Fitzharris Greg, Baltz Jay M
Hormones, Growth and Development Program, Ottawa Health Research Institute, Ottawa, ON K1Y 4E9, Canada.
Development. 2006 Feb;133(4):591-9. doi: 10.1242/dev.02246. Epub 2006 Jan 11.
Oocytes grow within ovarian follicles in which the oocyte is coupled to the surrounding granulosa cells by gap junctions. It was previously found that small growing oocytes isolated from juvenile mice and freed of their surrounding granulosa cells (denuded) lacked the ability to regulate their intracellular pH (pH(i)), did not exhibit the pH(i)-regulatory HCO(3)(-)/Cl(-) and Na(+)/H(+) exchange activities found in fully-grown oocytes, and had low pH(i). However, both exchangers became active as oocytes grew near to full size, and, simultaneously, oocyte pH(i) increased by approximately 0.25 pH units. Here, we show that, in the more physiological setting of the intact follicle, oocyte pH(i) is instead maintained at approximately 7.2 throughout oocyte development, and the growing oocyte exhibits HCO(3)(-)/Cl(-) exchange, which it lacks when denuded. This activity in the oocyte requires functional gap junctions, as gap junction inhibitors eliminated HCO(3)(-)/Cl(-) exchange activity from follicle-enclosed growing oocytes and substantially impeded the recovery of the oocyte from an induced alkalosis, implying that oocyte pH(i) may be regulated by pH-regulatory exchangers in granulosa cells via gap junctions. This would require robust HCO(3)(-)/Cl(-) exchange activity in the granulosa cells, which was confirmed using oocytectomized (OOX) cumulus-oocyte complexes. Moreover, in cumulus-oocyte complexes with granulosa cells coupled to fully-grown oocytes, HCO(3)(-)/Cl(-) exchange activity was identical in both compartments and faster than in denuded oocytes. Taken together, these results indicate that growing oocyte pH(i) is controlled by pH-regulatory mechanisms residing in the granulosa cells until the oocyte reaches a developmental stage where it becomes capable of carrying out its own homeostasis.
卵母细胞在卵巢卵泡内生长,其中卵母细胞通过缝隙连接与周围的颗粒细胞相连。先前发现,从小鼠幼崽中分离出的正在生长的小卵母细胞,去除其周围的颗粒细胞(裸卵)后,缺乏调节细胞内pH值(pH(i))的能力,不表现出在完全成熟的卵母细胞中发现的pH(i)调节性HCO(3)(-)/Cl(-)和Na(+)/H(+)交换活性,且pH(i)较低。然而,随着卵母细胞接近完全成熟,这两种交换体均变得活跃,同时,卵母细胞pH(i)增加约0.25个pH单位。在此,我们表明,在完整卵泡这种更接近生理状态的环境中,卵母细胞pH(i)在整个卵母细胞发育过程中反而维持在约7.2,并且正在生长的卵母细胞表现出HCO(3)(-)/Cl(-)交换,而裸卵则缺乏这种交换。卵母细胞中的这种活性需要功能性缝隙连接,因为缝隙连接抑制剂消除了卵泡包裹的正在生长的卵母细胞的HCO(3)(-)/Cl(-)交换活性,并严重阻碍了卵母细胞从诱导性碱中毒中恢复,这意味着卵母细胞pH(i)可能由颗粒细胞中的pH调节交换体通过缝隙连接进行调节。这将需要颗粒细胞中强大的HCO(3)(-)/Cl(-)交换活性,使用去卵丘(OOX)卵丘-卵母细胞复合体对此进行了证实。此外,在颗粒细胞与完全成熟的卵母细胞相连的卵丘-卵母细胞复合体中,两个区室中的HCO(3)(-)/Cl(-)交换活性相同,且比裸卵中的更快。综上所述,这些结果表明,正在生长的卵母细胞pH(i)由颗粒细胞中的pH调节机制控制,直到卵母细胞达到能够进行自身稳态调节的发育阶段。
