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Breast Cancer

Prolonged recombinant pregnancy hormone use in BRCA1 and BRCA2 mutation carriers

Depypere, Hermana; Su, Yanrongb; Dang, Nhib; Poppe, Brucec; Stanczyk, Frankd; Janssens, Jaake; Russo, Joseb

Author Information
European Journal of Cancer Prevention: May 2021 - Volume 30 - Issue 3 - p 195-203
doi: 10.1097/CEJ.0000000000000664

Abstract

Introduction

Large studies indicate that an early first full-time pregnancy (FFTP) substantially reduces breast cancer risk (Lambe et al., 1996; Kobayashi et al., 2012). It effectively restores genomic and epigenetic alterations (Zendehbad et al., 2019; Miranda Furtado et al., 2019). Indeed, when compared to the transcriptomic profile of the nulliparous postmenopausal breast, the parous postmenopausal breast shows significant differences in which cell differentiation, development, apoptosis and chromatin remodeling are the main biological processes (Russo et al. 2012; Peri et al., 2012).

The principal hormone responsible for this risk reduction is human chorionic gonadotropin (hCG). Ample in vitro, animal, and clinical studies have shown that hCG induces changes in gene expression and epigenetic markers, induces apoptosis, and protects breast epithelial cells from being transformed, and thereby inhibits breast tumorigenesis (Russo et al., 1990; Bernstein et al., 1995; Srivastava et al., 1997; Jiang et al., 2002,Kocdor et al., 2009; Santucci-Pereira et al., 2013). A recent study has demonstrated that young age at first pregnancy does protect against early-onset breast cancer in BRCA1/2 mutation carriers (Evans et al., 2018). Consequently, treatment with hCG could potentially have similar preventive capabilities compared to a FFTP and could serve as a preventive treatment for high-risk women, such as carriers of BRCA1/2 mutations.

In this study, we explored for the first time the possibility of using r-hCG in a preventive setting in BRCA 1/2 carriers. The primary objectives of this study were to assess clinical safety and potential beneficial influence of prolonged r-hCG treatment in young, nulliparous women.

Methods

Participants

Thirty-three, nulliparous, young women were recruited in this prospective, longitudinal interventional study [ethical board of the University Hospital approval (EudraCT number: 2015-001720-36; EC number: 2015/0588)]. Baseline characteristics, inclusion and exclusion criteria are given in Table 1.

