1. Introduction
Endometriosis affects approximately 10% of reproductive-age women worldwide but up to 50% of women diagnosed with infertility [
1,
2]. It is a common, benign, estrogen-dependent, and inflammatory disorder defined as the presence of uterine endometrial tissue outside of the normal location [
3,
4]. According to the most popular theory created by Sampson in the 1920s, it is the result of retrograde menstruation [
5]. Unfortunately, its diagnosis is still a challenge. Only a histopathologic evaluation of a lesion biopsied during surgery (preferably laparoscopy) can make a definitive diagnosis [
6,
7]. Such an approach remains the gold standard today. However, due to the invasive character of surgery and, most of all, vague symptoms, which overlap with the symptoms involving gynecological and gastrointestinal processes, we face a strong diagnostic delay varying from 7 to 12 years [
8,
9,
10,
11,
12]. Although the pathogenesis of endometriosis is, to a great extent, unclear, it is still extensively studied regarding many different pro- and anti-inflammatory factors, such as metalloproteinases, growth factors, cytokines, chemokines, miRNAs, and adhesion molecules, which were shown to be differentially expressed in different clinical samples including the plasma, the eutopic endometrium, and the peritoneal fluid [
13,
14,
15,
16,
17,
18,
19]. Cadherin 12 (CDH12) is one of the adhesion molecules, which is a type II cadherin and a member of the neural cadherin (N-cadherin) gene family. It plays an important role in calcium-dependent cell-to-cell adhesion [
20]. Endometriosis seems to share some similarities in its pathogenesis with cancer, resulting in the presence of cancer-associated mutations in different types of endometriosis [
21]. Additionally, CDH 12 can play a role in neoplastic processes by promoting adhesion, migration, invasion, and angiogenesis [
22].
CDH12 is proven to be involved in cancer progression of non-small cell lung cancer, salivary adenoid cystic cancer, bladder cancer, and colorectal cancer [
23,
24,
25,
26,
27]. In the latter case, it affects the epithelial–mesenchymal transition (EMT), the role of which was also demonstrated in the pathogenesis of endometriosis and infertility [
28,
29,
30,
31,
32,
33]. However, its role in the pathogenesis of endometriosis has not been described yet. There are examples of adhesion molecules involvement such as VCAM-1, Nectin-4, JAM-1, or different types of integrins [
34,
35,
36]. An increased concentration of N-cadherin coexists with higher endometrial cell invasiveness and the ability to migrate in patients with diagnosed endometriosis [
37]. Regarding infertility, the abovementioned epithelial–mesenchymal transition (EMT) plays a vital role in the development of endometrial fibrosis, which characterizes intrauterine adhesions (IUs)—a common cause of uterine infertility [
38]. Pathologic EMT regulates fertility and epithelial functional integrity and promotes fibrosis and tumorigenesis in the reproductive system [
39]. Unfortunately, there is also a lack of publications about CDH 12 involvement in the infertility process despite its well-known participation in the EMT process.
As mentioned before, there are no publications regarding the exact role of CDH12 in the pathogenesis of endometriosis and infertility, nor are there any studies regarding the concentrations of this cadherin in the various biological materials collected from patients diagnosed with endometriosis. Simultaneously, it is common knowledge that the peritoneal fluid is a universally recognized biological material that can be investigated in order to better understand the environment and pathogenesis of endometriosis. Based on the above arguments, we decided to examine cadherin 12 concentration levels in the peritoneal fluid of patients with endometriosis, compared with patients without a visible disease, as the potential pathogenetic justification of CDH12 involvement in this process.
2. Materials and Methods
Biological material was collected during a multicenter, cross-sectional study, which was undertaken at 8 Departments of Obstetrics and Gynecology in Poland between 2018 and 2019 (project number: 6/6/4/1/NPZ/2017/1210/13522, financed by the Ministry of Health): Department of Obstetrics and Gynecology, Medical University of Warsaw; Angelius Provita Hospital in Katowice; Department of Gynecology, Division of Infertility and Reproductive Endocrinology, Obstetrics and Gynecological Oncology at Poznan University of Medical Sciences; Department of Obstetrics and Gynecology, Central Clinical Hospital of the Ministry of Interior in Warsaw; Clinic of Obstetrics and Gynecology, Provincial Combined Hospital in Kielce; Department of Surgical Gynecology and Oncology, Medical University of Lodz; Department of Gynecology and Obstetrics, Provincial Hospital in Przemysl; Department of Gynecology, Gynecology Oncology, and Obstetrics, Institute of Medical Sciences, Medical College of Rzeszow University.
