A macrophage and theca cell-enriched stromal cell population influences growth and survival of immature murine follicles in vitro.

Innovations in in vitro ovarian follicle culture have revolutionized the field of fertility preservation, but the successful culturing of isolated primary and small secondary follicles remains difficult. Herein, we describe a revised 3D culture system that uses a feeder layer of ovarian stromal cells to support early follicle development. This culture system allows significantly improved primary and early secondary follicle growth and survival.

In vitro oocyte maturation and preantral follicle culture from the luteal-phase baboon ovary produce mature oocytes.

Female cancer patients who seek fertility preservation but cannot undergo ovarian stimulation and embryo preservation may consider 1) retrieval of immature oocytes followed by in vitro maturation (IVM) or 2) ovarian tissue cryopreservation followed by transplantation or in vitro follicle culture. Conventional IVM is carried out during the follicular phase of menstrual cycle. There is limited evidence demonstrating that immature oocyte retrieved during the luteal phase can mature in vitro and be fertilized to produce viable embryos.

In vitro grown human ovarian follicles from cancer patients support oocyte growth.

Background: Young female adult and adolescent cancer patients facing life-preserving but fertility-threatening chemo- or radiation-therapy are increasingly seeking options to protect their reproductive potential. Ovarian tissue cryopreservation with transplantation is a promising technique to safeguard fertility in cancer patients. However, this method may risk re-introduction of the original cancer to the survivor of the disease.

Prepubertal primordial follicle loss in mice is not due to classical apoptotic pathways.

More than half of the primordial follicles that are formed by Day 6 of postnatal life in the mouse will be eliminated from the ovary by the time of puberty. Apoptosis, a form of programmed cell death, is one mechanism by which these follicles could be actively lost. To investigate whether apoptosis is responsible for the loss of primordial follicles, follicular atresia was examined during the prepubertal period, when follicles die and are cleared from the ovary at an extremely high rate.

Regulation of neonatal Sertoli cell development by thyroid hormone receptor alpha1.

Neonatal hypothyroidism increases adult Sertoli cell populations by extending Sertoli cell proliferation. Conversely, hyperthyroidism induces premature cessation of Sertoli cell proliferation and stimulates maturational events like seminiferous tubule canalization. Thyroid hormone receptors alpha1 and beta1, which are commonly referred to as TRalpha1 and TRbeta1, respectively, are expressed in neonatal Sertoli cells.

Cell-cycle inhibitors p27Kip1 and p21Cip1 regulate murine Sertoli cell proliferation.

Thyroid hormone inhibits neonatal Sertoli cell proliferation and recent results have shown that thyroid hormone upregulates cyclin-dependent kinase inhibitors (CDKIs) p27Kip1 and p21Cip1 (also known as CDKN1B and CDKN1A, respectively) in neonatal Sertoli cells. This suggests that these CDKIs, which negatively regulate the cell cycle, could be critical in Sertoli cell proliferation. Consistent with this hypothesis, mice lacking p27Kip1 develop testicular organomegaly, but Sertoli cell numbers have not been determined.