Developmentally regulated cell cycle dependence of swelling-activated anion channel activity in the mouse embryo

Abstract

Anion channels activated by increased cell volume are a nearly ubiquitous mechanism of cell volume regulation, including in early preimplantation mouse embryos. Here, we show that the swelling-activated anion current (I_Cl,swell) in early mouse embryos is cell-cycle dependent, and also that this dependence is developmentally regulated. I_Cl,swell is present both in first meiotic prophase (germinal vesicle stage) mouse oocytes and in unfertilized mature oocytes in second meiotic metaphase, and it persists after fertilization though the 1-cell and 2-cell stages. I_Cl,swell was found to remain unchanged during metaphase at the end of the 1-cell stage. However, I_Cl,swell decreased during prophase and became nearly undetectable upon entry into metaphase at the end of the 2-cell stage. Entry into prophase/metaphase was required for the decrease in I_Cl,swell at the end of the 2-cell stage, since it persisted indefinitely in 2-cell embryos arrested in late G₂. There is considerable evidence that the channel underlying I_Cl,swell is not only permeable to inorganic anions, but to organic osmolytes as well. We found a similar pattern of cell cycle and developmental dependence in the 1-cell and 2-cell stages for the swelling-induced increase in permeability to the organic osmolyte glycine. Thus, entry into metaphase deactivates I_Cl,swell in embryos, but only after developmental progression through the 2-cell stage.