The patients underwent laparoscopy during which they were diagnosed according to the revised American Fertility Society Classification of Endometriosis [
31] and finally confirmed by histopathologic examination. All the patients completed the World Endometriosis Research Foundation (WERF) clinical questionnaire [
40]. As controls, patients without visible endometriosis during laparoscopy were recruited. All the patients underwent surgery because of infertility, pelvic pain, and/or ovarian cysts.
Only patients with suspected idiopathic infertility underwent surgery unless an ovarian cyst was also an indication. Thus, later, we also divided patients with endometriosis into two separate groups due to the similarities in disease activity between the stages in each particular group:
- (1)
Stage I or II endometriosis;
- (2)
Stage III or IV endometriosis.
All the above issues resulted in the inclusion of biological material from 82 patients (44 in the study group and 38 controls).
The exclusion criteria were non-regularly menstruating patients (more than 35 or less than 25 days), age at inclusion below 18 or over 40 years old, patients on any form of hormonal therapy during the last 3 months before laparoscopy, malignant or suspected malignant disease, autoimmunological disease, previous and/or current pelvic inflammatory disease, any prior history of pelvic surgery, uterine fibroids, or polycystic ovaries.
The cycle phase was calculated based on the last menstrual period and the average length of the menstrual cycle. Moreover, the phases of the menstrual cycle in women with and without endometriosis were determined by the histological dating of the eutopic endometrial samples collected simultaneously with pathological lesions.
Written informed consent was collected from all the patients, and the study was approved by the Ethics Committee of the Medical University of Warsaw (KB/223/2017).
Peritoneal fluid was collected via Veress needle aspiration under direct visual inspection at the beginning of the laparoscopy in order to avoid contamination with blood. The procedure was performed at all times in accordance with the Endometriosis Phenome and Biobanking Harmonisation Project standard operating procedures [
41]. The material collection did not have any impact on the medical management of the patients and was performed in the manner of the Declaration of Helsinki. The aspirated peritoneal fluid was spun in all the studied centers at 1000×
g for 10 min at 4 °C. The supernatant was transferred to a fresh 10 mL tube (Sarstedt). The time lapse between peritoneal fluid collection and processing was less than 45 min.
Cadherin 12 concentrations in the peritoneal fluid were determined using an enzyme-linked immunosorbent assay (ELISA) kit (SunRedBio, Shanghai, China) with a minimum detectable concentration of 0.050 ng/mL and the intra- and inter-assay coefficients of variation of less than 10% and less than 12%, respectively. The assay range for Cadherin 12 was 0.08–20 ng/mL. The absorbance at 450 nm was measured using a microplate reader (MULTISCAN GO, Thermo Fisher Scientific, Finland).
Cadherin 12 (CDH12) concentrations between different groups of patients were investigated: patients with vs. without endometriosis, patients with different stages of endometriosis, patients with vs. without infertility, patients with vs. without ovarian cysts, depending on the cycle phase and patients’ age.
Outliers were detected and then excluded using a classic statistical domain based on the interquartile range. The groups were compared by a chi-square test for categorical variables. The Mann–Whitney U test and Student’s t-test were performed for continuous variables depending on the distribution of variables after testing for normal distribution using the Shapiro–Wilk test. The level of statistical significance was set at p < 0.05. Statistical analysis was performed using Python v3.10 programming language.
3. Results
3.1. Clinical Characteristics of Patients
The statistical analysis including 82 patients (44 with endometriosis and 38 without endometriosis) revealed that there were no statistically significant differences (
p = 0.4) in cadherin 12 (CDH12) concentrations between the study group (patients with endometriosis) and the control group (patients without endometriosis). The study and control groups were correctly matched (
Table 1).
