Association between GnRH Receptor Polymorphisms and Luteinizing Hormone Levels for Low Ovarian Reserve Infertile Women
by
, ,
Shun-Long Weng
1,2,3, 
Shu-Ling Tzeng
4,5,
Chun-I Lee
6,7,8,
Chung-Hsien Liu
6,7,
Chun-Chia Huang
8,
Shun-Fa Yang
4,5
,
Maw-Sheng Lee
4,6,8 and
Tsung-Hsien Lee
4,6,8,*
1
Department of Obstetrics and Gynecology, Hsinchu MacKay Memorial Hospital, Hsinchu 30071, Taiwan
2
Department of Medicine, MacKay Medical College, New Taipei 25245, Taiwan
3
Mackay Junior College of Medicine, Nursing and Management College, Taipei 11260, Taiwan
4
Institute of Medicine, Chung Shan Medical University, Taichung 40203, Taiwan
5
Department of Medical Research, Chung Shan Medical University Hospital, Taichung 40203, Taiwan
6
Department of Obstetrics and Gynecology, Chung Shan Medical University Hospital, Taichung 40203, Taiwan
7
Department of Medicine, School of Medicine, Chung Shan Medical University, Taichung 40203, Taiwan
8
Division of Infertility Clinic, Lee Women’s Hospital, Taichung 40602, Taiwan
*
Author to whom correspondence should be addressed.
Int. J. Environ. Res. Public Health 2021, 18(13), 7006; https://doi.org/10.3390/ijerph18137006
Submission received: 19 May 2021
/
Revised: 24 June 2021
/
Accepted: 26 June 2021
/
Published: 30 June 2021
(This article belongs to the Section Women's Health)
Abstract
:The choice of ovarian stimulation protocols in assisted reproduction technology (ART) cycles for low ovarian reserve patients is challenging. Our previous report indicated that the gonadotrophin-releasing (GnRH) agonist (GnRHa) protocol is better than the GnRH antagonist (GnRHant) protocol for young age poor responders. Here, we recruited 269 patients with anti-Müllerian hormone (AMH) < 1.2 ng/mL undergoing their first ART cycles for this nested case-control study. We investigated the genetic variants of the relevant genes, including follicular stimulating hormone receptor (FSHR; rs6166), AMH (rs10407022), GnRH (rs6185), and GnRH receptor (GnRHR; rs3756159) in patients <35 years (n = 86) and patients ≥35 years of age (n = 183). Only the genotype of GnRHR (rs3756159) is distributed differently in young (CC 39.5%, CT/TT 60.5%) versus advanced (CC 24.0%, CT/TT 76.0%) age groups (recessive model, p = 0.0091). Furthermore, the baseline luteinizing hormone (LH) levels (3.60 (2.45 to 5.40) vs. 4.40 (2.91 to 6.48)) are different between CC and CT/TT genotype of GnRHR (rs3756159). In conclusion, the genetic variants of GnRHR (rs3756159) could modulate the release of LH in the pituitary gland and might then affect the outcome of ovarian stimulation by GnRHant or GnRHa protocols for patients with low AMH levels.
1. Introduction
In assisted reproduction technology (ART) for infertile couples, management for patients with an inadequate ovarian response is challenging [1,2,3,4]. Although investigators propose two international definitions, the Bologna [5] and POSEIDON [6] criteria, for poor responders, the choice of ovarian stimulation protocols for these patients is still controversial [7,8]. Most reports recommended the protocol for the use of gonadotropin-releasing hormone (GnRH) antagonist (GnRHant) or the mild stimulation protocol (MSP) for the poor responders, instead of the long protocol for using GnRH agonist (GnRHa) [9]. The primary reason for this recommendation is the cost-effective consideration, which is adjusted by the cost per oocyte retrieved and the number of exogenous gonadotropin injections. However, because it remains controversial, the GnRHa protocol is less recommended for poor responders.
