Methods for Studying Uterine Contributions to Pregnancy Establishment in an Ovariectomized Mouse Model.

For pregnancy to be established, a viable blastocyst must successfully interact with a receptive uterine lining (endometrium) to facilitate implantation and placenta formation and enable ongoing pregnancy. The limitations to pregnancy success caused by embryonic defects are well known and have been largely overcome in recent decades with the rise of in vitro fertilization (IVF) and assisted reproductive technologies. As yet, however, the field has not overcome the limitations caused by an inadequately receptive endometrium, thus resulting in stagnating IVF success rates. Ovarian and endometrial functions are closely intertwined, as hormones produced by the ovary are responsible for the endometrium's menstrual cyclicity. As such, when using rodent models of pregnancy, it can be difficult to ascertain whether an observed result is due to an ovarian or uterine deficit. To overcome this, an ovariectomized mouse model was developed with embryo transfer or artificial decidualization to allow the study of uterine-specific contributions to pregnancy. This article will provide instructions on how to perform ovariectomy and offer insights into various techniques for supplying exogenous hormones to support successful artificial decidualization or pregnancy following embryo transfer from healthy donors. These techniques include subcutaneous injection, slow-release pellets, and osmotic mini pumps. The key advantages and disadvantages of each method will be discussed, enabling researchers to choose the best study design for their specific research question.

Radiotherapy exposure directly damages the uterus and causes pregnancy loss.

Female cancer survivors are significantly more likely to experience infertility than the general population. It is well established that chemotherapy and radiotherapy can damage the ovary and compromise fertility, yet the ability of cancer treatments to induce uterine damage, and the underlying mechanisms, have been understudied. Here, we show that in mice total-body γ-irradiation (TBI) induced extensive DNA damage and apoptosis in uterine cells. We then transferred healthy donor embryos into ovariectomized adolescent female mice that were previously exposed to TBI to study the impacts of radiotherapy on the uterus independent from effects to ovarian endocrine function. Following TBI, embryo attachment and implantation were unaffected, but fetal resorption was evident at midgestation in 100% of dams, suggesting failed placental development. Consistent with this hypothesis, TBI impaired the decidual response in mice and primary human endometrial stromal cells. TBI also caused uterine artery endothelial dysfunction, likely preventing adequate blood vessel remodeling in early pregnancy. Notably, when pro-apoptotic protein Puma-deficient (Puma-/-) mice were exposed to TBI, apoptosis within the uterus was prevented, and decidualization, vascular function, and pregnancy were restored, identifying PUMA-mediated apoptosis as a key mechanism. Collectively, these data show that TBI damages the uterus and compromises pregnancy success, suggesting that optimal fertility preservation during radiotherapy may require protection of both the ovaries and uterus. In this regard, inhibition of PUMA may represent a potential fertility preservation strategy.

Checkpoint inhibitor immunotherapy diminishes oocyte number and quality in mice.

Loss of fertility is a major concern for female reproductive-age cancer survivors, since a common side-effect of conventional cytotoxic cancer therapies is permanent damage to the ovary. While immunotherapies are increasingly becoming a standard of care for many cancers-including in the curative setting-their impacts on ovarian function and fertility are unknown. We evaluated the effect of immune checkpoint inhibitors blocking programmed cell death protein ligand 1 and cytotoxic T lymphocyte-associated antigen 4 on the ovary using tumor-bearing and tumor-free mouse models. We find that immune checkpoint inhibition increases immune cell infiltration and tumor necrosis factor-α expression within the ovary, diminishes the ovarian follicular reserve and impairs the ability of oocytes to mature and ovulate. These data demonstrate that immune checkpoint inhibitors have the potential to impair both immediate and future fertility, and studies in women should be prioritized. Additionally, fertility preservation should be strongly considered for women receiving these immunotherapies, and preventative strategies should be investigated in future studies.

Development of an embryo transfer model to study uterine contributions to pregnancy in vivo in mice.

A mouse model to study uterine specific contributions to pregnancy.Maternal environmental exposures can exert impacts on the ability of the uterus to sustain healthy pregnancy. To establish an in vivo model to study this, we designed an ovariectomized mouse embryo transfer model. The rationale being future studies could expose recipient female mice to variables such as altered diet, drug, temperature, air, or activity exposure among others to define their impacts on the uterine contribution to pregnancy. Ovariectomy ensures the extent of the variable is limited to exploring outcomes on uterine but not ovarian function. Embryo transfer from healthy, unexposed donor mice guarantees that any impacts of the variable are attributed to the maternal uterine but not the embryonic state. Pregnancy outcomes including pregnancy success (number of implantation sites) and viability (number of viable vs resorbing implantation sites) can be investigated. Numerous functional outcomes can be assessed, including developmental competence encompassing decidual, placental, fetal, and vascular morphology and/or function (e.g. measured using Doppler ultrasound, comparisons of fetal growth, or molecular or histological characterization of the decidua, placenta, and fetal tissues). LAY SUMMARY: Many pregnancy complications occur because of problems in the womb (uterus), specifically the womb lining. There is a close relationship between the hormone function of the ovaries and the uterus and distinguishing between the way they both impact pregnancy success is difficult in existing studies using animals. Here, we developed a new animal model to utilize in addressing these gaps in our understanding of pregnancy.

