Ibuprofen is deleterious for the development of first trimester human fetal ovary ex vivo

Abstract

STUDY QUESTION

Does ibuprofen use during the first trimester of pregnancy interfere with the development of the human fetal ovary?

SUMMARY ANSWER

In human fetuses, ibuprofen exposure is deleterious for ovarian germ cells.

WHAT IS KNOWN ALREADY

In utero stages of ovarian development define the future reproductive capacity of a woman. In rodents, analgesics can impair the development of the fetal ovary leading to early onset of fertility failure. Ibuprofen, which is available over-the-counter, has been reported as a frequently consumed medication during pregnancy, especially during the first trimester when the ovarian germ cells undergo crucial steps of proliferation and differentiation.

STUDY DESIGN, SIZE, DURATION

Organotypic cultures of human ovaries obtained from 7 to 12 developmental week (DW) fetuses were exposed to ibuprofen at 1–100 μM for 2, 4 or 7 days. For each individual, a control culture (vehicle) was included and compared to its treated counterpart. A total of 185 individual samples were included.

PARTICIPANTS/MATERIALS, SETTING, METHODS

Ovarian explants were analyzed by flow cytometry, immunohistochemistry and quantitative PCR. Endpoints focused on ovarian cell number, cell death, proliferation and germ cell complement. To analyze the possible range of exposure, ibuprofen was measured in the umbilical cord blood from the women exposed or not to ibuprofen prior to termination of pregnancy.

MAIN RESULTS AND THE ROLE OF CHANCE

Human ovarian explants exposed to 10 and 100 μM ibuprofen showed reduced cell number, less proliferating cells, increased apoptosis and a dramatic loss of germ cell number, regardless of the gestational age of the fetus. Significant effects were observed after 7 days of exposure to 10 μM ibuprofen. At this concentration, apoptosis was observed as early as 2 days of treatment, along with a decrease in M2A-positive germ cell number. These deleterious effects of ibuprofen were not fully rescued after 5 days of drug withdrawal.

LARGE SCALE DATA

N/A.

LIMITATIONS, REASONS FOR CAUTION

This study was performed in an experimental setting of human ovaries explants exposed to the drug in culture, which may not fully recapitulate the complexity of in vivo exposure and organ development. Inter-individual variability is also to be taken into account.

WIDER IMPLICATIONS OF THE FINDINGS

Whereas ibuprofen is currently only contra-indicated after 24 weeks of pregnancy, our results points to a deleterious effect of this drug on first trimester fetal ovaries ex vivo. These findings deserve to be considered in light of the present recommendations about ibuprofen consumption pregnancy, and reveal the urgent need for further investigations on the cellular and molecular mechanisms that underlie the effect of ibuprofen on fetal ovary development.

Introduction

Nonsteroidal anti-inflammatory drugs (NSAIDs) are one of the most commonly used over-the counter (OTC) medications for the treatment of pain, inflammation and fever, with ibuprofen representing a significant share of the market (Kristensen et al., 2016). In 2013, up to 28.3% of pregnant women reported the use of ibuprofen at some stages during their pregnancy (Van Marter et al., 2013), ranking ibuprofen as the second most used OTC analgesic after paracetamol (Thorpe et al., 2013). Although ibuprofen is clearly contra-indicated from 24 weeks of gestation onwards because of well-known risks of malformations, guidelines are more equivocal prior to 24 weeks. Moreover, the consumption of ibuprofen during early pregnancy can also occur due to unawareness of the pregnant state, or through ignoring the composition of the self-medicated drugs that are being used.

During fetal life, the ovarian germ cell population goes through a series of complex processes, initiating with germ cell specification and migration into the gonad, followed by proliferation and entry into meiosis, and culminating in the formation of primordial follicles (Edson et al., 2009). More specifically, during the first trimester of pregnancy, ovarian dynamic developmental events are regulated by the germ cell niche which govern the balance between germ cell proliferation, differentiation and cell death (Kerr et al., 2013). Normal fetal development of the ovary, i.e. the establishment of a dynamic—but finite—reserve of follicles, defines the future reproductive capacity of the woman (McGee and Hsueh, 2000). A poorly stocked initial reserve will result in a shortened reproductive life span, early menopause or infertility (Nelson et al., 2013), events that occur decades later.

Ibuprofen, like all NSAIDs, works by blocking cyclooxygenases (COX), key enzymes involved in the first rate-limiting step in the conversion of arachidonic acid into prostaglandins (PG) (Rainsford, 2009). In the human fetal ovary, the constitutively expressed COX1 is primarily found in somatic cells, whereas the inducible COX2 is restricted to the periphery of the ovary where pluripotent germ cells are located, inferring COX2 involvement in ovarian development (Bayne et al., 2009). Despite evidence implicating PGs and COXs as critical factors in adult female reproductive function (Duffy, 2015; Sugimoto et al., 2015), little is known about their precise function in human ovarian organogenesis. However, prostaglandin E2 (PGE2) signaling was related to enhanced expression of germ cell survival genes in human fetal ovaries (Bayne et al., 2009), and analgesics were found to induce cell death in human ovarian cancer cell lines (Andrews et al., 2008; Zerbini et al., 2011; Duncan et al., 2012; Lima et al., 2015). Therefore, we hypothesized that exposure of the developing ovary to COX inhibitors may have toxic effects on germ and/or somatic cells.

