Trott D A, Cuthbert A P, Overell R W, Russo I, Newbold R F
Human Cancer Genetics Unit, Brunel University, Uxbridge, UK.
Carcinogenesis. 1995 Feb;16(2):193-204. doi: 10.1093/carcin/16.2.193.
Immortalization is a prerequisite for the clonal evolution and malignant transformation of normal mammalian cells in culture. In order to gain a mechanistic insight into the genetics of carcinogen-induced cellular immortality, a cell culture assay has been developed based on the use of freshly explanted Syrian hamster dermal (SHD) fibroblasts. The relative efficacies of a variety of chemical and physical carcinogens at immortalizing SHD cells (against a zero background of spontaneous immortalization) were compared. Ionizing radiation and nickel chloride appeared to be more effective as immortalizing agents than powerful point mutagens, suggesting (but not proving) that clastogenic damage may be more significant in the immortalization process than point mutation. Frequencies of induced immortality (10(-6)-10(-7)/treated cell) were arguably consistent with a direct mutational mechanism involving a single genetic target. However, detailed cytogenetic characterization of a panel of newly immortalized cell lines revealed no non-random chromosomal alterations in the cells at the level of G-banding. Furthermore, additional experiments with the SHD system have provided confirmatory evidence that immortalization can occur as an indirect consequence of carcinogen exposure following an induced high frequency change in the treated population, rather than through direct targeted mutagenesis. Previous somatic cell genetic studies have suggested the possibility that a target gene for immortalization exists on the human and Chinese hamster X chromosomes. Here we provide strong evidence that the normal SHD X chromosome displays powerful senescence-inducing properties when introduced, by microcell transfer, into newly immortalized SHD recipients. These results suggest that induction of the immortal phenotype in SHD cells by carcinogens results primarily from functional inactivation of a senescence gene which may be X-linked. One possible mechanism for senescence gene inactivation consistent with our observations is through a sub-microscopic interstitial genetic deletion. However, the considerable efficacy of nickel (a human carcinogen) as an immortalizing agent at nonmutagenic doses raises the alternative possibility that immortalization may occur through an epigenetic mechanism.
永生化是培养的正常哺乳动物细胞发生克隆进化和恶性转化的前提条件。为了深入了解致癌物诱导细胞永生化的遗传学机制,基于使用新鲜分离的叙利亚仓鼠皮肤(SHD)成纤维细胞开发了一种细胞培养检测方法。比较了多种化学和物理致癌物使SHD细胞永生化的相对效力(相对于自发永生化的零背景)。电离辐射和氯化镍作为永生化剂似乎比强大的点突变剂更有效,这表明(但未证明)在永生化过程中染色体断裂损伤可能比点突变更重要。诱导永生化的频率(10^(-6)-10^(-7)/处理细胞)可以说与涉及单个遗传靶点的直接突变机制一致。然而,对一组新永生化细胞系的详细细胞遗传学特征分析显示,在G带水平上细胞中没有非随机染色体改变。此外,SHD系统的其他实验提供了确凿证据,表明永生化可能是处理群体中诱导高频变化后致癌物暴露的间接结果,而不是通过直接靶向诱变。先前的体细胞遗传学研究表明,在人和中国仓鼠X染色体上存在永生化靶基因的可能性。在这里,我们提供了有力证据,即通过微细胞转移将正常SHD X染色体引入新永生化的SHD受体时,它表现出强大的衰老诱导特性。这些结果表明,致癌物诱导SHD细胞中永生化表型主要是由于可能与X染色体连锁的衰老基因功能失活。与我们的观察结果一致的衰老基因失活的一种可能机制是通过亚显微间隙基因缺失。然而,镍(一种人类致癌物)在非诱变剂量下作为永生化剂的相当效力提出了另一种可能性,即永生化可能通过表观遗传机制发生。