Prolonged atrazine exposure beginning in utero and adult uterine morphology in mice.

Through drinking water, humans are commonly exposed to atrazine, a herbicide that acts as an endocrine and metabolic disruptor. It interferes with steroidogenesis, including promoting oestrogen production and altering cell metabolism. However, its precise impact on uterine development remains unknown. This study aimed to determine the effect of prolonged atrazine exposure on the uterus. Pregnant mice (n = 5/group) received 5 mg/kg body weight/day atrazine or DMSO in drinking water from gestational day 9.5 until weaning. Offspring continued to be exposed until 3 or 6 months of age (n = 5-9/group), when uteri were collected for morphological and molecular analyses and steroid quantification. Endometrial hyperplasia and leiomyoma were evident in the uteri of atrazine-exposed mice. Uterine oestrogen concentration, oestrogen receptor expression, and localisation were similar between groups, at both ages (P > 0.1). The expression and localisation of key epithelial-to-mesenchymal transition (EMT) genes and proteins, critical for tumourigenesis, remained unchanged between treatments, at both ages (P > 0.1). Hence, oestrogen-mediated changes to established EMT markers do not appear to underlie abnormal uterine morphology evident in atrazine exposure mice. This is the first report of abnormal uterine morphology following prolonged atrazine exposure starting in utero, it is likely that the abnormalities identified would negatively affect female fertility, although mechanisms remain unknown and require further study.

Do cancer therapies damage the uterus and compromise fertility?

BACKGROUND: As cancer survival rates improve, understanding and preventing the adverse off-target and long-term impacts of cancer treatments, including impacts on fertility, have become increasingly important. Cancer therapy-mediated damage to the ovary and depletion of the primordial follicle reserve are well characterised. However, our knowledge of the full extent of damage to the rest of the female reproductive tract, in particular the uterus, is limited. OBJECTIVE AND RATIONALE: Improving our understanding of the off-target effects of cancer therapies on the entire female reproductive tract is a critical step towards developing truly effective strategies to protect the fertility of cancer survivors. The objective of this narrative review was to critically evaluate the available literature regarding the capacity for the uterus to sustain a healthy pregnancy following exposure to radiotherapy or chemotherapy. SEARCH METHODS: The authors performed PubMed (Medline) searches using the following key words: uterus, cancer survivors, radiotherapy, chemotherapy, pregnancy outcome, fertility preservation, infertility. There were no limits placed on time of publication. OUTCOMES: Overall, there were major limitations to the current available literature, meaning that interpretations should be taken with caution. Despite these drawbacks, data suggest that the uterus may sustain off-target damage, with the extent of damage dependent on the type of cancer treatment and patient age. Specifically, uterine growth is stunted and resistant to hormone replacement therapy in prepubertal girls receiving abdominal, pelvic or whole-body radiotherapy. In contrast, females treated with radiotherapy post-puberty can benefit from hormone replacement therapy, as demonstrated by increased uterine volume and function. No live births have been reported in women previously exposed to radiotherapy after transplantation of cryopreserved ovarian tissue, even when menstruation returns. However, this technique has proven to be a successful fertility preservation method for women previously treated with chemotherapy. Obstetricians commonly report that women who maintain sufficient ovarian function can achieve pregnancy naturally following radiotherapy, but they have thin and/or fibrotic myometrium at delivery, compromising safe delivery and subsequent pregnancy. Furthermore, women exposed to either radiotherapy or chemotherapy have a higher prevalence of preterm birth and low birth weight infants, even in those with normal ovarian function or when oocyte donation is utilised. The mechanisms of potential uterine damage are poorly understood. While the myometrium, vasculature and endometrial progenitor cells are possibly targets, further studies are clearly required and well-controlled animal models could provide the best avenue for these types of future investigations. WIDER IMPLICATIONS: Female cancer survivors experience greater rates of early pregnancy loss and complications, suggesting that cancer therapy-induced damage to the uterus contributes to infertility. Despite clinical reports dating back to 1989, we highlight a surprising lack of detail in the literature regarding the precise nature and extent of off-target damage inflicted to the uterus in response to cancer therapies. Young women requiring cancer treatment, and the clinicians treating them, must be equipped with accurate information to aid informed decision-making regarding cancer treatment regimens as well as the development and use of effective fertility preservation measures. As the current literature on the impacts of cancer treatments is limited, we hope that our narrative review on this subject will stimulate more research in this important field.