The scientific community is raising increasing concerns about the impact of environmental and pharmaceutical chemicals on the fetus development. This includes pain medications which induce endocrine disruption of the human fetal testis (Mazaud-Guittot et al., 2013; Kristensen et al., 2016; Ben Maamar et al., 2017) and result in infertility and premature ovarian insufficiency in mice and rats (Dean et al., 2016; Holm et al., 2016; Johansson et al., 2016). To date, there is insufficient evidence concerning short-term effects of ibuprofen on fetal organogenesis, and the prediction of long-term adverse effects of this common medicine in adults. Therefore, the objective of the present study was to assess the possible effects of ibuprofen on the human fetal ovary, with a focus on cell viability, window of sensitivity, target specificity and reversibility, during the key stages of female fetal germ cell development along the first trimester. To this end, we used an original ex vivo model of human fetal ovary organotypic culture, which we exposed to a range of ibuprofen concentrations for various durations. Our results show that in the developing human ovary, germ cells are particularly sensitive to ibuprofen damage.

Materials and Methods

Ethics statement

First trimester human fetuses (7–12 developmental weeks (DW), n = 185) were obtained from legally induced terminations of pregnancy performed in Rennes University Hospital from October 2013 to June 2017. No termination of pregnancy was due to fetal abnormality. Tissues were collected following women’s written consent, in accordance with the legal procedure agreed by the National agency for biomedical research (authorization #PFS09-011; Agence de la Biomédecine) and the approval of the Local ethics committee of Rennes Hospital (advice # 11-48) approved the whole procedure.

Human fetal ovary collection

The termination of pregnancy was induced using a standard combined Mifegyne® (mifepristone) and Cytotec® (misoprostol) protocol, followed by aspiration. A subset of women received either 400 or 800 mg of ibuprofen for preventive analgesia or none. The potential effect of ibuprofen intake prior termination was taken into account when analyzing the data. Gestational age was determined by ultrasound, and further confirmed by measurement of foot length. Blood was collected from umbilical cord from fetuses older than 8 DW, samples were centrifuged and serum was stored at −80°C. The ovaries were recovered from the aspiration products using a binocular microscope (Olympus SZX7, Lille, France). They were immediately placed in ice-cold phosphate-buffered saline (PBS).

Ex vivo culture

The recovered ovaries were cut into ~1 mm³ pieces and explants were cultured in cell culture inserts (0.4 μM pores) placed in 24-well companion plates (Becton-Dickinson, Le Pont de Claix, France). Ovaries from fetuses younger than 10 DW were cultured in two separate wells, one ovary being exposed to vehicle and the other one to ibuprofen. Ovaries from fetuses older than 10 DW were either cultured in one well (for hormone measurements) or four wells for multiple culture (i.e. one control and three ibuprofen concentrations) conditions. Ovaries were halved lengthways and each half was divided into 2–3 ovary pieces. Each well was filled with 400 μl of phenol red-free Medium 199 (Invitrogen Life Technologies, Cergy Pontoise, France) supplemented with 50 μg/ml gentamycin, 2.5 μg/ml fungizone (Sigma Aldrich Chemicals, Saint-Quentin Fallavier, France) and insulin (1 g/l), transferrin (0.55 g/l) and sodium selenite (0.67 mg/l) (Sigma Aldrich Chemicals). Cultures were incubated at 37°C for up to 7 days under a humidified atmosphere of 95% air and 5% CO₂. The medium was replaced with fresh media after the first 24 h and then every 48 h, immediately snap-frozen on dry ice and stored at −80°C. Explants were immediately exposed to treatments by adding to the medium either vehicle at a final concentration of 0.1% v/v (dimethyl sulfoxide; DMSO) or ibuprofen (Sigma Aldrich Chemicals). Since therapeutic concentrations of ibuprofen in the plasma range from 10 to 200 μM (Kallstrom et al., 1988; Karttunen et al., 1990), concentrations of analgesics used in the current study were 10 μM to test common treatment effect, and 1–100 μM to assess potential dose–response effects.

