Introduction
Polycystic ovary syndrome (PCOS) is one of the most common endocrine disorders in women of reproductive age and the most common cause of infertility due to ovulation problems [
1]. PCOS was observed to be associated with an increased risk of pregnancy complications as well as neonatal complications (miscarriages, gestational diabetes, gestational hypertension, preeclampsia, and fetal hypertrophy) [
2]. Cardiovascular disease, impaired glucose tolerance and type 2 diabetes, obstructive sleep apnea, and endometrial cancer are significantly more common in women with PCOS [
3]. The pathogenesis of PCOS remains largely unexplained. According to the literature, abnormal anti-Müllerian hormone (AMH) levels and significant vitamin D deficiency are responsible for a number of different abnormalities observed in PCOS patients [
4].
AMH is one of the most reliable markers of ovarian reserve [
5]. It regulates the development of early pre-antral and small antral follicles by reducing their sensitivity to follicle-stimulating hormone (FSH). It also has anti-proliferative and pro-apoptotic activity [
6,
7]. It has been postulated that AMH is capable of stimulating the activity of hypothalamic gonadotropin-releasing hormone (GnRH) secreting neurons by enhancing the secretion of luteinizing hormone (LH); thus, the involvement of AMH in the pathomechanism of PCOS-related disorders can be confirmed [
8]. Numerous studies confirmed a two- or even a threefold increase in AMH levels in PCOS patients as compared with healthy individuals. Cimino and coworkers suggested that high AMH levels are correlated with the severity of PCOS [
9]. However, the etiology of PCOS and the mechanism responsible for elevated AMH levels in PCOS patients remain unexplained, and the maintenance of normal AMH levels appears to play the key role in the management.
After the worldwide epidemic of vitamin D deficiency had been declared [
10], numerous studies were conducted to show that vitamin D plays an important role in the metabolic pathways in PCOS women [
11]. Vitamin D deficiency was shown to be much more common in PCOS women and was related to the severity of the syndrome [
12]. Besides regulation of calcium and phosphate metabolism, the range of vitamin D actions includes pro-differentiation, anti-proliferation, pro-apoptosis, immunosuppression, and anti-inflammation [
13]. Vitamin D is proposed to be an important steroid hormone involved in reproduction. Low vitamin D level is correlated with impaired ovarian function and with the increased risk of leiomyomas [
14]. In addition, the important role of this hormone in reproduction medicine is confirmed by higher pregnancy rates in women with higher levels of vitamin D [
15].
The maintenance of biological equilibrium with regard to proper AMH and vitamin D levels is a very complicated process. In a vast majority of studies, a significant correlation was observed between AMH and vitamin D levels. Naderi and coworkers suggested that vitamin D supplementation leads to increased serum AMH levels [
16]. Slightly different results were obtained by Irani and coworkers who showed that administration of vitamin D in women with PCOS may reduce the AMH levels [
17]. However, no correlation between AMH and vitamin D levels was observed in some studies [
18]. Because of the controversial findings, the role of AMH in pregnancy outcome is uncertain.
The impact of vitamin D on AMH synthesis remains unclear. The active form of vitamin D (calcitriol, 1,25(OH)D) mediates its biological effects by binding to vitamin D receptor (VDR), which acts as a transcription factor. Currently available data showed that
AMH is a target gene for calcitriol. Krishnan and coworkers identified vitamin D responsive element (VDRE) in the human
AMH promoter and found that AMH mRNA expression is upregulated in response to calcitriol [
19]. Because vitamin D activity is mediated by VDR, analysis of the
VDR genetic variation may elucidate the role of vitamin D in PCOS. It has been postulated that VDR polymorphisms (
ApaI,
BsmI, and
FokI) may contribute to PCOS susceptibility [
20]. The
VDR gene lies on the long arm of chromosome 12 (12q12-14) and has approximately 200 single-nucleotide polymorphisms (SNPs) [
21]. Each polymorphism is named according to the restriction site that was initially used to identify it. The most common allelic variants studied include
VDR Fok1 C/T (rs2228587), Bsm1 A/G (rs1544410), Apa1 A/C (rs7975232), and Cdx2 A/G (rs11568820) polymorphisms. Polymorphisms in
VDR can change mRNA stability, efficiency of VDR protein translation, and VDR activity [
22]. The presence of FokI polymorphism results in a shortened VDR protein [
23,
24]. Moreover ApaI, BsmI, and TaqI may affect gene expression by altering mRNA stability, splice sites for mRNA transcription, or intronic regulatory elements [
25]. Presence of different genetic variants in the vitamin D and AMH signaling pathway was also postulated to be a possible cause of reproductive dysfunction in women [
26]. Moreover, some data suggest that the
AMH (rs10407022) and
AMHR2 (rs2002555) polymorphisms result in increased susceptibility to PCOS; however, the outcome is still inconsistent [
27].