3.2. CDH12 Concentration Differences between Patients Depending on Different Factors
Afterward, we closely examined CDH12 concentrations. We sought to investigate the differences in concentrations between the groups of patients studied based on different factors. We aimed to determine if there were possible statistically significant differences in CDH12 concentrations related to age, infertility, stage of endometriosis, presence of ovarian cysts, day of the cycle, and phase of the cycle (
Table 2). There were statistically significant differences in CDH12 concentrations in terms of infertility and primary infertility (
p = 0.009154;
p = 0.009866, respectively). The mean concentration in infertile women was 7.75 (ng/mL) in comparison to 4.74 (ng/mL) in women without infertility. Among those women suffering from primary infertility, the mean concentration was even higher, at 8.49 (ng/mL), almost doubling that observed in those patients without this disorder, at 4.74 (ng/mL).
3.3. Statistical Significance of CDH12 Concentration Differences Based on Stage of Endometriosis and Infertility Factor
Then, the different groups of patients for the statistical significance analysis of CDH12 concentration differences were selected based on their stage of endometriosis and infertility factor. The analysis results are presented below (
Table 3 and
Table 4).
3.4. Characteristics of CDH12 Concentrations Based on Stage of Endometriosis and Infertility Factor
Finally, we present the results showing the characteristics within the different groups of patients based on their endometriosis stage and infertility factor (
Table 5 and
Table 6), which were analyzed in this study.
4. Discussion
The main finding of our study regarded the significantly higher cadherin 12 concentration levels in the peritoneal fluid of patients with primary infertility. Although there are no specific reports on the potential negative effect of cadherin 12 on the fertility of patients with endometriosis, there can be multiple potential mechanisms in which different cadherins may potentially impact fertility.
In a study by Verma et al., the authors investigated the role of cadherins in endometrial receptivity using mouse models [
42]. E-cadherin expression was observed both at the pre-receptive and receptive stages followed by reduced levels in the later stages of implantation, while N-cadherin was detectable only at pre-receptive stages.
It was also shown that a reduction in E-cadherin expression in the blastocyst and endometrial cells results in reduced adhesion to the uterine wall [
43]. The upregulation of E-cadherin expression interrupts the epithelial–mesenchymal transition and also causes reduced endometrial receptivity, as observed in a study by Zhao et al. [
44]. In another study, Zhou et al. investigated the expression of cadherin 6 in the endometrium during the receptive window of infertile and fertile women [
45]. The authors determined that the mid-secretory endometrial samples of patients with primary infertility have reduced cadherin 6 expressions compared with the control group.
Bellati et al. examined E- and K-cadherin expressions in the endometrial samples from women with primary infertility (n = 40), recurrent pregnancy loss (n = 12), and healthy controls (n = 24) [
46]. The endometrial expression of E- and K-cadherin was lower in primarily infertile women and in women with recurrent pregnancy loss than in fertile controls.
Similarly, a decreased E-cadherin expression was observed in infertile patients with intramural fibroids (n = 18) compared with fertile women (n = 12) in a study by Makker et al. [
47].
In another study by Béliard et al., the authors compared E-cadherin expression in endometriosis and the endometrial samples from women with (n = 18) and without (n = 9) endometriosis [
48]. It was observed that the expression of E-cadherin and its receptors in endometriosis and the endometrial samples was similar, and there were no significant differences between the study and control groups.
Ishida et al. examined the characteristics of the endometrium in 66 patients with infertility [
49]. It was observed that in the case of chronic endometritis, the incidence of the epithelial–mesenchymal transition detected by the loss of E-cadherin and positive N-cadherin expression was significantly higher than in the control group. The authors concluded that the epithelial–mesenchymal transition could negatively alter the implantation mechanisms.
The association between cadherins and another infertility mechanism was analyzed by Wang et al. [
50]. The authors determined cadherin 1 to be one of the molecules controlling oocyte meiosis. An increased cadherin 1 expression was observed in mice with depleted centromere protein T, which is a protein responsible for meiotic resumption. Conversely, the overexpression of centromere protein T resulted in decreased cadherin 1 levels.