Single cell dissociation and flow cytometry

Explants were submitted to a sequential enzymatic digestion procedure adapted from Le Bouffant et al. (2010) in order to obtain single cell suspensions. Briefly, ovarian pieces were first digested in 0.25% Trypsin–0.02% EDTA (w/v) (#T4049, Sigma-Aldrich) for 5 min at 37°C. Trypsin digestion was stopped by adding 10% fetal bovine serum in M199 media and samples were centrifuged at 350g for 5 min. The samples were then further digested with 2 mg/ml collagenase (#C0130, Sigma-Aldrich) and 0.05 mg/ml DNase (#DN25, Sigma-Aldrich) in M199 media for 5 min at 37°C. Dispersed cells were centrifuged and resuspended in PBS. Before proceeding to labeling, cell counting was performed on a Malassez Hemocytometer (Trypan blue exclusion of live cells was included). Apoptotic cells were labeled with FITC Annexin-V (BD pharmingen #556419) following the manufacturer’s recommendations, coupled to necrotic nucleus staining with 3 μg/ml 7-Aminoactinomycin D (7-AAD; FluoProbes, Interchim #132303) in 100 μl binding buffer. In Annexin-V versus 7-AAD contour plots with quadrant gates, dead cells included apoptosis (early: AnnV+7AAD– and late: AnnV+7AAD+) plus necrosis (AnnV–7AAD+) (Suppl. Fig. S1B). To identify germ cells, a plasma membrane M2A labeling was performed using anti-D240 mouse monoclonal antibody (abcam # 77854, diluted 1:200) in the presence of 10% FCS and incubated 30 min at room temperature (RT). Detection was allowed by a R-Phycoerythrin coupled anti-Mouse IgG (H + L) (Jackson ImmunoResearch # 715-116-150). To evaluate cell death and germ cell dynamics, a minimum of twenty thousand cells were acquired and analyzed by flow cytometry using a FACSCalibur (BD Biosciences) equipped with CellQuest software.

Immunohistochemistry and stereology

Immunohistochemistry was performed on 4% paraformaldehyde-PBS and Bouin solution-fixed, paraffin-embedded ovaries. Each fifth 5 μm-thick section was used for immunohistochemistry with cell-specific labeling. After unwaxing and rehydration, sections were blocked for 20 min at RT with 10% bovine serum albumin (BSA) in PBS before overnight incubation at 4°C with the primary antibody diluted in Dako antibody diluent (Dako Cytomation, Trappes, France). Apoptotic cells were stained with a rabbit anti-cleaved caspase-3 antibody (1:150; Cell Signaling Tech. #9661, Ozyme, Saint Quentin en Yvelines, France), proliferating cells with a mouse anti-Ki67 antibody (1:100; Dako #M7240) and germ cells with a mouse anti-M2A antibody (1:100, clone D2-40; Abcam #ab77854) or a rabbit anti-LIN28 (1:300, Abcam #ab46020). An antigen retrieval step at 80°C for 40 min with 10 mM Tris, 1 mM EDTA buffer, pH 9 for cleaved caspase-3 or 10 mM citrate buffer, pH 6 for Ki67, M2A and LIN28 was necessary. The secondary antibodies were biotinylated goat anti-rabbit or rabbit anti-mouse antibodies (1:500; E0342 and E0464, respectively, Dako). Sections were developed with streptavidin-horseradish peroxidase (Vectastain ABC kit, Vector Laboratories, Burlingame, CA, USA) and 3,3’-diaminobenzidine tetrahydrochloride (Sigma Aldrich Chemicals) and counterstained with hematoxylin. Stained sections were examined and photographed under the light microscope (Olympus BX51). Pictures of sections were captured with a scanner NanoZoomer 2.0 RS (Hamamatsu, Tokyo, Japan) at 40× magnification. The surfaces of 5–10 sections covering the whole explant were calculated with NDPview software (Hamamatsu, Tokyo, Japan). ImageJ software (US National Institutes of Health, Bethesda, MD, USA) was used to perform the cell counting based on stereological principles. Cells were counted in at least five sections and apoptotic cells counts reported as number per unit surface area of the section, while proliferating cells are reported as the percentage of Ki67-positive cells in a population of KI67-negative cells.

Prostaglandin measurement

Prostaglandin E2 (PGE2) levels were measured in culture media of ovarian explants after 1 day of exposure by an ELISA method (intra-assay CV 3.7–30.4% and inter-assay CV 6.4–35%; PG E2 EIA Kit—Monoclonal Cayman Chemical Company, Ann Arbor, MI, USA). Each sample was assayed in duplicate.

Ibuprofen assay

Ibuprofen was extracted from human plasma by solid phase extraction using 10 mg HLB Oasis cartridges (Waters, UK). Briefly, 50 μl plasma was enriched with 1ng deuterium-labeled acetaminophen (APAP-d4; Santa Cruz Biotechnology Inc.) as internal standard. Cartridges were conditioned with methanol and water, the sample loaded and washed with water − 5% methanol and then eluted with 1 ml methanol. The eluate was reduced to dryness under nitrogen at 40°C and reconstituted in mobile phase (100 μl water/acetonitrile (70:30, v/v)). Chromatographic separation was achieved by injecting 20 μl sample onto an Acquity UPLC system with an ACE Excel C18-AR column (150 × 2.1 mm; 2 μm) protected by a Kinetex KrudKatcher (Phenomenex) and operated at 30°C. Following separation, ibuprofen was detected on a QTrap 5500 triple quadrupole mass spectrometer (Seiex, Warrington, UK) operated in positive ion electrospray mode (5.5 kV, 550°C, ion source gas 60/40). Transitions monitored were m/z 207.1 → 161.1 and m/z 156.1 → 114.1 for ibuprofen and APAP-d4, respectively. The mobile phase consisted of 0.1% formic acid (Sigma Aldrich) in water and 0.1% formic acid in acetonitrile (B) at a flow rate of 0.5 ml/min. Gradient elution was achieved with a total run time of 9 min from 30% to 100% B. Ibuprofen eluted at 5.70 min and the internal standard, APAP-d4 eluted at 1.1 min.