The number of retrieved oocytes and patients’ age are the key predictors for a successful pregnancy and live birth in ART cycles [1]. The aneuploidy rates of oocytes/embryos are intimately correlated with maternal age. This means that oocyte quantity and quality (euploidy) are the critical factors for successful ART cycles. Our previous study, however, indicated that for young patients (<35 years of age) with low anti-Mullerian hormone (AMH) levels, the GnRHa protocol is better than the GnRHant protocol in terms of embryos available for transfer and pregnancy rate [10]. A randomized clinical trial also reported that the GnRHant protocol is correlated with a higher cancellation rate than that of the GnRHa protocol [11]. Those results suggested that the follicular and the subsequent embryo development after controlled ovarian stimulation might differ between GnRHant and GnRHa protocols for poor responders.
The response (number of retrieved oocytes) to ART protocols could be predicted by ovarian reserve markers, such as AMH or antral follicle count (AFC) [12,13]. However, some researchers observed unexpected poor ovarian responders after controlled ovarian stimulation in ART cycles, such as POSEIDON group 1 and group 2 patients. The single nucleotide polymorphism (SNP) in the hormones and hormone receptors related to follicular growth and development might cause such inadequate ovarian response [14]. For example, SNPs of AMH [14,15], follicular stimulating hormone (FSH) [16,17], and FSH receptor (FSHR) [16,17,18,19,20,21] have been surveyed to explain the ovarian response subsequent to controlled ovarian stimulation in ART cycles [14,17].
We previously reported a better pregnancy outcome by the GnRHa than the GnRHant protocol in POSEIDON group 3 patients [10]. Therefore, we raised the hypothesis that, in addition to the SNPs of AMH (rs10407022) and FSHR (rs6166), the SNPs of GnRH (rs6185) [22] or GnRH receptor (GnRHR; rs3756159) [23], may account for the difference of embryo development and pregnancy outcome for patients with low AMH levels (POSEIDON group 3 and group 4). The present study results revealed that the distribution of SNP of GnRHR (rs3756159) varied between POSEIDON group 3 and group 4 patients, and those SNPs are associated with varied baseline LH levels in ART cycles.
2. Materials and Methods
2.1. Study Design and Patient Selection
The infertile couples who underwent their first ART treatment cycle from January 2014 to December 2015 were recruited for this prospective nested case-control study. The inclusion criteria were as follows: (1) women age <45 years old; (2) serum AMH <1.2 ng/mL before ART treatment; and (3) no histories of ovarian surgery or pelvic radiation treatment. We drew a venous blood sample for DNA extraction and subsequent analysis for the chosen SNPs. The Institutional Review Board of Chung Shan Medical University Hospital approved the study protocol (CS13194 and CS2-14033). A written informed consent was obtained from each participant. All the recruited women for this analysis were Han Chinese people. Clinical trial register number: ISRCTN12768989.
We attempted to study the SNPs of related hormone molecules for ovarian responses in the GnRHa and GnRHant protocols. The methods for chosen SNPs were in line with our previous report [24], which was based on the searches in dbSNP (http://www.ncbi.nlm.nih.gov/snp, accessed 3 November 2013) and the international HapMap project (http://hapmap.ncbi.nlm.nih.gov, accessed 3 November 2013). Consequently, we surveyed the SNPs of AMH 146 T > G (rs10407022), FSHR Asn680Ser (rs6166), GnRH (rs6185), and GnRHR (rs3756159). The AMH 146 T > G is at the coding region of AMH and causes amnio acid substitution. FSHR Asn680Ser (rs6166) is the most common reported SNP that related to ovarian responses in ART cycles [16,17,18,19,20,21]. GnRH (rs6185) and GnRHR (rs3756159) are chosen to discriminate the different activities of GnRHa and GnRHanta in ART treatment. GnRH (rs6185) is located at the coding region and results in amnio acid substitution. GnRHR (rs3756159) is located at position 68305073 on chromosome 4 in the 5’ untranslated region of the GnRHR gene.
