Cortical and cytoplasmic flows driven by actin microfilaments polarize the cortical ER-mRNA domain along the a–v axis in ascidian oocytes

Cellular mechanisms generating the polarized redistribution of maternal Type I postplasmic/PEM mRNAs in ascidian oocytes remain unknown. We have previously shown that PEM-1 mRNA is associated with a network of rough cortical Endoplasmic Reticulum (cER) polarized along the animal–vegetal (a–v) axis forming a cER–mRNA domain in mature oocytes. We now investigate the a–v polarization of this cER–mRNA domain during meiotic maturation using H. roretzi and C. intestinalis. We show that the cER and Hr-PEM-1 aggregate as interconnected cortical patches at the cell periphery before maturation, which uniformly spread out during maturation and form a reticulated organization enriched in the vegetal hemisphere at the end of maturation. Time-lapse video recordings coupled with micromanipulations reveal that stereotyped surface, cortical and cytoplasmic flows accompany the vegetal shift of the cER–mRNA domain and mitochondria-rich myoplasm. Treatments with cytochalasin B and nocodazole indicate that both polarization of the cER–mRNA domain and mitochondria-rich myoplasm and cortical and cytoplasmic flows depend on actin cytoskeleton, but not microtubules. Using cortical fragments prepared from maturing oocytes coupled with high resolution immuno/in situ localization, we have further analyzed the effects of these inhibitors on the reorganizations the cER network and Hr-PEM-1 mRNA. We show that before maturation starts, Hr-PEM-1 mRNAs are already associated with the cER, and actin cytoskeleton inhibitors disturb their association. Finally, we hypothesize that Germinal Vesicle Break Down (GVBD) triggers an actomyosin-dependant cortical flow which directs the a–v polarization of ascidian oocytes.