More accurate analysis of maternal effect genes by siRNA electroporation into mouse oocytes

Abstract

AbstractMaternal RNAs and proteins accumulate in mouse oocytes and control the initial stages of development. The DNA in sperm combines with protamine, which is exchanged after fertilization with maternal histones, including H3.3, but the effect of H3.3 on post-fertilization development has been unclear. In this study, we established an electroporation method to introduce H3.3 siRNA into germinal vesicle (GV)-stage oocytes without removing cumulus cells. In the traditional microinjection method, cumulus cells attached to oocytes must be removed; however, we confirmed that artificially removing cumulus cells from oocytes reduced fertilization rates, and oocytes originally free of cumulus cells had reduced developmental competence. When H3.3 siRNA was introduced at the GV stage, H3.3 was still present in the maternal pronucleus and second polar body, but not in the paternal pronucleus, resulting in embryonic lethality after fertilization. This indicates that the H3.3 protein was not incorporated into the paternal pronucleus because it was repeatedly translated and degraded in a relatively short time. On the other hand, H3.3 protein incorporated into the maternal genome in the GV stage escaped degradation and remained in the maternal pronucleus after fertilization. This new method of electroporation into GV-stage oocytes without removing cumulus cells is not skill intensive and is essential for the accurate analysis of maternal effect genes.In briefFor analysis of maternal factors contained in the oocyte, suppression of genes within the oocyte is necessary. In this paper, siRNA was introduced into oocytes by electroporation, showing that maternal mRNA was suppressed efficiently.