2.2. ART Treatment Protocol and Hormone Analysis
During the study period from January 2014 to December 2015, we recruited those patients undergoing the same GnRHa stimulation protocol to avoid bias in the association between the chosen SNPs and ART outcomes. The ovarian stimulation procedure is the same as previously described [24]. The GnRHa protocol comprises daily injections of 0.5 mg of leuprolide acetate (Lupron; Takeda Pharmaceutics, Konstanz, Germany) from the mid-luteal phase (cycle day 21) of the previous cycle. After that, recombinant FSH (Gonal-F, Merck-Serono, Darmstadt, Germany) or highly purified FSH (Menopur; Ferring Pharmaceuticals) was administered daily for follicular growth. We used 10,000 IU human chorionic gonadotropin (Profasi, Serono, Norwell, MA, USA) to trigger final oocyte maturation, and ovum pick-up was performed 36 to 38 h later.
The baseline AMH, FSH, luteinizing hormone (LH), and estradiol (E2) levels were measured on day 2 to 3 of the menstruation cycles before the controlled ovarian stimulation. On day 2 to 3 of the hyper-stimulation cycle prior to gonadotropin injection, FSH, LH, and E2 levels were assessed again. On the day of hCG trigger, measurement of E2, LH, and progesterone (P4) levels was performed. The AMH/MIS ELISA kit (Immunotech/Beckman Coulter Inc., Marseille Cedex, France) was used in duplicate to assess serum AMH levels. A specific immunometric assay kit (Access; Beckman Coulter Inc., Fullerton, CA, USA) was utilized to measure serum FSH, LH, E2, and P4 levels. The sensitivity, intra-assay coefficient of variation (CV), and interassay CV for the FSH measurement were 0.2 mIU/mL, 4.3%, and 5.6%, respectively. The sensitivity, intra-assay CV, and interassay CV for the LH evaluation were 0.2 mIU/mL, 5.4%, and 6.4%, respectively.
2.3. DNA Extraction and Determination of Genotypes
We obtained genomic DNA with a QIAamp DNA blood mini kit (Qiagen, Valencia, CA, USA) from EDTA anti-coagulated venous blood. Genomic DNA extraction was performed following the manufacturer’s instructions as in a previous report [25]. We used Tris-EDTA (TE) buffer to disperse the extracted DNA and then measured the optical density at 260 nm to determine DNA quantity. The final solution was stored at −20 °C and used as polymerase chain reaction (PCR) templates. Genotyping of the four studied SNPs was assessed with the ABI StepOne™ Real-Time PCR System (Applied Biosystems, Foster City, CA, USA), and allele discrimination was analyzed using SDS version 3.0 software (Applied Biosystems, Foster City, CA, USA) and the TaqMan assay (Applied Biosystems, Foster City, CA, USA) [26]. The primers used for each genotype are listed in Table 1.
2.4. Statistical Analysis
The data supplemental to this prospective study is listed in the Supplementary File S1: SNP_low_AMH_single.txt A chi-square test was performed to determine the Hardy–Weinberg equilibrium, including AMH (rs10407022), FSHR (rs6166), GnRH (rs6185), and GnRHR (rs3756159). Then, a chi-square test examined the associations between POSEIDON group 3/4 and tested SNPs under the genotypic (AA versus Aa versus aa) and recessive (AA versus Aa/aa) models.
The Kolmogorov–Smirnov test was used for the demographic characteristics and other clinical parameters about ovarian responses to determine the distribution of those variables. After that, the continuous variables are presented as medians (interquartile range (IQR, 25th–75th percentile)), whereas categorical variables are shown as numbers and percentages. We used the Mann–Whitney U test (for continuous variables) or chi-square test (for categorical items) to compare the differences between groups with genetic variants under the recessive model (AA versus Aa + aa). All data were analyzed using the IBM SPSS Statistics for Windows, Version 22.0 (IBM Corp., Armonk, NY, USA). p-values < 0.05 were considered statistically significant.
3. Results
A total of 269 patients with low AMH levels undergoing their first IVF/ICSI cycles were recruited for this nested case-control study in a prospective cohort. The 269 patients were divided into young (<35 years of age, POSEIDON group 3, n = 86) and advanced (≥35 years of age, POSEIDON group 4, n = 183) age groups.
