MacDonald D, Boulton E, Pocock D, Goodhead D, Kadhim M, Plumb M
MRC Radiation and Genome Stability Unit, Chilton, Didcot, OXON, OX11 ORD, UK.
Int J Radiat Biol. 2001 Oct;77(10):1023-31. doi: 10.1080/09553000110073411.
If radiation-induced genetic instability is causal in mouse radiation leukaemogenesis, then genetic instability should be detectable in the irradiated target untransformed haemopoietic stem cell, and evidence of genetic instability detected in the clonal radiation-induced leukaemia. We have tested this hypothesis using the CBA/H mouse model of radiation-induced acute myeloid leukaemia (r-AML).
Fluorescence in situ hybridisation (FISH) was employed to screen for chromosomal aberrations in mouse 3 Gy X-ray-induced r-AMLs and in the clonal descendents of control and 3 Gy X-irradiated bone marrow haemopoietic stem cells using the in vitro clonogenic CFU-A colony assay.
High levels of clonal non-specific chromosomal aberrations were detected in the r-AML (approximately 4-5 aberrations/r-AML), and ongoing chromosomal instability as defined by subclonal variants detected in 5/10 r-AML. A similar analysis of CFU-A colonies revealed chromosomal aberrations in 25% of colonies derived from irradiated bone marrow (2% in controls). However, 66% of the aberrant colonies (2% in controls) exhibited ongoing genetic instability as defined by non-clonal chromosomal aberrations. Overall, 6% (121/1884) of the CFU-A cells derived from irradiated bone marrow were aberrant (0.05% in controls) of which 12% (15/121) were subclonal. No one CFU-A cell exhibited aberrations on more than one of the three chromosomes painted.
The high levels of non-specific genetic damage observed in the r-AMLs is therefore attributed to the accumulation of genetic lesions in the target haemopoietic stem cell over a longer time-scale after exposure than assessed in the in vitro CFU-A clonogenic assay. This is consistent with the long latency of the multi-stage radiation leukaemogenic process, and a role for radiation-induced genetic instability is inferred.
如果辐射诱导的基因不稳定是小鼠辐射诱发白血病的病因,那么在受照射的未转化造血干细胞中应可检测到基因不稳定,并且在克隆性辐射诱发白血病中也应能检测到基因不稳定的证据。我们使用辐射诱发急性髓系白血病(r-AML)的CBA/H小鼠模型对这一假设进行了检验。
采用荧光原位杂交(FISH)技术,通过体外克隆形成CFU-A集落试验,筛选小鼠3 Gy X射线诱发的r-AML以及对照和3 Gy X射线照射的骨髓造血干细胞的克隆后代中的染色体畸变。
在r-AML中检测到高水平的克隆性非特异性染色体畸变(约4 - 5个畸变/r-AML),并且在10个r-AML中的5个中检测到由亚克隆变异定义的持续染色体不稳定。对CFU-A集落的类似分析显示,来自照射骨髓的集落中有25%存在染色体畸变(对照中为2%)。然而,66%的异常集落(对照中为2%)表现出由非克隆性染色体畸变定义的持续基因不稳定。总体而言,来自照射骨髓的CFU-A细胞中有6%(121/1884)异常(对照中为0.05%),其中12%(15/121)为亚克隆。没有一个CFU-A细胞在三条被标记染色体中的一条以上出现畸变。
因此,在r-AML中观察到的高水平非特异性基因损伤归因于暴露后比体外CFU-A克隆形成试验评估的更长时间尺度上靶造血干细胞中基因损伤的积累。这与多阶段辐射致白血病过程的长潜伏期一致,并推断辐射诱导的基因不稳定起了作用。