Considering the significant discrepancy in the available literature data on the effects of vitamin D on AMH levels, we attempted to examine the relationship between the four functionally most relevant VDR polymorphisms (Fok1, Bsm1, Apa1, and Cdx2) as well as AMH and AMHR2 gene polymorphisms and their influence on AMH levels in PCOS women.
Materials
A prospective study was conducted at the Department of Gynecology and Oncological Gynecology of the Military Institute of Medicine, Warsaw, Poland, between 2015 and 2017. The study was approved by the institutional review board. Written informed consent was obtained from all patients.
The study group consisted of 75 women (aged 25–43 years) with polycystic ovary syndrome (PCOS). Meeting two of the following three conditions was required for inclusion:
-
Clinical or laboratory features of androgenization;
-
Infrequent ovulation or lack of ovulation;
-
Polycystic ovaries in ultrasound imaging.
Hirsutism was defined as a Ferriman-Gallwey score of more than 5; the laboratory features were assessed on the basis of free testosterone levels exceeding 3.5 pg/mL. Clinical indicators of infrequent ovulation or lack of ovulation included menstruation disturbances such as irregular menstruation (cycle durations differing by more than 10 days), oligomenorrhea (menstruation occurring with the frequency of 40 days to 6 months), and secondary amenorrhea (no menstruation over a 1-year period).
Ovarian morphology was assessed by means of transvaginal ultrasound. Polycystic ovaries were defined as ovaries with the ultrasound appearance of more than 12 subcapsular follicles (with diameters of 2–9 mm) or as ovaries with total volumes larger than 10 cm
3 according to the Rotterdam criteria published in 2003 [
28].
The control group consisted of 23 subjects (aged 27–42 years) recruited from young, healthy women without disorders in their obstetric-gynecological and internal medical history. None reported any problems with conception; all subjects declared a normal course of pregnancy and delivery. In addition, none of the control subjects was under any medical treatment. Transvaginal ultrasound scans were performed in all patients between day 3 and day 5 of the menstrual cycle to reveal normal morphology of the uterus, endometrium, and appendages. Women on oral hormonal contraception or women with hormonal intrauterine devices were excluded from the study.
Discussion
Vitamin D plays an important role in metabolic pathways associated with PCOS. Its level has been related with the severity of the phenotype of this disorder. However, it should be kept in mind that the prevalence of vitamin D deficiency in the general population of adults is about 20–48% [
29]. It has been postulated that vitamin D deficiency among women with PCOS is relatively higher, approximately 67–85% [
12]. In accordance with other reports, we confirmed statistically significantly lower vitamin D level in the group of PCOS patients as compared with the control group [
18].
One of the most important objectives of this study was to determine the influence of vitamin D and
VDR gene polymorphisms (Fok1, Bsm1, Apa1, and Cdx2) and
AMH and
AMHR polymorphisms on AMH levels in PCOS women. Numerous studies confirmed that the differences in the biological activity of vitamin D are mainly caused by gene expression changes mediated by intracellular vitamin D receptors (VDRs) [
30]. VDR, being a member of nuclear receptor family (NR1I1), is believed to be a universal translational complex that controls 3% of the human genome. Following activation with an active form of vitamin D (calcitriol, 1,25(OH)D), VDR forms a heterodimer with retinoid X receptor (RXR) which is enabled to recognize the specific DNA sequences and vitamin D response elements (VDRE) located within the promoter regions of vitamin D–regulated genes [
31]. The receptors bind to the regulatory regions of target genes, which is essential for directed changes in transcription. It should be noted that vitamin D receptors were found in many tissues, including ovaries, uterus, and placenta. They play different roles, including regulation of gene networks involved in proliferation and differentiation of cells as well as in the function of the immune system. Thus, the cellular expression of the receptor is very important, and the receptor’s concentration is a key component of cell’s sensitivity to the hormone.
In vitro studies demonstrated that the
AMH gene is upregulated by vitamin D via functional vitamin D response elements that bind the vitamin D receptor (VDR) [
6]. There are multiple reports regarding the relationship between AMH and vitamin D and the impact of vitamin D supplementation on AMH levels [
32,
13,
16]. When analyzing the available literature, it is clear that most of the studies revealed that supplementation of vitamin D to women with low AMH levels leads to an increase in these levels, thus improving reproductive outcomes [
33]. AMH levels in PCOS women are 2–3 times higher than those in the control group, as was also confirmed in our study (
p < 0.05) [
34]. However, it was demonstrated that too low (< 0.2 ng/mL) as well as too high (> 6.1 ng/mL) levels of AMH, particularly in PCOS women, are associated with poorer reproductive outcomes [
35]. Therefore, it is very important to keep the AMH levels within normal range. Several strategies have been proposed to achieve this important goal.
