Deguchi R, Shirakawa H, Oda S, Mohri T, Miyazaki S
Laboratory of Intracellular Metabolism, Department of Molecular Physiology, National Institute for Physiological Sciences, Myodaiji-cho, Okazaki, 444-8585, Japan.
Dev Biol. 2000 Feb 15;218(2):299-313. doi: 10.1006/dbio.1999.9573.
Fertilized mouse eggs exhibit repetitive rises in intracellular Ca(2+) concentration (Ca(2+)) necessary for egg activation. Precise spatiotemporal dynamics of each Ca(2+) rise were investigated by high-speed Ca(2+) imaging during early development of monospermic eggs. Every Ca(2+) rise involved a Ca(2+) wave. In the first Ca(2+) transient, Ca(2+) increased in two steps separated by a "shoulder" point, suggesting two distinct Ca(2+) release mechanisms. The first step was a Ca(2+) wave that propagated from the sperm-fusion site to its antipode in 4-5 s (velocity, approximately 20 microm/s in most eggs). The second step from the shoulder to the peak was a nearly uniform Ca(2+) rise of 12-15 s. A slight cytoplasmic movement followed the Ca(2+) wave in the same direction and recovered in 25-35 s. These characteristics changed as follows, as Ca(2+) oscillations progressed during the second meiosis up to their cessation at the stage of pronuclei formation ( approximately 3 h after fertilization). (1) The duration of Ca(2+) transients became shorter. (2) The shoulder point shifted to higher levels and the first step occupied most of the rising phase. (3) The rate of Ca(2+) rise became greater and wave speeds increased up to 80-100 microm/s or more. (4) The transient cytoplasmic movement always resulted from the Ca(2+) wave, although its displacement became smaller. (5) The Ca(2+) wave initiation site was freed from the sperm-fusion or -entry site and eventually localized in the cortex of the vegetal hemisphere. Since the shift of the wave initiation site to the vegetal cortex is observed in fertilized eggs of nemertean worms and ascidians, this might be an evolutionarily conserved feature.
受精的小鼠卵表现出细胞内钙离子浓度([Ca(2+)]i)的重复性升高,这是卵激活所必需的。通过对单精受精卵早期发育过程进行高速钙离子成像,研究了每次[Ca(2+)]i升高的精确时空动态。每次[Ca(2+)]i升高都涉及一个钙离子波。在第一次钙离子瞬变中,[Ca(2+)]i分两步升高,中间有一个“肩部”点,这表明存在两种不同的钙离子释放机制。第一步是一个钙离子波,它在4-5秒内从精子融合位点传播到其对极(在大多数卵中速度约为20微米/秒)。从肩部到峰值的第二步是[Ca(2+)]i在12-15秒内几乎均匀升高。钙离子波之后,细胞质会沿相同方向有轻微移动,并在25-35秒内恢复。随着减数第二次分裂过程中钙离子振荡的进行,直至在原核形成阶段(受精后约3小时)停止,这些特征发生了如下变化:(1)钙离子瞬变的持续时间变短。(2)肩部点移向更高水平,第一步占据了大部分上升阶段。(3)[Ca(2+)]i升高的速率变得更大,波速增加到80-100微米/秒或更高。(4)尽管细胞质的位移变小,但瞬时细胞质移动总是由钙离子波引起的。(5)钙离子波起始位点从精子融合或进入位点脱离,最终定位于植物半球的皮质。由于在纽形动物和海鞘的受精卵中也观察到波起始位点向植物皮质的转移,这可能是一个进化上保守的特征。