The representative results of real-time PCR and TagMan assay for each SNP genotype are shown in Figure 1 (for AMH 146 T > G (rs10407022)), Figure 2 (for FSHR A2039G (rs6166)), Figure 3 (for GnRH-1 (rs61850)), and Figure 4 (for GnRHR-1 (rs3756159)).
3.1. The Distribution of AMH, FSHR, GnRH, and GnRHR
The SNPs in AMH 146 T > G (rs10407022; Table 2), FSHR A2039G (rs6166; Table 3), and GnRH-1 (rs6185; Table 4), were not correlated with patients with diminished ovarian reserve phenotype. Only SNP in GnRHR-1 (rs3756159) was distributed differently in young (CC 39.5%, CT/TT 52 (60.5%)) versus advanced (CC 24.0%, CT/TT 139 (76.0%)) age groups (recessive model, p = 0.0091; Table 5).
3.2. The Clinical Characteristics of Patients with Varied Genotypes of GnRHR SNP (rs3756159)
Table 6 demonstrated the patients’ clinical parameters with the varied genotypes of GnRHR SNP (rs3756159). Among the clinical parameters related to ART cycles, only the baseline LH levels (3.60 (2.45 to 5.40) vs. 4.40 (2.91 to 6.48)) are different between the CC and CT/TT genotypes of GnRHR SNP (rs3756159).
Figure 5 revealed the baseline LH levels in POSEIDON group 3 and 4 patients divided by GnRHR SNP (rs3756159) genotypes (CC vs. CT/TT). For POSEIDON group 3 patients, the baseline LH levels are 3.40 (2.40 to 5.30) in the CC vs. 4.40 (2.85 to 6.46) in the CT/TT genotypes (p = 0.095 by Mann–Whitney U test). Furthermore, the baseline LH levels are 3.65 (2.70 to 5.90) in the CC vs. 4.50 (2.93 to 6.48) in the CT/TT genotypes (p= 0.152 by Mann–Whitney U test) in POSEIDON group 4 patients.
4. Discussion
In the present study, we found that the young patients with low AMH levels (POSEIDON group 3) are associated with a higher frequency of wild-type CC of GnRHR (rs3756159). Interestingly, we also noted a lower baseline of serum LH in patients with CC GnRHR (rs3756159). The results indicated that GnRHR SNP rs3756159 distributed significantly differently between POSEIDON group 3 and group 4 patients and might modulate the ovarian responses using GnRHa or GnRHanta protocols.
The primary physiological function of GnRH-GnRHR signaling is to release FSH and LH from the pituitary gland. The high baseline serum LH in patients with the CT/TT GnRHR (rs3756159) genotype indicated that the GnRHR (rs3756159) might modulate the function of GnRH on the target organs or tissues. The GnRHR (rs3756159) is located at the 5′ upstream untranslated region of the GnRHR gene. How the genetic variants affect the protein structure or function of GnRHR deserves further investigation. Interestingly, our previous report also showed higher LH levels in POSEIDON group 4 than those in POSEIDON group 3 for patients with GnRHa or GnRHant protocols [10]. Both reports indicated that the high LH levels in POSEIDON group 4 patients might correlate with the genetic variants of GnRHR (rs3756159). Furthermore, such different LH levels might affect follicular and embryo development [27,28,29].
The use of LH-containing agents, such as human menopausal gonadotropins (HMG), could improve the live birth rate for POSEIDON group 3 and 4 patients [27]. Nonetheless, the supplement of recombinant LH for IVF patients is beneficial for women 36–39 years of age but not young (<35 years) normal responders in a recent systemic review [28]. Furthermore, the GnRHa protocol is associated with a deeper suppression of LH, the supplementary of recombinant LH is no benefit for young patients in that meta-analysis [28]. It seems that the benefit of high serum LH levels or supplementing recombinant LH is only exhibited among women >35 years of age. By contrast, for women <35 years, the GnRHant protocol is associated with a higher rate of cancellation in our previous report for poor responders [10] and a large retrospective analysis by Grow et. al. in 2014 for women with a good prognosis [29].