Table 1 - This table lists the subject number, age at inclusion and description of mutations
Study number BRCA Mutation c1 Mutation p1 Age Contraception use
101 BRCA1 c.5406 + 5G>A 25 A
102 BRCA1 c.5266dupC 23 C
103 BRCA1 c.2359dupG (p.Glu787Glyfs*3) 21 A
104 BRCA2 8904del (former name: 9132delC) Val2969fs 24 A
105 BRCA2 c.4171delG (p.Glu1391Lysfs*19) 19 A
106 BRCA1 3661G>T Glu1221* 25 B (52 mg levonorgestrel over 5 years)
107 BRCA2 4935delA Glu1646fs 26 A
108 BRCA2 6275_6276delTT Leu22092Profs*7 18 A
109 BRCA1 212 + 3A>G 24 A
110 BRCA2 4935delA Glu1646fs 22 A
111 BRCA1 397delC Arg133Valfs*30 25 C
112 BRCA1 3661G>T Glu1221* 21 A
113 BRCA1 3661G>T Glu1221* 24 B (52 mg levonorgestrel over 5 years)
114 BRCA1 c.5194-2A>G 24 A
115 BRCA1 134 + 3A>C 22 B (13.5 mg levonorgestrel over 3 years)
116 BRCA2 6275_6276delTT Leu209Profs*7 20 C
117 BRCA2 1389_1390delAG Val464Glyfs*3 22 C
118 BRCA1 2359dupG Glu787Glyfs*3 19 B (13.5 mg levonorgestrel over 3 years)
119 BRCA1 2359dup (former name: 2478-2479insG) Glu787fs 24 C
120 BRCA1 3607C>T Arg1203* 20 C
121 BRCA1 2019del (former name: 2138delA) Glu673fs 26 A
122 BRCA1 2359dup Glu787fs 26 C
123 BRCA1 2359dup Glu787fs 24 C
124 BRCA2 3847_3848del (former name: 4075delGT) Val1283fs 24 A
125 BRCA2 c.5213_5216del4 (p.Thr1738Ilefs*2) 19 B (EE 0.04 mg + DSG 0.15 mg)
126 BRCA1 c.2359dupG 20 B (E2 1.5 mg + Nomac 2.5 mg)
127 BRCA2 4171del (former name: 4399delG) Glu1391fs 23 C
128 BRCA1 4575_4585delAGAGGAGCTCA Gln1525Hisfs*2 22 B (19.5 mg levonorgestrel over 5 years)
129 BRCA1 212 + 3A>G 25 A
130 BRCA1 c.3661G>T 22 B (19.5 mg levonorgestrel over 5 years)
131 BRCA1 c.3661G>T 18 B (19.5 mg levonorgestrel over 5 years)
132 BRCA2 c.662_663del 26 C
133 BRCA2 c.4576dupA (p.Thr1526Asnfs*3) 21 B (etonogestrel 68 mg over 3 years)
To be included in the study, the participants had to be asymptomatic, nulligravid women between 18 and 30 years of age, carriers of the BRCA1 or BRCA2 mutation (diagnosed by the genetics laboratory of the Ghent University Hospital, a CLIA-certified clinical genetics laboratory). The ECOG performance status needed to be 0 (Kornofsky 100%). The contraceptive profile consisted of three categories: (A) participants did not take any hormonal medication during the study and had stopped contraception more than 30 days prior to the start of study medication; (B) in instances where contraception containing any hormone was used, the contraceptive method is listed in this table. Three types of levonorgestrel intrauterine systems were used: Mirena (releasing 52 mg levonorgestrel over 5 years N = 2); Jaydess (releasing 13.5 mg of levonorgestrel over 3 years; N = 2); and Kyleena (releasing 19.5 mg of levonorgestrel over 5 years; N = 3). Etonogestrel (68 mg over 3 years) is an implant inserted 2 years prior to the study participation in one subject. One participant used a natural estradiol-containing oral contraceptive (17β-estradiol (E2) 1.5 mg + nomegestrol acetate (Nomac) 2.5 mg). Another participant used an oral formulation containing Ethinyl estradiol 0.04 mg combined with desogestrel (DSG) 0.15 mg; (C) participants did not take any hormonal medication during the study but stopped contraception less than 30 days prior to the start of study medication.

Participants were asked to stop oral contraception prior to the study. We expected that an levonorgestrel-intrauterine system (IUS) would not interfere with the study protocol since it was previously published that the amount of levonorgestrel in the breast epithelium was extremely low (Depypere et al., 2019). As such, seven women with an levonorgestrel-IUS could be included in the study without needing to remove the IUS. One woman had a long-acting reversible contraceptive implant. Two women did not want to stop oral contraception.

Clinical protocol

Blood was drawn, and an ultrasound of both ovaries and the uterus was performed. If all examinations were normal, a first Spirotome (Bioncise, Belgium) 4-mm breast biopsy was performed. Following the biopsy, the r-hCG treatment was initiated. The r-hCG (Ovidrel Prefilled Syringe, Serono) was purchased from Serono, Inc., Rockland, Massachusetts, USA or Switzerland. Participants received a subcutaneous injection of 250 µg r-hCG three times a week for 12 weeks. A rigorous follow-up protocol during and after the study was implemented to monitor acceptance rate, procedural inconsistencies, interferences with clinical parameters, side effects, and safety of prolonged r-hCG administration in these young women (Supplementary S1, Supplemental digital content 1, http://links.lww.com/EJCP/A320).

