Background
Diminished ovarian reserve (DOR) often results in reduced fecundability, accompanied by reduced oocyte quantity and decreased oocytes quality. These phenomena also occur during normal ovarian aging [
1,
2]. Due to the close relationship between DOR with poor ovarian response, DOR patients usually have a higher rate of in vitro fertilization (IVF) failure [
3,
4]. These difficulties are frequently encountered by reproductive physicians and are a major challenge in the field of reproductive medicine. Decreased oocyte capacity is believed to be partly attributed to oxidative stress and long-term use of low-dose antioxidants containing vitamin A has been demonstrated to favor ovarian function by decreasing the accumulation of reactive oxygen species (ROS) [
5,
6].
Vitamin A, also known as retinol, is an antioxidant. Its important role in repairing oxidative damage to the ovary in conjunction with other antioxidative vitamins has been extensively studied [
6‐
9]. However, retinol and its metabolites are involved in normal physiological ovarian follicle development and maturation in different species [
10]. Data on the potential relationship between retinol levels and ovarian reserve are limited. Serum retinol-binding protein 4 (RBP4), a known transport protein of retinol, binds to retinol at a ratio of 1:1 and delivers retinol to peripheral target tissues. Therefore, serum RBP4 levels can predict retinol concentrations in the blood to a certain degree [
11].
Oxidative stress occurs when the antioxidation system is weakened, at which time, ROS levels increase to induce chronic inflammation and increased levels of inflammatory cytokines. Among them, C-reactive protein (CRP) has been reported to play a key role in this association [
12]. Some studies have shown that higher CRP concentrations are related to lower levels of retinol in inflammatory diseases [
13‐
15], but other studies have failed to find this connection [
16]. These contradictory results may be due to differences in the races of the study groups [
17], the populations included [
16] and detection methods used [
18]. Furthermore, CRP has recently, been identified as a marker of cardiovascular risk that is inversely correlated with anti-Mullerian hormone (AMH) levels in DOR patients [
19,
20]. However, so far, there are few reports on the relationships between RBP4, CRP and DOR. Our study was designed to investigate serum RBP4 and CRP concentrations in DOR patients and to further examine the possible link between AMH and RBP4 or, CRP levels.
Discussion
In this cross-sectional study, the concentrations of RBP4 and hs-CRP in the plasma of DOR patients were explored for the first time. We found lower RBP4 levels and higher hs-CRP levels in DOR subjects and a positive association between RBP4 and AMH. After adjustments were made for age and BMI as covariates, this relationship still existed. hs-CRP was not associated with AMH; therefore, RBP4 seems to be associated with ovarian reserve.
Like vitamin E, vitamin A (retinol), is an antioxidant [
8]. Because retinol is easily decomposed when exposed to light, coupled with the limitations of detection technology, RBP4 is considered to be a good indicator of serum retinol levels in some cases [
18]. RBP4 has been recognized as an adipokine and as one of the oxidative stress markers involved in the pathogenesis of obesity-related metabolic diseases [
23]. However, most of these studies were focused on adipose tissues, in which the effects of RBP4 were believed to be attributed to apo-RBP4, a form of RBP4 that does not bind retinol [
24‐
26]. Some studies have shown that the antioxidative effects of RBP4, also known as RBP, may be related to holo-RBP4, which refers to RBP4 combined with retinol [
27]. Retinol/RBP (holo-RBP4) was the primary form of retinol in the blood, and its proportion reaches 99% under fasting condition [
28]. Previous studies have shown that the levels of serum RBP in retinol-depleted rats was extremely low [
29], after administration of retinol, holo-RBP was secreted immediately into the serum [
30]. Under several pathophysiological conditions, decreased serum RBP4 levels were related to impaired synthesis and/or secretion of RBP4. This was common in several hepatopathies [
31], infection [
32] or vitamin A deficiency [
33]. In our study, we preliminary ruled out women with any history of liver-related diseases and infection disease, and collected fasting blood, so as to better reflect retinol concentration in the blood.
Due to limitations of commercial Elisa kits, it is impossible to distinguish the above two kinds of RBP4 and evaluated the total RBP4 levels. However, in vitro studies have revealed that apo-RBP4 induced inflammatory cascades [
34]. Clinical studies have also found elevated apo-RBP4 in obese subjects and type 2 diabetes [
23]. One explanation for this phenomenon may be the lack of retinol in fat, which was insufficient to bind RBP, then apo-RBP was released from the adipose into the blood, thereby diluting serum holo-RBP concentration. Therefore, increased RBP4 levels in the blood of patients with obesity and metabolic diseases does not mean increased levels of retinol. Indeed, the results of Erikstrup C et al.’s study on patients with type 2 diabetes further confirmed this view [
24]. They found lower levels of retinol in the blood of such patients, Thus, the concentration of apo-RBP4 was strongly associated with BMI. In our study, we set an even stricter boundary and exclude all people who were obese, and 94.5% of the participants had a BMI of 25 kg/m
2 or less in our study. Additionally, those at risk of any metabolic diseases were excluded. Therefore, to a certain extent, we controlled for the factors that led to changes in apo-RBP4 levels so that RBP4 levels could better predict blood retinol levels. This view was verified in another study. Hermsdorff et al. [
35] found that vitamin A intake and RBP4 levels were positively correlated in Hispanic women who were healthy and not obese (BMI<30 kg/m
2).