In our study, we did not observe any differences in cadherin 12 levels between patients with and without endometrial ovarian cysts. Among cadherins, only E-cadherin (CDH1) and N-cadherin (CDH2) concentrations in the endometrial tissue were investigated; decreased concentrations of E-cadherin and increased concentrations of N-cadherin coexisted with higher endometrial cell invasiveness and the ability to migrate in patients with diagnosed endometriosis [
37,
51]. Decreased E-cadherin concentrations were also noticed in the peritoneal fluid of patients with endometriosis [
52], but there are no more details about this study. Sancakli Usta et al. examined the expression of E-cadherin in the eutopic and ectopic endometrial tissue samples collected from endometriomas (n = 32) and compared them with the endometrial tissue samples from healthy controls (n = 30) [
53]. It was observed that women with endometrioma had significantly lower E-cadherin expression in their ectopic tissue than healthy controls. There was no difference in E-cadherin expression between the eutopic and ectopic endometrial samples from the endometrioma subgroup. The authors also observed a negative correlation of E-cadherin expression with the incidence of deep infiltrating endometriosis. There were also fluctuations in E-cadherin expression in the eutopic endometrial tissue during the menstrual cycle, with lower levels during the proliferative phase.
Kang et al. reported that the rs8049282 single nucleotide polymorphism of the E-cadherin gene can be associated with primary infertility in patients with ovarian endometriosis, as it was more prevalent in patients with a history of infertility compared with endometriosis patients with fertility success [
54].
The primary aim of our study was to compare cadherin 12 levels in the peritoneal fluid of patients with endometriosis and healthy controls; however, no significant differences were observed using the ELISA method.
We are aware that one of the greatest limitations of our study is its restricted number of observations. With more patients enrolled in the study, we would be able to investigate the issue of infertility more comprehensively, without decreasing its statistical power. We plan to study the possible differences in CDH12 concentrations between those patients diagnosed with primary infertility in comparison with secondary infertility in general but also among patients with and without endometriosis. For now, a total number of nine patients diagnosed with secondary infertility, which was used in this study, does not give such an opportunity.
Furthermore, an investigation of the plasma instead of the peritoneal fluid could be an interesting idea, as the plasma is easier to access and, therefore, presents a greater diagnostic potential.
5. Conclusions
Based on our study, cadherin 12 (CDH12) in the peritoneal fluid did not show diagnostic potential for endometriosis. However, it can possibly play a role in the pathogenesis of infertility, both in women with and without endometriosis, resulting in statistically significant differences in CDH12 concentrations in the peritoneal fluid between these two groups, compared with fertile women. This can result in a more precise infertility diagnosis and, therefore, more effective treatment.
However, this hypothesis undoubtedly needs further examination in a larger group of patients. Moreover, testing cadherin 12 levels in the plasma can be an idea that is complementary to our work because of the higher diagnostic potential of this biological material in terms of endometriosis as well as infertility.
Author Contributions
Conceptualization, P.L. and K.G.; methodology, K.G. and R.S. (Robert Soczewica); software, R.S. (Robert Soczewica); validation, E.K.-Ż., M.Ż. and K.G.; formal analysis, R.S. (Robert Soczewica) and K.G.; data curation, K.G., R.S. (Robert Soczewica), G.M., M.K. (Mariusz Kiecka), M.L., D.W., R.S. (Robert Spaczyński), P.P., B.B., A.J., T.I., W.R., J.M., M.S., P.S., G.R., K.S., T.K., M.K. (Marek Kluza), M.W. and P.L.; writing—original draft preparation, K.G. and. J.K.-B.; writing—review and editing, K.G., J.K.-B. and P.L.; visualization, K.G.; supervision, P.L.; project administration, K.G.; funding acquisition, K.G. All authors have read and agreed to the published version of the manuscript.
Funding
This research was funded by the Medical University of Warsaw, mini-grant number 1W51/2/M/MG/N/20. This project has received funding from the European Union’s Horizon 2020 research and innovation program under the Marie Skłodowska-Curie grant agreement No. 101008193 TRENDO.
Institutional Review Board Statement
The study was conducted in accordance with the Declaration of Helsinki. The Bioethical Committee of the Medical University of Warsaw was informed about the study and has given a positive statement (AKBE/133/2020).
Informed Consent Statement
Informed consent was obtained from all the subjects involved in the study.
Data Availability Statement
Not applicable.
Conflicts of Interest
The authors declare no conflict of interest.
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Table 1.
Study group (patients with endometriosis) and control group (patients without endometriosis) characteristics.