The second and third Spirotome biopsies were taken immediately and 6 months after r-hCG treatment. The third biopsy was done to assess whether transcriptomic and histological changes occurring in the breast due to r-hCG treatment persisted after 6 months’ follow up. Details of Spirotome biopsies procedure and processing are included in the Supplementary S2, Supplemental digital content 1, http://links.lww.com/EJCP/A320.

The hematoxylin and eosin (H&E) staining was performed following a standard protocol (Supplementary S2, Supplemental digital content 1, http://links.lww.com/EJCP/A320). Immunohistochemistry (IHC) was performed by staining with primary antibodies using an i6000 BioGenex Autostainer following a standard protocol (Supplementary S2, Supplemental digital content 1, http://links.lww.com/EJCP/A320).

Total RNA was extracted within a month after all samples were received using the RNeasy Lipid Tissue Mini kit (Qiagen, Germantown, Maryland, USA) at Fox Chase Cancer Center according to the manufacturer’s protocol; the library construction and sequencing were carried out by the BGI Company in Hong Kong (Supplementary S2, Supplemental digital content 1, http://links.lww.com/EJCP/A320). In total, there were 166 files sequenced, with each containing from 128–199 million reads (Supplementary S3–S6, Supplemental digital content 1, http://links.lww.com/EJCP/A320: library construction/qualified participants/sequence reads/statistics of reads generated from sequencing).

Ultrasound monitoring

Ultrasound examinations of the endometrium, uterus and ovaries were performed with a vaginal probe (7.5 Hz, Medison, Germany) prior to the start of the r-hCG treatment and every month thereafter.

Hormone level monitoring

Estradiol and progesterone serum levels were used to monitor the cycle. Since none of the participants had any complaints during the r-hCG administration, and no signs of ovarian dysfunction were observed on ultrasound monitoring, blood was analyzed in one batch at the end of the study. Estradiol, progesterone, follicle stimulating hormone (FSH), luteinizing hormone (LH) and hCG were measured by electrochemiluminescence immunoassay on the Elecsys (Erler, 1998) and Cobas immunoassay analyzers.

Statistical power sampling for RNA sequencing

Analysis of differential expression between two time points involved adjustment for multiple testing in terms of controlling the false discovery rate (FDR). At a significance level of the FDR of 0.05, and an effect size of 1 with the RNA sequencing to an average of 11× depth, the required sample size of approximately 11 allows the differential gene expression analysis of 90% power [R version 3.4.4 package RNASeqPower (Hart et al., 2013)]. In terms of log 2 ratios, an effect size of 1 corresponds to a two-fold change difference between any two time points being compared. A significance level of 0.05 results in 100 false discoveries per 2000 nondifferentially expressed genes. Due to the paired nature of the comparisons, 11 participants are required for each time point. Taking into account the fact that breast samples would not always yield enough material for RNA analysis in each biopsy and that we needed study participants where all three biopsies could be compared, we projected that we needed to include 30 women. Some participants were related to each other, and we did not want to choose amongst them for inclusion in the study. Hence, we included three more women to end up with a total of 33 women participating in the trial.

Statistical analysis for hormones and ultrasound

Linear mixed models for the natural log-transformed hormones were fitted with a random intercept for patient (to account for the correlation between repeated measurements on the same patient) and with the visit as a categorical fixed effect (the visit at week 1 before r-hCG administration was taken as a reference). Confidence intervals were computed using the profile method based on the likelihood ratio test. P values were computed via Satterthwaite’s degrees of freedom method.

In addition, linear mixed models were fitted with the visit (categorical, with the visit at week 1 before r-hCG administration was taken as the reference group), responsiveness (low to moderate responders versus responders) and the two-way interaction between visit and responsiveness in the fixed effect part of the model.

Results

In total, 33 women were recruited (Fig. 1). All women were young nulliparous women with a mean age of 22.5 years. Clinical signs were monitored before, during and after the r-hCG administration. The most frequently reported side effects were nausea (12.5%), fatigue (12.5%), headache (29.2%), vasomotor symptoms (<5%) and insomnia (<5%). The side effects of prolonged r-hCG administration were mild and did not cause interference with daily functioning. The complete list of medications used by the participants during the study is provided as Supplementary S7, Supplemental digital content 1, http://links.lww.com/EJCP/A320. The compliance with the study medication was 100%. All participants included in the study finished the study and had three biopsies of the breast during the trial.