Quantitative PCR

RNAs were extracted from ovarian explants using All Prep RNA/DNA/protein extraction kit (Qiagen) according to manufacturer’s instructions. Total RNAs (250 ng) were reverse transcribed with iScript cDNA synthesis kit (Biorad) and quantitative PCR was performed using the iTaq© universal SYBR green supermix (Biorad) according to manufacturer’s instructions in a Cfx384 OneTouch Real-Time PCR system (Biorad). The following amplification program was used: an initial denaturation of 3 min at 95°C, 40 cycles of 10 s denaturation at 95°C and 30 s at 62°C for annealing and extension. Dissociation curves were produced using a thermal melting profile performed after the last PCR cycle. To avoid amplification of contaminating genomic DNA, primer pairs were selected on either side of an intron. RPLP0 and RPS20 mRNA were used as internal controls for normalization (Table I). Results were calculated by the ΔΔCT method as n-fold differences in target gene expression, relative to the reference gene and calibrator sample which is constituted of an equal mixture of all the samples tested specifically in each tested organ.

Statistical analysis

For each multivariate analysis (cell death, cell counts), the statistical framework included (i) a global analysis of the effect of exposure to ibuprofen with a non-parametric Kruskal–Wallis sum rank test; (ii) every time a global significant effect was predicted, post-hoc non-parametric tests between control and ibuprofen-treated samples at different dose (from 1 to 100 μM) or age (from 7 to 12 DW) were performed (Wilcoxon or Mann–Whitney tests) and corrected for multiple testing with Bonferroni correction. Statistically significant post-hoc tests are indicated by (*) if the P-value corrected for multiple testing is below 0.05, (**) below 0.01 and (***) below 0.001. The free software environment for statistical computing and graphics R was used to perform the calculations.

Results

Ibuprofen crosses the placental barrier

To get insights into the range of concentrations of ibuprofen the fetus can be exposed to, ibuprofen concentration in the umbilical cord of 13 fetuses between 8 and 12 DW were measured (Table II). Ibuprofen concentrations were on average ± SEM 7.1 ± 5.02 μM (0.37–14.5 μM) when pregnant women had ingested 800 mg of ibuprofen 2–5 h prior to termination of pregnancy. Following ingestion of a single dose of 400 mg, ibuprofen concentration was on average ± SEM 2.09 ± 1.25 μM (0.83–6.95 μM) in the umbilical serum. Ibuprofen was non-detectable when the women had not used the analgesic (n = 5 samples). Consequently, concentrations covering the range of those found in the umbilical blood were chosen for subsequent ex vivo experiments.

Ibuprofen suppresses ovarian prostaglandin E2 production

One day of exposure to ibuprofen at 10 μM significantly decreased by 66.3% prostaglandin E2 (PGE2) production by explants aged 7–12 DW. The average level (±SEM) of PGE2 in control samples was 353 ± 73.9 pg/ml (n = 21), while levels were reduced to 119 ± 10.6 pg/ml (n = 16) in ibuprofen samples (P = 0.0062). No age-window of sensitivity for effect on PGE2 production was observed.

Ibuprofen impairs ovarian cell growth

Fetal ovarian explants (7–12 DW) were exposed for a week to a range of ibuprofen concentrations (from 1 to 100 μM) and the overall cell number was assessed (Fig. 1A). In uncultivated ovaries, the total number of cells per ovary increased exponentially from 2.6 × 10⁵ at 7 DW to 1.3 × 10⁶ at 12 DW (Suppl. Fig. S1A). This number further increased during the 7 days of culture in control conditions (Suppl. Fig. S1A). By contrast, when the organs were exposed to ibuprofen at the concentration of 10 μM for 7 days, the total ovarian cell count was significantly reduced (of −50% on average) compared to the unexposed controls, regardless of the developmental age of the explant (Fig. 1A). Although not significant for every age group, a reduction of the cell number was also observed with a 1 μM (−20% on average) and a 100 μM dose (−20% on average).

To determine whether ibuprofen-induced ovarian cell depletion could result from a decrease in cell proliferation, we scored the percentage of KI67-positive cells, including both somatic and germ cells, in histological sections after 7 days of culture (Fig. 1B and C). Before 8 DW, ibuprofen at all tested concentrations induced a massive decrease in the percentage of KI67-positive cell density. In 8–12 DW explants, cell proliferation also exhibited a statistically significant decline of KI67-positive cell density at 1 and 10 μM ibuprofen, but not at 100 μ M (Fig. 1C).