The GnRHR (rs3756159) features a modulation effect of LH release from the pituitary gland in the present study. Although the GnRHR (rs3756159) CT/TT genotype is associated with a higher baseline serum LH levels and more common in POSEIDON group 4 patients, the benefit of high LH levels is demonstrated for women 36–39 years of age, in other words, the POSEIDON group 4 patients. These might partially explain why the GnRHa protocol’s performance was better than the GnRHant protocol for POSEIDON group 3 patients, but the efficacy of these two protocols is almost equal for POSEIDON group 4 patients in our previous report [10].
The limitation of the present study includes a relatively small sample size, and we did not recruit patients with GnRHant protocol. The baseline LH levels are higher in patients with GnRHR (rs3756159) CT/TT genotype than those with CC genotype either POSEIDON group 3 or group 4 patients, but the difference did not reach statistical significance (Figure 1). Nonetheless, the effect of GnRHR genotype on baseline LH levels is exhibited before the commence of controlled ovarian stimulation, no matter which stimulation protocol would be used.
The FSHR SNPs, including A2039G (rs6166), are the most common studied genetic variants related to ovarian response in ART treatment [16,17,18,19,20,21]. A recent meta-analysis indicated that FRHR rs6166 is associated with premature ovarian insufficiency (POI) in an Asian population [20]. In the present study, although most of the population is younger than the age of 40 (for the definition of POI), the reference group consists of poor responders < 35 years of age instead of normal responders. Furthermore, the ovarian dysfunction in the patients we recruited for this prospective study is not as severe as those in POI patients. That may explain why FSHR rs6166 is not different between POSEIDON group 3 and group 4 patients in the present study.
5. Conclusions
The genetic variants at GnRHR (rs3756159) distributed differently between POSEIDON group 3 and group 4 patients. The CC phenotype is more common in POSEIDON group 3 patients than in POSEIDON group 4 patients. Furthermore, the CC phenotype is associated with lower LH levels compared with the CT/TT phenotype. The GnRHR (rs3756159) may modulate the ovarian responses using GnRHa or GnRHant protocols. The effect of GnRHR (rs3756159) on ovarian responses and embryo development deserves further investigation.
Supplementary Materials
The data supplemental to this prospective study is available online at https://www.mdpi.com/article/10.3390/ijerph18137006/s1, File S1: SNP_low_AMH_single.txt.
Author Contributions
Conceptualization, S.-L.W., T.-H.L. and M.-S.L.; methodology, T.-H.L. and S.-F.Y.; validation, S.-L.T., C.-C.H. and C.-I.L.; formal analysis, S.-L.W. and T.-H.L.; data curation, C.-C.H.; writing—original draft preparation, C.-I.L.; writing—review and editing, C.-H.L.; project administration, S.-L.T.; funding acquisition, T.-H.L. All authors have read and agreed to the published version of the manuscript.
Funding
This research was funded by the Hsinchu MacKay Memorial Hospital, grant number CSMU-HCMMH-107-02.
Institutional Review Board Statement
The study was conducted according to the guidelines of the Declaration of Helsinki and approved by the Institutional Review Board of Chung Shan Medical University Hospital (CS13194 and CS2-14033).
Informed Consent Statement
Informed consent was obtained from all subjects involved in the study.
Data Availability Statement
The data presented in this study are available in Supplementary Materials.
Acknowledgments
We acknowledge administrative and technical support by Hui-Mei Tsao and En-Hui Cheng.
Conflicts of Interest
The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, or in the decision to publish the results.
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Figure 1.
Representative TaqMan assay for AMH rs10407022 genotyping. The FAM (blue) and VIC (green) fluorescence probes detect T and G alleles, respectively. The ROX (red) fluorescence probes are used for calibration.
Figure 1.
Representative TaqMan assay for AMH rs10407022 genotyping. The FAM (blue) and VIC (green) fluorescence probes detect T and G alleles, respectively. The ROX (red) fluorescence probes are used for calibration.
Figure 2.
