Offspring from oocytes grown in frozen-thawed ovarian tissues transplanted to male and female bodies

Abstract

Abstract Objective: There are few reports of live births from heterotopic transplantation of frozen-thawed ovarian tissue. The purpose of this study is to assess the follicular development in the frozen-thawed ovarian tissues following heterotopic transplantation in both female and male bodies. Methods: Cluster of differentiation 1 (CD1) mice (6-8 weeks) were used in this study as ovarian tissue donors and foster mothers for embryo transfer. Sperm from CD1 male mice were used for insemination by intracytoplasmic sperm injection (ICSI). Nude severe combined immunodeficiency mice (8 weeks) were employed as recipients of ovarian tissue transplantation. The frozen-thawed ovarian tissues were transplanted to 4 sites on each mouse, female and male, subcutaneously. After 3 months, both female and male mice were injected with 5.0 IU gonadotropins intraperitoneally. Post 48 hours of injection, the mouse was killed for ovarian transplant collection. Only fully grown oocytes with contacted cumulus cells (cumulus-oocyte complexes) were then selected for maturation in vitro. In vitro matured oocytes were inseminated with fresh sperm by ICSI, and the developed blastocysts were frozen using the vitrification method and stored until embryo transfer. After thawing, the thawed blastocysts were incubated for at least 2 hours before the transfer. The foster mice mothers mated with vasectomised male 3 days previously. Live birth was monitored at 19 days after transfer, and the resulted offspring was raised for fertility test. Results: The relatively high recovery rates of the transplanted ovarian tissues were collected in both frozen-thawed and fresh ovarian tissue transplants from both female and male bodies. The fully grown immature oocytes became mature in vitro and the fertilized zygotes developed to blastocyst stage. There are no differences between frozen-thawed and fresh ovarian transplants in term of oocyte quality and embryo development to blastocyst rates. Nineteen-day post-transfer, 3 foster mothers from the frozen-thawed ovarian tissue transplant group delivered 13 pups and the 4 foster mothers of the fresh ovarian tissue transplant group delivered 12 live pups. The produced offspring were normal in appearance and grew healthy and fertile. Conclusions: Our results attest that the follicles can survive and develop in the frozen-thawed ovarian tissues following the subcutaneous transplant to adult male mouse's body regardless of basal endocrinal environment. Those fully grown oocytes can produce healthy and fertile offspring which will provide the possibility for further mechanistic understanding of endocrinology of folliculogenesis.