Ibuprofen induces cell death in the human fetal ovary

To determine whether the ibuprofen-induced reduction in the number of total ovarian cells could result from a loss of cell viability, cell death was quantified using a flow cytometry-based Annexin-V labeling coupled with 7-AAD nuclear staining (Suppl. Fig. S1B). Briefly, in Annexin-V versus 7-AAD contour plots with quadrant gates, dead cells include apoptotic cells displaying annexin V in the outer membrane (early: AnnV+7AAD– and late: AnnV+7AAD+) and necrotic cells in which the 7AAD dye could enter the nucleus (AnnV–7AAD+). To eliminate a potential cytotoxic impact of the organotypic culture itself, we assessed cell death before and during the 7 days of culture in control conditions (Suppl. Fig. S1C). Overall, the majority (94–96%) of the cells appeared to be viable, total cell death only reaching a maximum of 6%. This cell death rate remained stable from Day 0 to Day 7 regardless of the age of the explant.

Following ibuprofen exposure, the percentage of global cell death, including both apoptotic and necrotic death, was consistently higher compared to vehicle-exposed explants for both 7 DW fetuses (P = 0.0028) and 8–12 DW fetuses (P < 0.001) (Fig. 2A). Whilst 1 μM ibuprofen induced a weak cytotoxic effect, statistically significant only in the 8–12 DW group (P = 0.098, +42% at 7 DW, and P = 0.028, +45% at 8–12 DW), 10 μM ibuprofen concentration induced a marked accumulation of dead cells (P = 0.007, +85% at 7 DW, and P < 0.001, +170% at 8–12 DW) (Fig. 2A). Notably, the cytotoxic effect of 10 μM ibuprofen was intensified in the oldest explant group (10.47 ± 2.11 versus 16.14 ± 1.88; Means ± SEM of 7 versus 8–12 DW). When uncoupling apoptosis from necrosis, only the former cell death mechanism significantly increased in both exposed age groups (Fig. 2A).

To further investigate the effects on cell death, a histological analysis on ovarian explant sections was carried out using cleaved caspase-3 staining as a hallmark of apoptosis (Fig. 2B and C). Overall, exposure to ibuprofen for 7 days resulted in an increase in the density of cleaved caspase-3-positive cells for both 7 and 8–12 DW groups; however this only reached statistical significance in 8–12 DW fetuses (P < 0.001) compared to 7 DW fetuses (P = 0.072) (Fig. 2C). Both the 10 and 100 μM concentrations of ibuprofen induced a dramatic accumulation of apoptotic cells (P < 0.001, +208%, and +182%, respectively) in 8–12 DW fetuses, whereas the 1 μM dose–response did not pass the significance threshold. It is noteworthy that the quantitative analysis could not be performed in several 10 and 100 μM ibuprofen-exposed tissue sections (7 and 2 individuals, respectively) due to a massive degradation and loss of integrity of the tissue itself. These data indicate that ibuprofen is cytotoxic, resulting in apoptosis in 7–12 DW fetal ovaries, with exacerbated effect when gestational age of the fetus increases. Quantitative PCR analysis of several cell proliferation (marker of proliferation Ki67 MKI67), cycle (cyclin B1, CCNB1; Cyclin D1, CCND1; cyclin dependent kinase inhibitor 1 A, CDKN1A; checkpoint kinase 1, CHEK1) and death markers (tumor protein p53, TP53) showed a significant increase in the expression of TP53 and CDKN1A (Fig. 2D).

Ovarian fetal germ cells are highly sensitive to ibuprofen

The large size of the cleaved caspase-3 positive cells revealed by our histological study (Fig. 2B) suggested that the apoptotic cells in ibuprofen-exposed explants were likely to be germ cells. To verify our hypothesis, we used an antibody targeting LIN28, a marker of fetal germ cells (Childs et al., 2012), which revealed a decrease of the density of LIN28-positive cells (Fig. 3A and Suppl. Fig. S2A-B). Another marker of fetal germ cells, M2A (Jin et al., 2010) enabled the identification of two populations of germ cells (Suppl. Fig. S2C), as reflected by two distinct peaks in flow cytometry. (Suppl. Fig. S2D). In accordance with the unchanged viability profile observed along the 7 days of culture in control medium (Suppl. Fig. S1C), the percentage of M2A high-positive cells was not affected during the week of ex vivo culture of 7–12 DW explants (Suppl. Fig. S2E). By contrast, the proportion of M2A-germ cells increased steadily between the isolation of the organ (Day 0) and the end of the 7 days of culture.

As measured by flow cytometry, the population expressing high levels of M2A (10 to >15% of the total ovarian cells depending on the fetal age, Suppl. Fig. S2E) was significantly diminished following ibuprofen exposure (P = 0.0038 and P < 0.001, for 7 DW and 8–12 DW, respectively), with a large reduction when exposed to 10 μM (Fig. 3B). In terms of total M2A-positive cell number, the germ cell population expanded exponentially from 7 to 12 DW, increasing from 4 × 10⁴ to over 3 × 10⁵ M2A-high positive cells per ovary in control conditions (Fig. 3C). Following ibuprofen treatment, 1 and 100 μM doses both induced on average a 30% depletion of the germ cell count, whereas 10 μM ibuprofen led to a significant (50–75%) loss of germ cells, depending on the fetal age (Fig. 3C). Thus, unequivocally, ibuprofen exposure resulted in a decrease in the number of M2A-positive germ cells.