Representative TaqMan assay for FSHR (rs6166) genotyping. The FAM (blue) and VIC (green) fluorescence probes detect A and G alleles, respectively. The ROX (red) fluorescence probes is used for calibration.
Figure 2.
Representative TaqMan assay for FSHR (rs6166) genotyping. The FAM (blue) and VIC (green) fluorescence probes detect A and G alleles, respectively. The ROX (red) fluorescence probes is used for calibration.
Figure 3.
Representative TaqMan assay for GNRH1 (rs6185) genotyping. The FAM (blue) and VIC (green) fluorescence probes detect G and C alleles, respectively. The ROX (red) fluorescence probes is used for calibration.
Figure 3.
Representative TaqMan assay for GNRH1 (rs6185) genotyping. The FAM (blue) and VIC (green) fluorescence probes detect G and C alleles, respectively. The ROX (red) fluorescence probes is used for calibration.
Figure 4.
Representative TaqMan assay for GnRHR (rs3756159) genotyping. The FAM (blue) and VIC (green) fluorescence probes detect C and T alleles, respectively. The ROX (red) fluorescence probes is used for calibration.
Figure 4.
Representative TaqMan assay for GnRHR (rs3756159) genotyping. The FAM (blue) and VIC (green) fluorescence probes detect C and T alleles, respectively. The ROX (red) fluorescence probes is used for calibration.
Figure 5.
The baseline LH levels for patients with various GnRHR rs3756159 genotypes. There was no significant difference of these LH levels between CC vs. CT/TT genotypes in young (POSEIDON group 3, p = 0.095) or advanced age (POSEIDON group 4, p = 0.152) patients by Mann–Whitney U test.
Figure 5.
The baseline LH levels for patients with various GnRHR rs3756159 genotypes. There was no significant difference of these LH levels between CC vs. CT/TT genotypes in young (POSEIDON group 3, p = 0.095) or advanced age (POSEIDON group 4, p = 0.152) patients by Mann–Whitney U test.
Table 1.
The context sequence of four primers to detect AMH, FSHR, GnRH, and GnRHR SNPs in the study.
Table 1.
The context sequence of four primers to detect AMH, FSHR, GnRH, and GnRHR SNPs in the study.
| Variable | Assay ID | Context Sequence |
|---|---|---|
| AMH 146 T > G (rs10407022) | C__25599842_10 | GAAGACTTGGACTGGCCTCCAGGCA[G/T] CCCACAAGAGCCTCTGTGCCTGGTG |
| FSHR A2039G (rs6166) | C___2676874_10 | AGGGACAAGTATGTAAGTGGAACCA[C/T] TGGTGACTCTGGGAGCTGAAGAGCA |
| GnRH-1 (rs6185) | C___1529427_1_ | CTGGCTGGAGCAGCCTTCCACGCAC[C/G] AAGTCAGTAGAATAAGGCCAGCTAG |
| GnRHR-1 (rs3756159) | C__27477550_10 | AACATGAAAGGTATAAAGCCCTCAA[A/G] TGCAGGGTGTGGCTATGAAAGTCGG |
Table 2.
The frequencies of AMH 146T > G (rs10407022) SNP among women with serum AMH < 1.2 ng/mL in varied age groups.
Table 2.
The frequencies of AMH 146T > G (rs10407022) SNP among women with serum AMH < 1.2 ng/mL in varied age groups.
| AMH 146 T > G (rs10407022) | Age < 35 Years (n = 86) | Age ≥ 35 Years (n = 183) | p Value 1 | ||
|---|---|---|---|---|---|
| Genotype | n | % | n | % | |
| TT | 37/86 | 43.0 | 62/183 | 33.9 | Reference |
| TG | 37/86 | 43.0 | 90/183 | 49.2 | 0.1913 |
| GG | 12/86 | 14.0 | 31/183 | 16.9 | 0.2773 |
| Recessive | |||||
| TT | 37/86 | 43.0 | 62/183 | 33.9 | Reference |
| TG/GG | 49/86 | 57.0 | 121/183 | 66.1 | 0.1478 |
| Allele | |||||
| T | 111/172 | 64.5 | 214/366 | 58.5 | Reference |
| G | 61/172 | 35.5 | 152/366 | 41.5 | 0.1802 |
1 by Chi-square test.
