Aneuploidy, the somatic mutation that makes cancer a species of its own.

P Duesberg, D Rasnick
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引用次数: 240

Abstract

The many complex phenotypes of cancer have all been attributed to "somatic mutation." These phenotypes include anaplasia, autonomous growth, metastasis, abnormal cell morphology, DNA indices ranging from 0.5 to over 2, clonal origin but unstable and non-clonal karyotypes and phenotypes, abnormal centrosome numbers, immortality in vitro and in transplantation, spontaneous progression of malignancy, as well as the exceedingly slow kinetics from carcinogen to carcinogenesis of many months to decades. However, it has yet to be determined whether this mutation is aneuploidy, an abnormal number of chromosomes, or gene mutation. A century ago, Boveri proposed cancer is caused by aneuploidy, because it correlates with cancer and because it generates "pathological" phenotypes in sea urchins. But half a century later, when cancers were found to be non-clonal for aneuploidy, but clonal for somatic gene mutations, this hypothesis was abandoned. As a result aneuploidy is now generally viewed as a consequence, and mutated genes as a cause of cancer although, (1) many carcinogens do not mutate genes, (2) there is no functional proof that mutant genes cause cancer, and (3) mutation is fast but carcinogenesis is exceedingly slow. Intrigued by the enormous mutagenic potential of aneuploidy, we undertook biochemical and biological analyses of aneuploidy and gene mutation, which show that aneuploidy is probably the only mutation that can explain all aspects of carcinogenesis. On this basis we can now offer a coherent two-stage mechanism of carcinogenesis. In stage one, carcinogens cause aneuploidy, either by fragmenting chromosomes or by damaging the spindle apparatus. In stage two, ever new and eventually tumorigenic karyotypes evolve autocatalytically because aneuploidy destabilizes the karyotype, ie. causes genetic instability. Thus, cancer cells derive their unique and complex phenotypes from random chromosome number mutation, a process that is similar to regrouping assembly lines of a car factory and is analogous to speciation. The slow kinetics of carcinogenesis reflects the low probability of generating by random chromosome reassortments a karyotype that surpasses the viability of a normal cell, similar again to natural speciation. There is correlative and functional proof of principle: (1) solid cancers are aneuploid; (2) genotoxic and non-genotoxic carcinogens cause aneuploidy; (3) the biochemical phenotypes of cells are severely altered by aneuploidy affecting the dosage of thousands of genes, but are virtually un-altered by mutations of known hypothetical oncogenes and tumor suppressor genes; (4) aneuploidy immortalizes cells; (5) non-cancerous aneuploidy generates abnormal phenotypes in all species tested, e.g., Down syndrome; (6) the degrees of aneuploidies are proportional to the degrees of abnormalities in non-cancerous and cancerous cells; (7) polyploidy also varies biological phenotypes; (8) variation of the numbers of chromosomes is the basis of speciation. Thus, aneuploidy falls within the definition of speciation, and cancer is a species of its own. The aneuploidy hypothesis offers new prospects of cancer prevention and therapy.

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非整倍体,使癌症成为一个独立物种的体细胞突变。
许多复杂的癌症表型都归因于“体细胞突变”。这些表型包括发育不全、自主生长、转移、细胞形态异常、DNA指数从0.5到2以上、克隆起源但不稳定和非克隆核型和表型、中心体数量异常、在体外和移植中不朽、恶性肿瘤的自发进展以及从致癌物到癌变的极慢动力学(数月至数十年)。然而,这种突变是非整倍体、染色体数目异常还是基因突变还有待确定。一个世纪前,Boveri提出癌症是由非整倍体引起的,因为它与癌症相关,并且在海胆中产生“病理”表型。但半个世纪后,当癌症被发现是非整倍体的非克隆性,而体细胞基因突变的克隆性时,这个假设被抛弃了。因此,非整倍体现在普遍被认为是一种结果,而突变的基因是导致癌症的原因,尽管:(1)许多致癌物不会使基因突变,(2)没有功能上的证据表明突变的基因会导致癌症,(3)突变是快速的,但致癌是非常缓慢的。被非整倍体巨大的致突变潜力所吸引,我们对非整倍体和基因突变进行了生化和生物学分析,结果表明非整倍体可能是唯一可以解释癌变所有方面的突变。在此基础上,我们现在可以提供一个连贯的两阶段癌变机制。在第一阶段,致癌物通过分裂染色体或破坏纺锤体引起非整倍体。在第二阶段,由于非整倍性破坏了核型的稳定性,新的和最终致瘤性的核型会自动催化进化。导致基因不稳定。因此,癌细胞从随机染色体数目突变中获得独特而复杂的表型,这一过程类似于汽车厂装配线的重组,类似于物种形成。癌变的缓慢动力学反映了通过随机染色体重组产生超过正常细胞生存能力的核型的低概率,再次类似于自然物种形成。有相关的和功能的原理证明:(1)实体癌是非整倍体;(2)基因毒性和非基因毒性致癌物引起非整倍体;(3)细胞的生化表型受到影响数千个基因剂量的非整倍体的严重改变,但实际上不受已知假设的致癌基因和肿瘤抑制基因突变的影响;(4)非整倍性使细胞不朽;(5)非癌性非整倍体在所有被测物种中产生异常表型,例如唐氏综合征;(6)非整倍体的程度与非癌细胞和癌变细胞的异常程度成正比;(7)多倍体也改变生物学表型;(8)染色体数目的变化是物种形成的基础。因此,非整倍性属于物种形成的定义,癌症是一个自己的物种。非整倍体假说为癌症预防和治疗提供了新的前景。
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