Fig. 1
Fig. 1:
Flow chart of the participants used for the study.

The breast tissues of BRCA1/2 carriers (Fig. 2) contain very dense stroma and fewer well-defined lobules compared to the breast tissues of BRCA1/2 wild-type women, consistent with previous findings (Russo et al., 2001).

Fig. 2
Fig. 2:
The quality of breast biopsy samples for H&E and IHC staining. (a) Picture of one breast biopsy specimen. (b) H&E stained images of breast tissue. Magnification: 200×. (c) IHC images stained with E-cadherin, showing positive membrane staining in the epithelial cells. Magnification: 200×. (d) IHC images stained with H3K27me3, showing positive nuclear staining. Magnification: 400×. H&E, hematoxylin and eosin; IHC, immunohistochemistry.

Since the response to r-hCG treatment evaluated by RNA-seq varied between the study participants, we reanalyzed our data according to hormonal contraceptive use during the study. Among these 25 patients, there were 11 women who did not use contraceptives during the r-hCG trial or who stopped oral contraceptives more than 30 days prior to the trial (except one case using a copper IUD before, during, and after the trial) and 14 women using oral contraceptives or a hormonal IUD during the trial or stopping the pills less than 30 days prior to the trial. We observed a strong difference between women with and without contraceptive use in response to the r-hCG at both T2 and T3 versus baseline, T1. That was clearly reflected in Fig. 3c showing the differentially expressed genes (DEGs) at the cutoff fold change of 1.5 and 2, respectively, with 1907 DEGs (1032 up, 875 down) at T2 vs. T1 and 1065 DEGs (897 up, 168 down) at T3 vs. T1 for the women not using contraceptives (named as responders) while there was almost no response at T2 vs. T1 and a small number of DEGs, 260 (214 up, 46 down) at T3 vs. T1 for the group of 14 women using contraception during or close to start of the trial (named as low responders). Notably, the number of DEGs with the fold change of two accounts for about half of the total number of genes with significant expression changes.

Fig. 3
Fig. 3:
r-hCG treatment induces a significant amount of gene expression changes in BRCA1/2 mutation carriers without contraceptives exposure. (a) Per sequence quality scores. Overall Phred scores. Each panel on the left-side shows the universal quality values of all reads in main trials and additional cases (paired-end, 166 read files in total). The y-axis shows the total counts corresponding to the Phred scores (x-axis). Green area represents good quality scores. (b) Per base sequence content. Right and left panels show the paired raw reads with very few acceptable biases for the difference between A and T, or G and C greater than 20% at the first of reads. The remaining base pairs of reads showed no bias, and no adapter contamination was observed. (c) Graphs representing the number of DEGs found in the breast tissue of women at different time points after r-hCG treatment compared to the control samples taken from the same patient before treatment [cutoff of false discovery rate-adjusted P value (FDRp) <0.05 and fold change of 1.5 or 2]. DEGs, differentially expressed genes; r-hCG, recombinant human chorionic gonadotrophin.

Ultrasound changes

There was a significant, gradual increase in the size of the ovaries, from 582 (488–694) mm2 at the beginning of the study to a significantly higher surface of 831 (697–991) mm2 (mean ratio 1.43 (1.19–1.71), P = 0.002) at the end (week 13) of the r-hCG administration. After the study was completed, the size of the ovaries remained within the values before the administration of the medication (Fig. 4). No clinically relevant changes were observed either by ultrasound or reported subjectively by the participants during the study. No cyst formation was observed. There was a marginally significant decrease in endometrial thickness from 3.9 cm (2.98–5.11) to 2.79 cm (2.13–3.66) (mean ratio 0.72 (0.54–0.95), P = 0.059). The subsequent values for endometrial thickness were not different.