Ibuprofen-induced adverse effects after 2 days of exposure were not reversible by a 5-day withdrawal period

We next investigated the effects of shorter exposures of 10 μM ibuprofen, a dose shown to be deleterious for the organ (Fig. 4). Whereas overall cell death remained low in all control explants regardless of the fetal age, the percentage of apoptotic cells progressively increased as early as 2 days after the beginning of the treatment (Fig. 4A). Ibuprofen significantly induced cell death from 4 days of exposure in the 7 DW age group (P = 0.028 and 0.0079 after 4 and 7 days, respectively), and as early as 2 days of exposure in the 8–12 DW group (P = 0.00058; 3.84 × 10^–7, and 3.03 × 10^–8 after 2, 4 and 7 days, respectively) (Fig. 4A). In addition, in young 7 DW explants, M2A-positive germ cell depletion was progressively enhanced and became significant after 7 days of ibuprofen exposure (Fig. 4B). Of concern, M2A-germ cell depletion in 8–12 DW explants reached its maximum of −66.7% as rapidly as 2 days following ibuprofen treatment.

We next assessed the recovery capacity of this organ following ibuprofen withdrawal. Explants (10–12 DW) were exposed to 10 μM ibuprofen for 2 days, and subsequently cultured in control media without ibuprofen for a further 5 days (Fig. 5A). No significant difference in the overall cell death percentage at 7 days of culture was seen whether or not a 5-day recovery period had been allowed after the initial 2 days of ibuprofen-treatment (15.98 ± 2.38 versus 11.86 ± 1.31, Means ± SEM, P = 0.47). Likewise, the apoptosis rate induced by 2 days of ibuprofen exposure was not significantly reduced after a 5-day recovery (Fig. 5B; 13.50 ± 2.27 versus 9.58 ± 1.52, Means ± SEM, P = 0.43). However, the percentage of M2A-positive germ cells increased along with the 5 days recovery compared to the 2-day ibuprofen treatment alone, returning to its control level (Fig. 5C). These data most probably indicate that the cytotoxic effect induced by a 2 day ibuprofen exposure was not fully rescued by a 5 day-long withdrawal of the drug, despite an improvement of the germ cell percentage.

Discussion

Ibuprofen is one of the most widely used over-the-counter analgesic–antipyretic–anti-inflammatory medication. It has even been presented as ‘the mildest NSAID with the fewest side effects which has been in clinical use for a long time’ (Rainsford, 2009; Servey and Chang, 2014). During the third trimester of pregnancy, all NSAIDs are currently contra-indicated due to risks of severe cardiopulmonary toxicity and renal dysfunction in the fetus (Black and Hill, 2003; Servey and Chang, 2014). Several studies have reported the consumption of ibuprofen by pregnant women, with percentages of exposed women reaching up to 30% (Kristensen et al., 2016; Van Marter et al., 2013). Consistent with current recommendations, the majority of women using ibuprofen do so during the first trimester and frequency decreases thereafter (Glover et al., 2003; Nezvalova-Henriksen et al., 2013; Palmsten et al., 2016; Stephansson et al., 2011; Wen et al., 2008; Werler et al., 2005). We here report that ibuprofen, a non-selective inhibitor of COX, induces a decreased cell proliferation and an increased cell death in first trimester human fetal ovaries mainly due to effects on fetal germ cells. This raises concern about ibuprofen consumption by pregnant women during the fetal ovarian organogenesis period and a subsequent risk for the establishment of the follicular reserve.

Ibuprofen crosses the placental barrier during the first trimester of pregnancy

Paracetamol and acetyl salicylic acid can cross the human placental barrier (Jacobson et al., 1991; Levy et al., 1975; Naga Rani et al., 1989; Weigand et al., 1984). In rats and rabbits, ibuprofen and its metabolites can also readily enter the fetal circulation (Adams et al., 1969). In human, ibuprofen was found in the meconium of newborn infants (Alano et al., 2001). However, to the best of our knowledge, there has not been any direct measurement of the ability of ibuprofen to cross the placental barrier and its subsequent plasma levels in human fetuses.

Here, we took advantage of the use of ibuprofen for preventive analgesia by women undergoing abortion to investigate the circulating levels of ibuprofen in umbilical cord blood. We were able to reveal that when the woman ingested ibuprofen before abortion, it was detectable in the umbilical cord blood in concentrations ranging from 0.4 to 14 μM. Notably, the range of circulating ibuprofen depended more on the delay between ingestion and blood collection than on the ingested dose (400 versus 800 mg), the highest levels being found when this delay was between 3 and 6 h. In adults, the maximal therapeutic plasma concentration for ibuprofen has been defined in the 100 μM range for oral doses between 400 and 800 mg (Ceppi Monti et al., 1992; Kallstrom et al., 1988; Karttunen et al., 1990; Regazzi et al., 1986) and about 200 μM in children (Scott et al., 1999). Our results thus show for the first time that placental transfer of ibuprofen occurs as early as in the first trimester, and exposes the fetus to concentrations between 1 and 10 μM.

