G2/M 期转换期 Cyclin A/B1/B2 相关事件
中文名称
通路描述
细胞周期的进展由 G1/S、S/G2 和 G2/M 转换期 Cyclin 依赖性蛋白激酶的激活所调节(参见 Lemmens 和 Lindqvist 2019)。S/G2 转换期的 DNA 复制完成允许 CDK1 和 PLK1 的激活。最近的证据表明,Cyclin A:CDK1 (CCNA:CDK1) 复合物的激活促进 AURKA 的激活,进而促进 PLK1 的激活,后者又促进 Cyclin B:CDK1 (CCNB:CDK1) 复合物的激活(参见 Pintard 和 Archambault 2018, Lemmens 和 Lindqvist 2019, Moura 和 Conde 2019)。抑制性 PKMYT1 和 WEE1 激酶阻止 CDK1 复合物的过早激活(参见 Lemmens 和 Lindqvist 2019)。CDC25 家族磷酸酶(CDC25A, CDC25B 和 CDC25C)在 G2/M 转换期被激活,去除抑制性磷酸化修饰,与由 CAK 复合物介导的激活性磷酸化共同作用(参见 Lolli 和 Johnson 2005),从而允许 CDK1 复合物的完全激活(参见 Lemmens 和 Lindqvist 2019, Moura 和 Conde 2019)。CCNA:CDK1 和 CCNB:CDK1 复合物磷酸化大量参与有丝分裂(M 期)的蛋白质(参见 Sefton 2001),包括核纤层蛋白(参见 Lemmens 和 Lindqvist 2019, Liu 和 Ikegami 2020)以及其他参与核膜崩解的蛋白质(参见 Lindqvist 等人 2009, Lacroix 等人 2022)、参与有丝纺锤体形成的蛋白质(参见 Hayward 等人 2019, Lacroix 等人 2022)以及参与高尔基体崩解的蛋白质(参见 Preisinger 和 Barr 2005)。虽然 CDK1 复合物在体外可能表现出高水平的冗余性(Bellanger 等人 2007),但其底物特异性在体内部分由其亚细胞定位决定,其中 CCNA:CDK1 复合物主要位于细胞核,CCNB1:CDK1 复合物主要位于细胞质,而 CCNB2:CDK1 复合物主要定位于高尔基体膜(Jackman 等人 1995, Hagting 等人 1999, Dravian 等人 2001,参见 Yang 和 Kornbluth 1999)。此外,虽然 CCNA2, CCNB1 和 CCNB2 普遍表达,但 CCNA1 主要在睾丸中表达,并在减数分裂中发挥重要作用(参见 Chotiner 等人 2019),但也参与特定细胞类型(如造血干细胞)中的有丝分裂(参见 Dai 等人 2019)。CCNB3 仅在减数分裂中发挥作用(参见 Chotiner 等人 2019)。
英文描述
Cyclin A/B1/B2 associated events during G2/M transition Cell cycle progression is regulated by activation of cyclin-dependent protein kinases at G1/S, S/G2, and G2/M transitions (reviewed in Lemmens and Lindqvist 2019). Completion of DNA replication at the S/G2 transition allows activation of CDK1 and PLK1. Recent evidence implies that the activation of Cyclin A:CDK1 (CCNA:CDK1) complexes promotes the activation of AURKA, which promotes the activation of PLK1, which then promotes the activation of Cyclin B:CDK1 (CCNB:CDK1) complexes (reviewed in Pintard and Archambault 2018, Lemmens and Lindqvist 2019, Moura and Conde 2019). Inhibitory PKMYT1 and WEE1 kinases prevent premature activation of CDK1 complexes (reviewed in Lemmens and Lindqvist 2019). The CDC25 family phosphatases (CDC25A, CDC25B, and CDC25C), activated at G2/M transition, remove the inhibitory phosphorylations and, together with the activating phosphorylation mediated by the CAK complex (reviewed in Lolli and Johnson 2005), enable the full activation of CDK1 complexes (reviewed in Lemmens and Lindqvist 2019, Moura and Conde 2019). CCNA:CDK1 and CCNB:CDK1 complexes phosphorylate a large number of proteins involved in mitosis (M phase) (reviewed in Sefton 2001), including lamins (reviewed in Lemmens and Lindqvist 2019, Liu and Ikegami 2020) and other proteins involved in nuclear envelope breakdown (reviewed in Lindqvist et al. 2009, Lacroix et al. 2022), proteins involved in mitotic spindle formation (reviewed in Hayward et al. 2019, Lacroix et al. 2022), and proteins involved in disassembly of the Golgi apparatus (reviewed in Preisinger and Barr 2005). While CDK1 complexes may exhibit a high level of redundancy in vitro (Bellanger et al. 2007), their substrate specificity in vivo is partially determined by their subcellular localization, with CCNA:CDK1 complexes being mainly nuclear, the CCNB1:CDK1 complex being mainly cytosolic, and the CCNB2:CDK1 complex localizing mainly to the Golgi membrane (Jackman et al. 1995, Hagting et al. 1999, Dravian et al. 2001, reviewed in Yang and Kornbluth 1999). In addition, while CCNA2, CCNB1, and CCNB2 are ubiquitously expressed, CCNA1 is predominantly expressed in the testes and plays an important role in meiosis (reviewed in Chotiner et al. 2019), but it is also implicated in mitosis in specific cell types, such as hematopoietic stem cells (reviewed in Dai et al. 2019). CCNB3 functions exclusively in meiosis (reviewed in Chotiner et al. 2019).
所含基因
32 个基因