Fig. 4
Fig. 4:
Mean ovary two-dimentional size (a) and endometrial thickness (b) with 95% confidence interval. The changes induced by r-hCG on the uterus were assessed by measuring the endometrial thickness and its appearance (triple lining, luteal appearance), the fundal diameter and isthmus-fundal distance. There was a marginal significance of decrease in endometrial thickness from 3.9 cm (2.98–5.11) to 2.79 cm (2.13–3.66) (mean ratio 0.72 (0.54–0.95), P = 0.059). The subsequent values for endometrial thickness were not different. r-hCG, recombinant human chorionic gonadotrophin.

Hormonal changes

During the r-hCG administration, there was a drop in FSH and LH levels. FSH decreased from 3.6 (2.4–5.2) mIU/mL (reference time: T1 = week 1) at the start of the study to a significantly lower value of 1.9 (1.3–2.8) mIU/mL (mean ratio 0.54 (0.35–0.83), P = 0.021) at week 5. The subsequent FSH levels were not significantly different. The LH levels significantly decreased from 5.7 (4.3–7.7) mIU/mL at the start of the study to 1.6 (1.2–2.2) mIU/mL (mean ratio 0.28 (0.2–0.38), P < 0.001) at week 5, and 3.9 (2.8–5.7) mIU/mL (mean ratio 0.69 (0.48–0.99), P = 0.098) at week 9. During the last month of r-hCG administration, the LH normalized. After the administration of the study medication, LH was not different from values at the beginning of the study.

We observed that the response to r-hCG treatment evaluated by the number of DEGs varied between study participants. The response evaluated in DEGs varied in relation to the history of contraceptive use; we assessed whether this variation could be explained by differences in hormone levels during the study. The following differences were observed:

Firstly, both LH and FSH levels were significantly higher ((LH at week 5 (P = 0.003, mean ratio = 2.91) and FSH [at weeks 5, 9 and 13 (pooled analysis)] (P = 0,028, mean ratio low responders to responders = 1.98)) in the noncontraceptive-low-responder group (Supplementary S8, Supplemental digital content 1, http://links.lww.com/EJCP/A320).

Secondly, responders had a higher level of estradiol (P = 0.078, mean ratio = 0.55) and progesterone (P = 0.01, mean ratio = 0.2) compared to low responders at week 1 (Supplementary S8, Supplemental digital content 1, http://links.lww.com/EJCP/A320). There was a remarkable reduction for both estradiol and progesterone in responders at week 5 and a peak at week 9, and after that time, the levels of estradiol and progesterone decreased. Generally, the mean levels of estradiol and progesterone in the responders were always higher than those in the low responders at each time point during the first 36 weeks of the trial.

Thirdly, the mean hCG level was 206 (180–237) IU/L at weeks 5, 9 and 13 in the low responders; it was significantly (P < 0.005) higher than the mean value 154 (134–178) IU/L in the responders (mean ratio low responders to responders = 1.34). The levels of prolactin were not significantly different between groups, not even when they were pooled (Supplementary S8, Supplemental digital content 1, http://links.lww.com/EJCP/A320).

Discussion

We examined whether the use of r-hCG, a recombinant hormone, mimics pregnancy. By inducing changes in the mammary gland, it could be a novel preventive strategy against breast cancer for high-risk women and, by extension, for all women. This is the first study in which r-hCG was administered during a prolonged period of 12 weeks in young women as a tentative chemoprophylactic agent in an attempt to mimic the effects of an FFTP.

Overall prolonged r-hCG was well supported, with all participants completing the trial. The side effects were minimal. Initially, we started the administration during the luteal phase. Since the recruitment and maturation of one follicle had taken place, it was considered that this would be a safe option to avoid multiple follicle recruitment. This was done to avoid potential ovarian hyperstimulation (OHSS). As evidenced by laboratory tests and ultrasound monitoring, prolonged administration was safe, and no significant increase in estradiol levels was observed. Since in the initial participants no signs of OHSS were observed, we allowed women to start r-hCG soon after stopping hormonal contraception, not requiring them to start during the luteal phase. Because most participants had an ongoing relationship, we avoided that they had to wait too long prior to the onset of the study, especially since some women took contraceptives because they had irregular or very irregular cycles. Stopping contraceptives would entail these latter participants having to wait for months until ovulation occurred, so they could start the study. We did not require the 7 participants having a hormonal levonorgestrel-IUS to have it removed prior to the study. To our surprise, these women (contraception group) had different responses with a delay and a significant reduction in DEGs.

