Hunt T, Luca F C, Ruderman J V
Marine Biological Laboratory, Woods Hole, Massachusetts 02543.
J Cell Biol. 1992 Feb;116(3):707-24. doi: 10.1083/jcb.116.3.707.
Fertilization of clam oocytes initiates a series of cell divisions, of which the first three--meiosis I, meiosis II, and the first mitotic division--are highly synchronous. After fertilization, protein synthesis is required for the successful completion of every division except meiosis I. When protein synthesis is inhibited, entry into meiosis I and the maintenance of M phase for the normal duration of meiosis occur normally, but the chromosomes fail to interact correctly with the spindle in meiosis II metaphase. By contrast, inhibition of protein synthesis immediately after completion of meiosis or mitosis stops cells entering the next mitosis. We describe the behavior of cyclins A and B in relation to these "points of no return." The cyclins are synthesized continuously and are rapidly destroyed shortly before the metaphase-anaphase transition of the mitotic cell cycles, with cyclin A being degraded in advance of cyclin B. Cyclin destruction normally occurs during a 5-min window in mitosis, but in the monopolar mitosis that occurs after parthenogenetic activation of clam oocytes, or when colchicine is added to fertilized eggs about to enter first mitosis, the destruction of cyclin B is strongly delayed, whereas proteolysis of cyclin A is maintained in an activated state for the duration of metaphase arrest. Under either of these abnormal conditions, inhibition of protein synthesis causes a premature return to interphase that correlates with the time when cyclin B disappears.
蛤蚌卵母细胞受精会引发一系列细胞分裂,其中前三次分裂——减数分裂I、减数分裂II和第一次有丝分裂——高度同步。受精后,除减数分裂I外,每次分裂的成功完成都需要蛋白质合成。当蛋白质合成受到抑制时,进入减数分裂I以及在减数分裂的正常持续时间内维持M期均正常发生,但在减数分裂II中期,染色体无法与纺锤体正确相互作用。相比之下,在减数分裂或有丝分裂完成后立即抑制蛋白质合成会阻止细胞进入下一次有丝分裂。我们描述了细胞周期蛋白A和B与这些“不可逆点”相关的行为。细胞周期蛋白持续合成,并在有丝分裂细胞周期的中期 - 后期转换前不久迅速被降解,细胞周期蛋白A比细胞周期蛋白B提前降解。细胞周期蛋白的降解通常在有丝分裂的5分钟窗口内发生,但在蛤蚌卵母细胞孤雌激活后发生的单极有丝分裂中,或者当秋水仙碱添加到即将进入第一次有丝分裂的受精卵中时,细胞周期蛋白B的降解被强烈延迟,而细胞周期蛋白A的蛋白水解在中期停滞期间保持激活状态。在这两种异常情况下,抑制蛋白质合成都会导致过早回到间期,这与细胞周期蛋白B消失的时间相关。