Ovarian stem cell


Ovarian stem cells are oocytes formed in ovarian follicle before birth in female mammals. Interest has recently been devoted to OSCs, whose isolation from female ovaries, followed by their in vitro culture, led to their maturation to OLCs, namely, neo-oocytes comparable to viable eggs suitable for IVF. Translation of these data to FP clinical application creates new hope in the treatment of infertility.

History

1870s

Studies performed on humans, dogs, and cats revealed that oocyte production stops shortly after birth. If this is true, it would mean that females have a finite number of oocytes that are formed before they are born.

1920s

Studies demonstrated that 'new' oocytes could be produced after damage to the fowl ovary. Additional research demonstrated that rats which had one ovary removed before puberty produced the same number of mature eggs as healthy rats. This would suggest that some compensatory mechanism is at work; an increase in immature follicle development could have occurred, or post-natal oogenesis may have been activated. However, such theories were merely speculative.

1950s

Sir Solomon Zuckerman examined reports from 1900 to 1950 of multiple species and concluded that "no experimental or histological evidence supports the view that oogenesis continues after puberty". This dogma was rarely challenged.

1960s

Studies in adult primates demonstrated the presence of oogonia in mitosis as well as oocytes at successive stages of meiosis, leading to the conclusion that postnatal oogenesis takes place. Mitotic cells were not specifically stained for oocyte markers, so identification was limited to histological analysis of haematoxylin-stained sections. It is therefore possible that granulosa/theca cells, or other support cells within the ovary, could be dividing.

1990s

's postnatal oogenesis cycle is well characterized; however, invertebrates lack the genetic similarity to allow translation of the same findings into mammals.

2000s

Mice were found to have presumptive oocyte stem cells expressing mitotic gene markers, indicating that they were dividing. A potential functional role of OSCs in vivo has also been demonstrated by the growth of GFP-labeled OSCs into follicles when transplanted into wild-type mouse ovaries. There is widespread scientific disagreement about whether mammalian oogenesis occurs post-natally.

2010s

In female human cancer patients that were treated with ABVD led to an increase in mean follicular density. So perhaps under certain perturbed circumstances, OSCs can be stimulated to form follicles.

Structure and function

The structure and characteristics of ovarian stem cells are controversial, since there is currently no definitive evidence that they exist. However, scientists that do believe ovarian stem cells exist have described the stem cells as having the ability to finish meiotic progression, which they believe they have confirmed through cytometry and in situ hybridisation.
Using fluorescent proteins to label the OSCs, scientists have demonstrated OSCs that can form primordial follicles that are capable of further growth and development. However, these findings are not agreed upon by the scientific community.

Markers

Markers for ovarian stem cells are also a source of contention.
Markers previously used are:
  • DDX4
  • STRA-8
  • SCP-3
  • SPO 11
  • Dmc 1
DDX4 protein is a commonly used marker as its expression is associated with germ cells. The identification of these cells revolves around their key ability to undergo mitotic division. Several studies have identified isolation of cells expressing DDX4, or VASA in rodents. Isolation has been based on expression of DDX4 which is an RNA helicase DEAD box polypeptide 4, in the ovary this is only expressed in the germline. DDX4 has been criticized as a maker mainly due to the assumption that DDX4 does not have a surface epitope and is only an intracellular protein. However recent evidence has shown that cell populations from the human ovary can express DDX4 on the cell surface. Therefore, invalidating ddx4 as a marker.

Potential clinical

If OSCs can be definitively identified and better understood, then it is proposed that manipulation of these cells could present a novel treatment method for Premature Ovarian Insufficiency, female infertility, and post-menopausal health conditions. This would rely on successful identification, removal, cryopreservation, and re-injection of OSCs and such a protocol currently only exists in theory.
Removal and cryopreservation of OSCs from female patients prior to ovotoxic treatments such as chemotherapy, and subsequent replacement into the patient's ovary, has been proposed as a way to allow women to produce their own oocytes and conceive their own child after follicle-depleting treatment.
Re-injection of OSCs into the ovary following menopause may restore the population of hormone secreting oocytes, restoring endocrine function in the ovary and resulting in the reversal of the unpleasant symptoms of menopause.
Removal and preservation of OSCs in advance of anticipated POI, followed by re-injection when the patient desires pregnancy may be a future fertility treatment for women suffering from POI.
Ultimately, until OSCs have been irrevocably characterized, and a more developed understanding of the ovarian environment has been achieved, these treatments remain hypothetical.