Generally, it is believed that the action of hCG is luteinizing hormone-chorionic gonadotropin receptor (LHCGR) mediated. The expression of LHCGR has been identified not only in the ovary and testis but also in extragonadal tissues, such as in the uterus (Sacchi et al., 2018) and breast (Meduri et al., 1997). It was shown that hCG has a role in promoting the weight gain of ovaries and uterus (Lecompte et al., 2010,Rafert et al., 2016), as well as inducing mammary gland development (Russo et al., 1990). Interestingly, estrogen receptor antagonists exert a dose-dependent inhibition of the hCG stimulation of uterine weight gain when injected simultaneously with hCG (Rafert et al., 2016), suggesting that the estrogen level could affect the impact of the hCG on its target organs.

Organs such as the ovary, breast, liver and kidney can take up hCG after administration. The hCG receptor expression differential including (1) cell numbers with receptor, (2) receptors per cell and (3) receptor affinity can affect the distribution of hCG in the breast and ovaries. The liver is responsible for the removal of hCG from the circulation, and the kidney is involved in excretion of hCG (Mizejewski, 1975). All these factors can have an influence on the serum hCG level. Studies have shown that exogenous hCG concentrates preferentially in the ovarian tissues of nonhypophysectomized mice, the maximum concentration occurring at 2–4 h after injection (Kazeto and Hreshchyshyn, 1970), although serum hCG levels were reduced hours after hCG administration, the tissue/blood hCG ratio in the ovaries increased (Rafert et al., 2016), suggesting that the serum hCG level does not reflect hCG’s bioactivity. In our study, the lower serum hCG level in responders might suggest a higher binding of r-hCG in target organs. Consistently, the serum estrogen and progesterone levels were relatively higher in responders during 36 weeks of the study, indicating a higher hCG response.

Interference from medication, hormonal status and hCG can act in two ways. The influence of hCG on clinical and endocrine parameters seems minimal and even absent. The effect of clinical parameters on hCG efficiency is unexpected. Hormonal use seems to have a paramount effect on molecular biology parameters. This observation is the first of its kind, and subsequent prevention studies should take into account stratification according to contraception techniques and wash-out periods.

In conclusion, this study demonstrates for the first time that prolonged use of r-hCG in young BRCA1/2 mutation carrier women for breast cancer prevention is feasible and safe. The RNA-sequencing analysis showed that r-hCG treatment has a remarkable effect on the gene expression profile of breast tissues from BRCA1/2 carrier women who did not use any hormonal contraceptives, whereas the use of contraceptives during the study delayed the response and significantly reduced the number of DEGs.

Acknowledgements

The study medication was provided to us by a grant of Think Pink, Belgium and ECP.

R.J. conceived and supervised the whole project; D.H. carried out the clinical trial, collected samples, analyzed hormone and ultrasound analysis and drafted the manuscript; S.Y. received all biopsy samples, performed histological analysis, extracted total RNAs and drafted the manuscript; D.N. carried out RNA-seq analysis and drafted the manuscript. P.B. is the clinical director of the department of genetics. He was involved in the counseling of high-risk women. He recruited women from his database of BRCA carriers and designed the invitation letters approved by the ethical board of the University Hospital. S.F. helped us during the design of the study and helped interpret the data. J.J. helped us in the design of the study. He shared with us his extensive experience with the Spirotome system, coordinated the handling of the biopsies and cosupervised the project.

Conflicts of interest

There are no conflicts of interest.

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Keywords:

BRCA; breast cancer prevention; recombinant human chorionic gonadotropin

Supplemental Digital Content

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