Ibuprofen impacts the growth of the human fetal ovary

Ovarian development is characterized by cell proliferation of both somatic and germ cell lineages (Fulton et al., 2005). During the first trimester, the oogonia actively proliferate and from the end of the first trimester, a subset of germ cells commit to meiosis (Jorgensen and Rajpert-De Meyts, 2014). In agreement with previous histological studies (Mamsen et al., 2011), we report that in uncultured ovaries, the total number of cells at least quadruples from 7 to 12 DW (2.6 × 10⁵ cells at 7 DW versus 1.3 × 10⁶ cells at 12 DW). Importantly, cell growth kept occurring over the course of 7 days in culture (4.5 × 10⁵ cells, i.e. +190,000 cells for 7 DW and 2 × 10⁶ cells, i.e. +700,000 cells for 12 DW cultured explants). The active proliferation of the germ cells was also evidenced ex vivo, where the M2A-positive cell population proliferates five times from 7 to 12 DW after 7 days of culture (from 4.7 × 10⁴ to over 3 × 10⁵ germ cells per cultured ovary) and increases 1.5 times after 7 days of culture (from 2.2 × 10⁵ in uncultivated ovaries to 3 × 10⁵ germ cells after 7 days of culture for 12 DW ovaries). Accordingly, KI67 immunostaining confirmed both somatic and germ cell proliferation ex vivo. Ovarian development during the first trimester has also been characterized by a low rate of apoptosis where apoptotic cells were mostly identified as oogonia (Fulton et al., 2005). Consistently, we found a similarly weak density of cleaved caspase-3-positive cells after 7 days of control culture and our flow cytometry data displayed equally low cell death rate in both fresh organ and ex vivo culture (close to 6%). Overall, these data suggest that the organotypic culture by itself did not impact either the high proliferation or the low apoptotic rates, therefore allowing the development of the ovary. By contrast, following exposure to ibuprofen, we have shown a reduction of the overall number of ovarian cells, effect coupled to a dramatic decline of cell proliferation and a significant enhancement of apoptosis, but not necrosis. This suggests that ibuprofen compromised both proliferation and viability, ultimately resulting in a loss of ovarian cells. At this stage, we cannot speculate if both events are linked or simply concomitant.

It has been over two decades since several studies have reported a role for ibuprofen and other NSAIDs in cancer prevention (Matos and Jordan, 2015). In cancer cell lines, ibuprofen is also known to alter cell proliferation and viability, the resulting cell growth slowdown being often associated with cell cycle arrest. In many cases, such as colon carcinoma (Andrews et al., 2008; Janssen et al., 2006, 2008), prostate cancer (Andrews et al., 2002, 2008; Minnery and Getzenberg, 2005), oral cavity cancer cell lines (Kim et al., 2004; Thurnher et al., 2001) and ovarian cancer cell lines (Andrews et al., 2008; Duncan et al., 2012; Lima et al., 2015), ibuprofen also induces apoptosis. Similar to its mechanism of action in cancer cells, we observed that ibuprofen alters both proliferation and cell death in human fetal ovary. At a molecular level, studies in several cell lines have suggested a TP53-dependent mechanism of ibuprofen toxicity that also involves an increase in the expression of CDKN1A (also known as p21) (Bonelli et al., 2011; Ikegaki et al., 2014; Janssen et al., 2008; Tsai et al., 2004). We found similar increases in TP53 and CDKN1A expression in the human fetal ovary after exposure to ibuprofen, suggesting that ibuprofen toxicity in the human fetal ovary may use a similar signaling pathway, and may act on molecular targets placed at the crossroad of proliferation and cell death. Further experiments will be required to investigate the fine molecular mechanism of action of ibuprofen on the human fetal ovary.

Interestingly, in four ovarian cancer cell lines (SKOV-3, CAOV-3, 36M2 and SW626) (Duncan et al., 2012), only the high concentration of 200 μM ibuprofen was shown to induce apoptosis, whereas doses ranging from 20 to 100 μM had no cytotoxic effect on the same cells. This suggests that ibuprofen may use different signaling pathways depending on the concentration of exposure, as well as the tumoral/physiological state of the cellular target. In our ex vivo model, the overall impact of ibuprofen was most pronounced when used at 10 μM and notably more variable at 100 μM. Non-monotonic dose–response curves have been described in the testis where several endocrine disruptor compounds exhibited these curves (Gaudriault et al., 2017). In the ovary, only two studies have investigated several concentrations (of either Bisphenol A or dexamethasone) and found linear dose–response curves (Brieno-Enriquez et al., 2011; Poulain et al., 2012). Non-linear dose–response effects are often associated with differences in the mechanism of action, such as induction of the detoxification pathway, alteration of signaling pathways or saturation of metabolic pathways (Vandenberg et al., 2012). Therefore, ibuprofen mechanism of action requires further investigations. Importantly, however, it is noteworthy that during the first trimester the developing fetuses are more likely to be exposed to the active concentrations of 10 μM and below.