Table 1.
Study group (patients with endometriosis) and control group (patients without endometriosis) characteristics.
Variable | Patients with Endometriosis (n = 44) | Patients without Endometriosis (n = 38) | p |
---|
CDH 12 concentration (ng/mL) | 4.12 | 3.24 | 0.41 |
(2.11; 10.28) | (2.08; 7.28) |
7.22 | 5.61 |
Age | 30 | 31.5 | 0.61 |
(28; 34) | (27.25; 35) |
31.36 | 30.763 |
Day of cycle | 12 | 10.5 | 0.08 |
(10; 20) | (8; 15.75) |
14.43 | 12.21 |
Infertility | 27 | 20 | 0.75 |
(61.4) | (52.6) |
Primary infertility | 23 | 15 | 0.6 |
(52.3) | (39.5) |
Secondary infertility | 4 | 5 | 1.0 |
(9.1) | (13.2) |
First phase of cycle | 26 | 27 | 0.37 |
(59) | (71) |
Table 2.
Statistical significance of CDH12 concentrations depending on different factors.
Table 2.
Statistical significance of CDH12 concentrations depending on different factors.
Factor | CDH12 Concentration p-Value | Statistically Significant |
---|
Infertility | 0.01 | YES |
Primary infertility | 0.01 | YES |
Secondary infertility | 1.0 | NO |
Age | 0.17 | NO |
Stage of endometriosis | 0.92 | NO |
Ovarian cysts | 0.93 | NO |
Day of cycle | 0.08 | NO |
Phase of cycle | 0.48 | NO |
Table 3.
Statistical significance of CDH12 concentrations between different groups (including patients with infertility).
Table 3.
Statistical significance of CDH12 concentrations between different groups (including patients with infertility).
Group 1 | Group 2 | CDH 12 Concentration p-Value | Statistically Significant |
---|
Patients with endometriosis (study group) and patients with infertility | Patients without endometriosis (control group) and Patients without infertility | 0.02 | YES |
Stage I or II endometriosis and patients with infertility | 0.03 | YES |
Patients without endometriosis (control group) and patients with infertility | 0.01 | YES |
Table 4.
Statistical significance of CDH12 concentrations between different groups (including patients with primary infertility).
Table 4.
Statistical significance of CDH12 concentrations between different groups (including patients with primary infertility).
Group 1 | Group 2 | CDH 12 Concentration p-Value | Statistically Significant |
---|
Patients with endometriosis (study group) and patients with primary infertility | Patients without endometriosis (control group) and Patients without primary infertility | 0.02 | YES |
Stage I or II endometriosis and patients with primary infertility | 0.05 | YES |
Patients without endometriosis (control group) and patients with primary infertility | 0.03 | YES |
Table 5.
Characteristics of CDH 12 concentrations (ng/mL) within different groups (including patients with infertility).
Table 5.
Characteristics of CDH 12 concentrations (ng/mL) within different groups (including patients with infertility).
Group | Median | Mean | Q1 | Q3 |
---|
Patients with endometriosis (study group) and patients with infertility | 3.86 | 8.0 | 2.58 | 13.86 |
Stage I or II endometriosis and patients with infertility | 4.29 | 7.61 | 3.23 | 9.88 |
Patients without endometriosis (control group) and patients with infertility | 4.46 | 7.41 | 3.04 | 11.51 |
Patients without endometriosis (control group) and patients without infertility | 2.33 | 3.61 | 1.47 | 3.91 |
Table 6.
Characteristics of CDH 12 concentrations (ng/mL) within different groups (including patients with primary infertility).
Table 6.
Characteristics of CDH 12 concentrations (ng/mL) within different groups (including patients with primary infertility).
Group | Median | Mean | Q1 | Q3 |
---|
Patients with endometriosis (study group) and patients with primary infertility | 4.73 | 8.58 | 2.58 | 17.92 |
Stage I or II endometriosis and patients with primary infertility | 4.73 | 7.93 | 3.13 | 10.24 |
Patients without endometriosis (control group) and patients with primary infertility | 5.09 | 8.34 | 2.98 | 12.88 |
Patients without endometriosis (control group) and patients without primary infertility | 2.41 | 3.83 | 1.55 | 4.69 |
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