时间的差异)。在≤2.2 Gy 的剂量下观察到剂量率节省效应(P < 0.05),使得急性剂量γ-H2AX 和 TUNEL 阳性细胞产量明显大于等效的 LDR 产量。在 4.45 Gy 剂量下,两种剂量率之间γ-H2AX 表达无差异,而 LDR 样品中的凋亡增加了两到三倍,与等效的 4.45 Gy 急性剂量相比。使用体外细胞有丝分裂阻断微核(CBMN)测定法在 24 小时和 7 天时测量微核产量。结果表明,MNi 产量在 2.2 Gy 时增加,在 4.45 Gy 时不再增加,并且在暴露后 24 小时或 7 天的整个剂量范围内没有可检测的剂量率效应。总之,与微核形成相比,γ-H2AX 生物标志物在测量低剂量 LDR X 射线后的剂量率效应方面具有更高的敏感性;然而,暴露后修复时间的变化、增加的细胞杀伤和细胞周期阻滞等混杂因素可能导致微核产量随着电离辐射累积剂量的增加而增加。