Inositol 1,4,5-trisphosphate (IP₃) plays an important role in the release of Cα²+ from intracellular stores into the cytoplasm in a variety of cell types. IP₃ translocation dynamics have been studied in response to many types of cell signals. However, the dynamics of cytosolic IP₃ in salivary acinar cells are unclear. A green fluorescent protein (GFP)-tagged pleckstrin homology domain (PHD) was constructed and introduced into a phospholipase C δ1 (PLC δ1) transgenic mouse, and then the salivary acinar cells were isolated. GFP-PHD was heterogeneously localized at the plasma membrane and intracellular organelles in submandibular gland and parotid gland cells. Application of trypsin, a G protein-coupled receptor activator, to the two types of cells caused an increase in GFP fluorescence in the cell cytoplasm. The observed time course of trypsin-evoked IP₃movement in acinar cells was independent of cell polarity, and the fluorescent label showed an immediate increase throughout the cells. These results suggest that GFP-PHD in many tissues of transgenic mice, including non-cultured primary cells, can be used as a model for examination of IP₃intracellular dynamics.

BACKGROUND Ca2+ oscillations during fertilization induce eggs activation and embryonic development in mammalian eggs.. The type 1 inositol 1,4,5-trisphosphate receptor (IP3R1) is in charge of Ca2+ oscillations for the release of stored Ca2+ from the endoplasmic reticulum. The capacity of this oscillation is obtained during egg maturation and corresponds with an increase in the sensitivity of the IP3R1 and their localization in cytoplasm. Cluster formation of IP3R1 in the egg cortex is important to initiation of Ca2+ oscillations during egg and sperm fusion. In this study, we investigated that cell cycle–coupled redistribution of IP3R1 and Ca2+- oscillatory activity in mouse zygotes. MATERIALS AND METHODS Metaphase II arrested eggs were collected from ICR female mouse after super ovulation induction. At 14 hr post hCG, MII eggs were collected, and artificially activated in Ca2+ free CZB medium with 10 mM SrCl2 for 2 hrs. Pronuclear zygotes (PN) were collected from Strontium activated eggs at 8 hr post activation, and the first mitotic eggs were collected at 16~17 hr post activation. To identify cell cycle coupled IP3R1 redistribution, MII eggs, zygotes, and first mitotic eggs were collected, and fixed for immunostaining with anti-IP3R1antibody (CT-1) and observed on CLSM. Ca2+-oscillatory activity was monitored with fluorescence microscope mounted SimplePCI program (Hamamatsu) after injection of cRNA of mouse phospholipase C zeta (mPLCZ). RESULT IP3R1 were shown clusters, 1~2 um in diameter, in cortex of ovulated MII eggs with high Ca2+ oscillatory activity by mPLCZ injection. These eggs represent more than 6 spikes per 60 min. However, IP3R1 clusters were disappeared in PN eggs and these eggs showed very low Ca2+- oscillatory activity by mPLCZ. In mitosis I stage eggs, clusters of IP3R1 were appeared and Ca2+-oscillatory activity was reactivated slightly (2 spikes per 60 min). CONCLUSIOINS This study introduced the redistribution of IP3R1 clusters were occurred in egg activation according to cell cycle dependent manner. Also, functional modification of IP3R1 including protein phosphorylation was associated with cortical clustering of IP3R1 in cell cycle coupled Ca2+ oscillatory activity.