Low Ovarian Reserve Clinical Trial
Official title:
Can Dormant Ovarian Follicles From Perimenopausal Women Become Gonadotropin Responsive by Incubation With PTEN Inhibitor and PI3K Activating Peptide?
The purpose of this study to obtain ovarian cortical fragments from perimenopausal patients, who undergo pelvic organ surgery and test whether treatment with PTEN inhibitor and PI3K activating peptide would induce these fragments to produce FSH responsive follicles in the nude mouse model.
Introduction Women stop menstruating at the mean age of 51, yet pregnancies become much less
prevalent beyond 40, with pregnancy at 43 being a relative rarity. Current common perception
attributes the regression of fertility to depletion of the primordial follicles' pool
(Burger et al. 2008). The decline in fertility may result not necessarily from a sharp
depletion of the primordial follicle pool (Hansen et al. 2008) but may be due to failure of
adequate transition from primordial to antral, gonadotropin-responsive follicles. It is not
infrequent to encounter a fertility patient at her late thirties or early forties, who would
not respond to the most extreme doses of exogenous FSH, but will nevertheless continue to
menstruate until the age of 50. The usual practice is to refer these patients to oocyte
donation programs.
Recently, Li et al. (2010) demonstrated that incubation of neonatal mouse ovarian fragments
with an inhibitor of the Phosphatase with TENsin homology deleted in chromosome 10 (PTEN)
phosphatase and a PI3K activating peptide, increased nuclear exclusion of Foxo3 and
propelled large numbers of dormant primordial follicles into becoming FSH-responsive antral
follicles. Furthermore, in the nude mice model (mice lacking immune system) they showed that
transplanted human ovarian fragments containing mainly primordial follicles from surgical
specimens, treated by the same incubation, also underwent activation of dormant follicles to
derive preovulatory follicles containing mature oocytes.
Based on all the above we hypothesize, that ovaries of women at their perimenopausal years
could be propelled to become FSH-responsive, using incubation with PTEN inhibitor and PI3K
activating peptide to activate dormant primordial follicles.
If found feasible, this technique could provide hope of achieving fertility to patients who
would otherwise be referred to receive oocyte donation.
Aim of the proposed study To obtain ovarian cortical fragments from perimenopausal patients,
who undergo gynecological surgery, and test whether treatment with PTEN phosphatase and PI3K
activating peptide would induce these fragments to produce FSH responsive follicles in the
nude mouse model.
Study subjects and specimen harvest Up to ten women, older than 45 years, who are scheduled
to gynecological operation, will be asked to provide half of an ovary for the study. The
tissue will then be cut to multiple fragments, suitable for cryopreservation.
Laboratory methods Cryopreservation of ovarian fragments will use a vitrification protocol
similar to earlier report for oocyte cryo-storage (Yoon et al. 2003). Because the
cryo-preservation reagents can easily penetrate primordial follicles as compared with the
large oocytes, we anticipate efficient preservation of these follicles. In young patients,
one 1 mm cortical cubes contains ~50 primordial follicles.
Three tissue samples from each patient will be transferred to the Hsueh laboratory in
Stanford (attached letter), and will be thawed for in vitro activation followed by
xeno-transplantation using the same protocol as that described by Li et al. from that
laboratory. (Li et al. 2010). The in vitro incubation will be in bpV(pic) (Calbiochem), a
PTEN inhibitor, which allows the activation of dormant follicles. and a cell-permeable
phospho-peptide (740Y-P) (Tocris) capable of binding to the SH2 domain of the p85 regulatory
subunit of PI3K to stimulate enzyme activity. Activated PI3K converts phosphatidylinositol
(4, 5)-bisphosphate (PIP2) to phosphatidylinositol (3-5)-trisphosphate (PIP3), whereas the
PTEN inhibitor prevents the conversion of PIP3 back to PIP2. Accumulated PIP3, in turn,
could stimulate the phosphorylation of Akt and increase the nuclear exclusion of the
transcriptional factor Foxo3.
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Intervention Model: Single Group Assignment, Masking: Open Label, Primary Purpose: Basic Science
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