Abstract
Ca 2+ oscillations and signaling represent a basic mechanism for controlling many cellular events. Activation of mouse eggs entrains a temporal series of Ca 2+ -dependent events that include cortical granule exocytosis, cell cycle resumption with concomitant decreases in MPF and MAP kinase activities, and recruitment of maternal mRNAs. The outcome is a switch in cellular differentiation, i.e., the conversion of the egg into the zygote. By activating mouse eggs with experimentally controlled and precisely defined Ca 2+ transients, we demonstrate that each of these events is initiated by a different number of Ca 2+ transients, while their completion requires a greater number of Ca 2+ transients than for their initiation. This combination of differential responses to the number of Ca 2+ transients provides strong evidence that a single Ca 2+ transient-driven signaling system can initiate and drive a cell into a new developmental pathway, as well as can account for the temporal sequence of cellular changes associated with early development.
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