Viallard J F, Lacombe F, Belloc F, Pellegrin J L, Reiffers J
Service de médecine interne et maladies infectieuses, centre François-Magendie, hôpital du Haut-Lévêque, 5, avenue Magellan, 33604 Pessac, France.
Cancer Radiother. 2001 Apr;5(2):109-29. doi: 10.1016/s1278-3218(01)00087-7.
Comprehension of cell cycle regulation mechanisms has progressed very quickly these past few years and regulators of the cell cycle have gained widespread importance in cancer. This review first summarizes major advances in the understanding of the control of cell cycle mechanisms. Examples of how this control is altered in tumoral cells are then described.
The typical mammalian cell cycle consists of four distinct phases occurring in a well-defined order, each of which should be completed successfully before the next begins. Progression of eukaryotic cells through major cell cycle transitions is mediated by sequential assembly and activation of a family of serine-threonine protein kinases, the cyclin dependent kinases (CDK). The timing of their activation is determined by their post-translational modifications (phosphorylations/dephosphorylations), and by the association of a protein called cyclin, which is the regulatory subunit of the kinase complex. The cyclin family is divided into two main classes. The 'G1 cyclins' include cyclins C, D1-3, and E, and their accumulation is rate-limiting for progression from the G1 to S phase. The 'mitotic or G2 cyclins', which include cyclin A and cyclin B, are involved in the control of G2/M transition and mitosis. The cyclins bind to and activate the CDK, which leads to phosphorylation (and then inhibition) of the tumor suppressor protein, pRb. pRb controls commitment to progress from the G1 to S phase, at least in part by repressing the activity of the E2F transcription factors known to promote cell proliferation. Both the D-type cyclins and their partner kinases CDK4/6 have proto-oncogenic properties, and their activity is carefully regulated at multiple levels including negative control by two families of CDK inhibitors. While members of the INK4 family (p16INK4A, p15INK4B, p18INK4C, p19INK4D) interact specifically with CDK4 and CDK6, the CIP/KIP inhibitors p21CIP1/WAF1, p27KIP1 and p57KIP2 inhibit a broader spectrum of CDK. The interplay between p16INK4A, cyclin D/CDK, and pRb/E2F together constitute a functional unit collectively known as the 'pRb pathway'. Each of the major components of this mechanism may become deregulated in cancer, and accumulating evidence points to the 'pRb pathway' as a candidate obligatory target in multistep oncogenesis of possibly all human tumor types.
Major advances in the understanding of cell cycle regulation mechanisms provided a better knowledge of the molecular interactions involved in human cancer. This progress has led to the promotion of new therapeutic agents presently in clinical trials or under development. Moreover, the components of the cell cycle are probably involved in other non-cancerous diseases and their role must be defined.
在过去几年中,对细胞周期调控机制的理解取得了飞速进展,细胞周期调节因子在癌症领域已变得极为重要。本综述首先总结了在细胞周期机制控制理解方面的主要进展。接着描述了肿瘤细胞中这种控制是如何改变的实例。
典型的哺乳动物细胞周期由四个不同阶段按明确顺序发生组成,每个阶段都应在下一阶段开始前成功完成。真核细胞通过主要细胞周期转换的进程由一组丝氨酸 - 苏氨酸蛋白激酶(细胞周期蛋白依赖性激酶,CDK)的顺序组装和激活介导。它们激活的时间由其翻译后修饰(磷酸化/去磷酸化)以及一种名为细胞周期蛋白的蛋白质的结合决定,细胞周期蛋白是激酶复合物的调节亚基。细胞周期蛋白家族分为两大类。“G1期细胞周期蛋白”包括细胞周期蛋白C、D1 - 3和E,它们的积累是从G1期进入S期进程的限速因素。“有丝分裂或G2期细胞周期蛋白”,包括细胞周期蛋白A和细胞周期蛋白B,参与G2/M转换和有丝分裂的控制。细胞周期蛋白与CDK结合并激活它,这导致肿瘤抑制蛋白pRb的磷酸化(进而抑制)。pRb至少部分通过抑制已知促进细胞增殖的E2F转录因子的活性来控制从G1期进入S期的进程。D型细胞周期蛋白及其伴侣激酶CDK4/6都具有原癌基因特性,它们的活性在多个水平受到精细调节,包括由两类CDK抑制剂进行负调控。INK4家族成员(p16INK4A、p15INK4B、p18INK4C、p19INK4D)特异性地与CDK4和CDK6相互作用,而CIP/KIP抑制剂p21CIP1/WAF1、p27KIP1和p57KIP2抑制更广泛的CDK谱。p16INK4A、细胞周期蛋白D/CDK和pRb/E2F之间的相互作用共同构成一个功能单元,统称为“pRb通路”。该机制的每个主要组成部分在癌症中都可能失调,越来越多的证据表明“pRb通路”是可能所有人类肿瘤类型多步骤肿瘤发生中一个候选的必需靶点。
对细胞周期调控机制理解的重大进展使我们对人类癌症中涉及的分子相互作用有了更好的认识。这一进展促使了目前正在临床试验或研发中的新型治疗药物的出现。此外,细胞周期的组成部分可能参与其他非癌性疾病,其作用必须加以明确。