Current data present an inconsistent correlation between vitamin D supplementation and AMH levels. Jukic and coworkers found some evidence that low vitamin D levels were associated with low AMH levels and other biomarkers of ovarian reserve [
36]. The association between vitamin D and AMH levels was also confirmed by Dennis and coworkers, who demonstrated a significant seasonal correlation of vitamin D and AMH concentrations [
33]. According to the study, higher vitamin D levels observed in the summer season were associated with higher AMH concentrations. In addition, supplementation with vitamin D was found not only to sufficiently replenish seasonal drops in AMH and vitamin D levels but also to increase the overall concentrations of both substances. Similarly, Merhi and coworkers observed a positive correlation between serum concentrations of vitamin D and AMH, thus suggesting a relationship between low ovarian reserve and vitamin D deficiency. However, it should be noted that no such correlation was observed in younger women [
13]. In contrast to previous studies, some reports suggest an inverse correlation between vitamin D supplementation and AMH levels. Irani and coworkers demonstrated that administration of vitamin D in PCOS women could decrease AMH levels [
17]. The clinical effect was notably positive as it could result from improved folliculogenesis and thus improve reproductive outcomes.
Our study demonstrated no significant correlation between AMH and vitamin D levels. Similarly, Drakopoulos and coworkers aimed at finding potential correlations between serum vitamin D levels and ovarian reserve in infertile women. However, researchers did not find any correlations between AMH levels and antral follicle counts (AFC) in patients with normal vitamin D levels and in patients with vitamin D deficiency [
37]. Also, Cappy and coworkers were unable to demonstrate any significant correlation between vitamin D supplementation and AMH levels in women with PCOS diagnosed with vitamin D deficiency [
38]. Additionally, Pearce and coworkers, in their study conducted on 340 PCOS women, did not observe any changes in AMH levels secondary to the changes to vitamin D levels [
39].
Such a large discrepancy in the available literature data may suggest that the mechanism of action is different and probably depends on
VDR polymorphisms rather than on vitamin D levels. Xavier and coworkers in their study demonstrated that Taq1 and Bsm1 polymorphisms were independently associated with PCOS [
40]. The clinical role of
VDR polymorphisms is under consideration. Notably, polymorphisms of the
VDR gene may affect its biological activity by reducing its activity and transcription levels [
41].
VDR SNPs within the coding regions in ovarian signaling pathways could play an important role in reproductive outcomes as they are responsible for the synthesis of hormone receptors, metabolic enzymes, or transport molecules. Several studies revealed the statistical significant correlations between
VDR polymorphisms and clinical and biochemical determinants of PCOS. Dasgupta and coworkers show that the Fok1 polymorphism is associated with infertility, while Cdx2 polymorphism was found to be associated with testosterone levels in PCOS [
42].
As mentioned above, VDR is present within the AMH promoter site. Our study suggests a significant correlation between Fok1 (rs2228570) and Apa1 (rs7975232) polymorphisms of the VDR gene and AMH levels in PCOS women. To the best of our knowledge, this is the first study of the relationship between serum AMH and VDR SNPs in PCOS women. Our study showed that the wild-type variants of Fokl and Apal gene polymorphisms are associated with lower, normal, AMH levels in PCOS women. On the other hand, heterozygous or mutated genes were associated with much higher, abnormal AMH levels. Based on our findings, we hypothesize that the translational complex formed by the VDR gene with Fok1 and Apa1 SNPs within the AMH promoter site leads to the enhancement of AMH synthesis in PCOS women.
The etiology of PCOS and the mechanism of elevated AMH levels in PCOS still remain to be further elucidated. Considering the role of AMH with regard to the regulation of ovarian function, it has been postulated that genetic variants in the signaling pathway can be responsible for the impairment of reproductive function of women. Currently available data show that the
AMH gene polymorphism is connected with the susceptibility and phenotype of PCOS, which suggests that it is one of the factors devoted to the pathogenesis of PCOS [
43]. However, in our study we did not find significant differences in the comparison of
AMH and
AMHR polymorphism frequencies between PCOS patients and controls. In addition, Wang and coworkers, based on their meta-analysis, demonstrated that there is no association of the abovementioned genetic variants of
AMH and
AMHR2 with the development of PCOS [
9].
In conclusion, Fok1 (rs2228570) and Apa1 (rs7975232) VDR polymorphisms seem to be associated with elevated AMH levels in PCOS women, suggesting their possible role in the PCOS pathophysiology. However, the challenge for the future would be further investigation focusing on a molecular mechanism behind VDR SNP.
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