Ibuprofen targets the germ cell lineage

We have shown that 10 μM ibuprofen efficiently inhibited PGE2 production by human fetal ovaries, as has been shown previously in human fetal testis culture (Ben Maamar et al., 2017; Mazaud-Guittot et al., 2013), and in vivo in the rat (Dean et al., 2016). In the human fetal ovary, COX1 is expressed by somatic cells, while COX2 and PTGES are confined to germ cells during the first and second trimesters (Bayne et al., 2009). Furthermore, previous studies have reported that exposure of human fetal ovaries to PGE2 (8 h exposure at 0.1 μM) increased the mRNA levels of MLC1 and INHA, two markers of mature germ cells (Bayne et al., 2009), suggesting a favorable impact of PGE2 on germ cell development. In the rat, in utero exposure to either indomethacin (0.8 mg/kg d) or paracetamol (350 mg/kg.d) between 13.5 and 21.5 days post-conception (dpc) altered the expression of some germ cell markers (Dean et al., 2016), while ex vivo exposure of 12.5 dpc mouse ovaries to 100 μM paracetamol for 3 days did not alter the expression of several typical germ cell markers (Holm et al., 2016). In the human fetal ovary, our ex vivo data reveal that ibuprofen massively impacts the viability of the germ cell lineage. It is thus reasonable to propose that the exacerbated effects of ibuprofen in 8–12 DW ovaries (compared to 7 DW organs) may be related to the increasing proportion in germ cells and their production of PGE2 at this stage.

Noteworthy, we observed that withdrawal of ibuprofen for 5 days after continuous exposure for 2 days allowed for a rescue of M2A-positive germ cell percentage, but with a persistent high apoptosis rate. We hypothesize that germ cells surviving the 2 days of ibuprofen exposure may proliferate rapidly after termination of drug administration, resulting in complete ovarian potential 5 days after exposure ended. Therefore, at the cellular level, the negative effect of ibuprofen on the germ cell lineage viability might be limited. This does not however exclude potential damage at the molecular level, such as DNA damage as suggested by inherited impact of paracetamol and indomethacin, another NSAID, in the germ cells of the rat (Dean et al., 2016).

While overexpression of COX2 and increased prostaglandin biosynthesis has been observed during carcinogenesis (Harris, 2007), NSAIDs anti-tumoral effect has been to a large part attributed to their inhibition of COX enzymes (Matos and Jordan, 2015). Because COX2 expression is restricted to germ cells during fetal development (Bayne et al., 2009), it could be hypothesized that ibuprofen would preferentially target cells expressing high COX2 levels, such as tumor and fetal germ cells. However, if the canonical mechanism of action of ibuprofen and other NSAIDs rely on the inhibition of prostaglandin synthesis, ibuprofen can also display cytotoxic effects independently of COX2 expression or activity (Andrews et al., 2008; Janssen et al., 2008). The specific mechanism(s) of action of ibuprofen on ovotoxicity and germ cell viability thus requires further detailed investigations.

Overall, our data reveal that a 2–7 days exposure to the non-selective COX inhibitor ibuprofen, at concentrations relevant to in utero conditions impacts the germ cell stockpile in human fetal ovaries in the first trimester of pregnancy. The incomplete capacity for rescue of the fetal ovary to ibuprofen-induced damages suggests that prolonged exposure to ibuprofen during fetal life may lead to long-term effects on female reproductive function. This raises concern about ibuprofen consumption by pregnant women during the fetal ovarian organogenesis period, and the subsequent risk for the establishment of the follicular reserve.

Supplementary data

Supplementary data are available at Human Reproduction online.

Authors’ roles

S.L.P. and S.M.G. designed, performed and analyzed experiments (culture, histology, cell counts and cytometry for S.L.P.; organ collection, culture, histology and QtPCR for S.M.G.). R.T.M. and N.H. designed and conducted the ibuprofen measurements. M.B.M. performed experiments (organ and blood collection, culture). L.L. performed experiments (culture, cytometry). E.B. performed the statistical analyses and contributed to the writing of the corresponding section. V.L. supervised the collection of the first trimester human fetal ovarian samples. S.M.G. conceptualized the project, S.L.P. and S.M.G. prepared the visualization of the data and wrote the original draft, N.D.R., D.M.K., F.C. and B.J. contributed to critical discussions, reviewed and edited the manuscript, and all authors approved the final manuscript.

Funding

This study was funded by Inserm, University of Rennes 1, EHESP—School of Public Health, by grants from the Agence Nationale de Sécurité du Médicament et des Produits de Santé (ANSM; HAP-2014-073), Agence Nationale de la Recherche (ANR-15-CE34-0001-01) and the Danish Council for independent Research (Medical Sciences), and the Wellcome Trust (Grant no: 098522).

Conflict of interest

The authors declare they have no competing financial interest and funders had no role in the study design, data collection and analysis, decision to publish or preparation of the manuscript.

Acknowledgements

We thank all the staff of the Department of Obstetrics and Gynecology and the Department of Pediatric Surgery of the Rennes Sud Hospital (Rennes, France) and the participating women, without whom this study would not have been possible. The authors are grateful for Isabelle Coiffec for assistance on organ collection and the H2P2 histology facility of Rennes 1 University. We also thank the Edinburgh CRF Mass Spectrometry Core.

References