Ovarian dysfunction caused by oxidative stress has been reported to be associated with DOR. Long-term low-dose use of antioxidants containing vitamin A can protect the ovary from ROS induced by oxidative stress [
5,
6,
9]. According to prior studies, the accumulation of ROS in granulosa cells caused ovary response poor to FSH in older women through downregulation of follicle-stimulating hormone (FSHR) expression and dysregulation of the FSHR signal transduction pathway [
36,
37]. The physiological function of granulosa cells and follicular development is inseparable from the communication between FSH and its receptor. Any changes in FSHR, including reduced contact between FSHR and its ligand and reduced signaling after contacting, may result in decreased ovarian reserve [
38]. To the best of our knowledge, fewer studies have evaluated the effect of abnormal retinol alone on ovarian reserve. However, these studies indirectly evaluated the correlation between RBP4 and FSHR. Overexpression of RBP4 can upregulate the expressions of FSHR in granulosa cells [
39]. This fact was further supported by Rebeca et al. [
40]. As ovarian reserve decreases, FSHR expression in the ovary decreases. Similar to this study, Zeinab et al. [
41] also showed a downward trend in FSHR transcript expression in DOR patients. However, in this study, the difference was not significant, and they attributed it mainly to the limited sample size. Contrary to the above findings, Hattori, M.et al. [
42] found that retinoic acid (RA), the main active form of retinol in vivo, inhibited FSHR expression, thereby preventing immature granulosa cells from further developing into mature cells. However, the contradictory findings on the effects of retinol and its binding protein and derivates on granulosa cells during follicle development may be because the studies involved different species, examined different groups of subjects, were conducted in diverse geographical areas, had variability in sample size and used different experimental methods. These studies collectively suggested that retinol may regulate ovarian reserve. Hence, it is reasonable to speculate that abnormal RBP4 levels may be associated with DOR. According to our study, the serum RBP4 levels of DOR patients were lower than those of NOR patients, and RBP4 levels were positively correlated with AMH. This association has not been studied or proved before. This association may just be a link, rather than a necessary causal relationship. Nevertheless, it provides a reference basis for our future research.
Oxidative stress induces an abnormal immune response, together with an increase in inflammatory markers. Among them, CRP is a classic marker of chronic inflammation [
43] and has been shown to be significantly related to DOR. Two cross-sectional studies found increased CRP in young women (under the age of 35 years) with DOR [
19,
20]. Our observation that hs-CRP levels are higher in DOR patients is in line with previous studies. However, after we adjusted for covariates, hs-CRP was not associated with AMH. In previous studies that addressed the relationship between hs-CRP and AMH, there was either a negative correlation [
19,
20] or no correlation [
44], so the relationship between them still needs to be explored. In a large cross-sectional study, scientists analyzed a group of women aged 21–64 years and suggested negatively correlations between AMH levels and BMI or, fasting glucose. However, we did not observe the same relationship between AMH and BMI. It is worth noting that the BMI levels of the people in our study were all below 28, and 94.5% of them had a BMI of 25 kg/m
2 or less, this criterion was more stringent than the standards used in previous studies. Our study included only women with normal serum levels of lipids and fasting glucose and women with no family history of cardiovascular diseases because abnormalities in these biochemical parameters and a family history of cardiovascular diseases may impact the plasma levels of CRP and AMH.
To the best of our knowledge, this study is the first to explore the potential connection between the ovarian reserve marker AMH and RBP4, hs-CRP. This research has the following advantages: First, we assessed a group of patients within a normal BMI range and who were under the age of 40 years and had no metabolic risk factors, to eliminate the additional effects of these factors on AMH and biochemical indicators in this experiment. Second, all of our blood samples were taken before IVF started, considering that different doses and kinds of ovulation drugs may have unknown impacts on inflammation and oxidative stress, thus minimizing the potential measurement bias caused by IVF treatment and providing the possibility for an accurate assessment of ovarian function.
Our research has limitations. First, the cross-sectional character of the study that did not able to follow-up of participants at a later stage. Second, we did not perform a direct analysis of retinol but did use RBP4 instead. This was because RBP4 is more stable than retinol and because RBP4 detection kits are less expensive and more easily obtained than retinol detection kits. Third, we did not go on to assess this association in the follicular fluid of the patients due to the small sample sizes of the follicular fluid we collected. Currently, we are still enrolling patients who meet the criteria and collecting both blood and follicular fluid for further research. Fourth, the small number and scope of the research population is mainly related to our strict inclusion and exclusion criteria. It is necessary to further expand the research to include a broader patient group. Nevertheless, our results may provide insight into the potential mechanisms that regulate ovarian reserve.
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