Radiotherapy exposure directly damages the uterus and causes pregnancy loss
Meaghan J. Griffiths, Sarah A. Marshall, Fiona L. Cousins, Lauren R. Alesi, Jordan Higgins, Saranya Giridharan, Urooza C. Sarma, Ellen Menkhorst, Wei Zhou, Alison S. Care, Jacqueline F. Donoghue, Sarah J. Holdsworth-Carson, Peter A.W. Rogers, Evdokia Dimitriadis, Caroline E. Gargett, Sarah A. Robertson, Amy L. Winship, Karla J. Hutt
Meaghan J. Griffiths, Sarah A. Marshall, Fiona L. Cousins, Lauren R. Alesi, Jordan Higgins, Saranya Giridharan, Urooza C. Sarma, Ellen Menkhorst, Wei Zhou, Alison S. Care, Jacqueline F. Donoghue, Sarah J. Holdsworth-Carson, Peter A.W. Rogers, Evdokia Dimitriadis, Caroline E. Gargett, Sarah A. Robertson, Amy L. Winship, Karla J. Hutt
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Research Article Reproductive biology Vascular biology

Radiotherapy exposure directly damages the uterus and causes pregnancy loss

Abstract

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.

Authors

Meaghan J. Griffiths, Sarah A. Marshall, Fiona L. Cousins, Lauren R. Alesi, Jordan Higgins, Saranya Giridharan, Urooza C. Sarma, Ellen Menkhorst, Wei Zhou, Alison S. Care, Jacqueline F. Donoghue, Sarah J. Holdsworth-Carson, Peter A.W. Rogers, Evdokia Dimitriadis, Caroline E. Gargett, Sarah A. Robertson, Amy L. Winship, Karla J. Hutt

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Figure 3

Radiotherapy exposure impairs decidualization in vitro and in vivo.

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Radiotherapy exposure impairs decidualization in vitro and in vivo. (A) ...
(A) Ovariectomized (OVX) adolescent female wild-type mice exposed to 7 Gy TBI (IRR) or nonirradiated controls (Non-IRR) were hormone-primed with estradiol (E2) and a progesterone pellet (P4) before undergoing artificial decidualization. (B) Representative images of uteri collected 4 days after artificial decidualization are shown. (C) Relative uterine weight (UW) to body weight (BW) was quantified. (D) Expression of genes key for decidualization and hormone responses — Esr1 and Pgr — was analyzed by qPCR. (E) Cultured primary human endometrial stromal fibroblasts were exposed to 7 Gy γ-irradiation (IRR) or left as nonirradiated controls (Non-IRR) and then artificially decidualized in vitro. (F) Representative images highlighting cell morphology between nondecidualized (Non-Decid) and decidualized (Decid) cells are shown. (G) The concentration of prolactin in the media was quantified by ELISA. (H) Prolactin (PRL) gene expression was assessed by qPCR. Scale bars: 5 mm. Data are mean ± SEM; unpaired t test (2 groups; parametric distribution), Mann-Whitney test (2 groups; nonparametric distribution) or 1-way ANOVA with Holm-Šídák post hoc test; *P < 0.05, **P < 0.01, ***P < 0.001; n = 2–9/group. Hand2, heart and neural crest derivatives expressed 2.