Table 3.
The frequencies of FSHR A2039G (rs6166) SNP among women with serum AMH < 1.2 ng/mL in varied age groups.
Table 3.
The frequencies of FSHR A2039G (rs6166) SNP among women with serum AMH < 1.2 ng/mL in varied age groups.
| FSHR A2039G (rs6166) | Age < 35 Years (n = 86) | Age ≥ 35 Years (n = 183) | p Value 1 | ||
|---|---|---|---|---|---|
| Genotype | n | % | n | % | |
| AA | 30/86 | 34.9 | 73/183 | 39.9 | Reference |
| AG | 48/86 | 55.8 | 91/183 | 49.7 | 0.3746 |
| GG | 8/86 | 9.3 | 19/183 | 10.4 | 0.9593 |
| Recessive | |||||
| AA | 30/86 | 34.9 | 73/183 | 39.9 | Reference |
| AG/GG | 56/86 | 65.1 | 110/183 | 60.1 | 0.4316 |
| Allele | |||||
| A | 108/172 | 62.8 | 237/366 | 64.8 | Reference |
| G | 64/172 | 37.2 | 129/366 | 35.2 | 0.6582 |
1 by Chi-square test.
Table 4.
The frequencies of GnRH-1 (rs6185) SNP among women with serum AMH < 1.2 ng/mL in varied age groups.
Table 4.
The frequencies of GnRH-1 (rs6185) SNP among women with serum AMH < 1.2 ng/mL in varied age groups.
| GnRH-1 (rs6185) | Age < 35 Years (n = 86) | Age ≥ 35 Years (n = 183) | p Value 1 | ||
|---|---|---|---|---|---|
| Genotype | n | % | n | % | |
| GG | 25/86 | 29.1 | 54/183 | 29.5 | Reference |
| GC | 43/86 | 50.0 | 93/183 | 50.8 | 0.9966 |
| CC | 18/86 | 20.9 | 36/183 | 19.7 | 0.8387 |
| Recessive | |||||
| GG | 25/86 | 29.1 | 54/183 | 29.5 | Reference |
| GC/CC | 61/86 | 70.9 | 129/183 | 70.5 | 0.9414 |
| Allele | |||||
| G | 93/172 | 54.1 | 201/366 | 54.9 | Reference |
| C | 79/172 | 45.9 | 165/366 | 45.1 | 0.8539 |
1 by Chi-square test.
Table 5.
The frequencies of GnRHR-1 (rs3756159) SNP among women with serum AMH < 1.2 ng/mL in varied age groups.
Table 5.
The frequencies of GnRHR-1 (rs3756159) SNP among women with serum AMH < 1.2 ng/mL in varied age groups.
| GnRHR-1 (rs3756159) | Age < 35 Years (n = 86) | Age ≥ 35 Years (n = 183) | p Value 1 | ||
|---|---|---|---|---|---|
| Genotype | n | % | n | % | |
| CC | 34/86 | 39.5 | 44/183 | 24.0 | Reference |
| CT | 32/86 | 37.2 | 94/183 | 51.4 | 0.0071 |
| TT | 20/86 | 23.3 | 45/183 | 24.6 | 0.1166 |
| Recessive | |||||
| CC | 34/86 | 39.5 | 34/183 | 24.0 | Reference |
| CT/TT | 52/86 | 60.5 | 139/183 | 76.0 | 0.0091 |
| Allele | |||||
| C | 100/172 | 58.1 | 182/366 | 49.7 | Reference |
| T | 72/172 | 41.9 | 184/366 | 50.3 | 0.0732 |
1 by Chi-square test.
Table 6.
The demographic and ovarian stimulation characteristics of infertile woman in GnRHR (rs3756159) SNP with CC vs. CT/TT genotype. The data are presented with median (25% to 75%).
Table 6.
The demographic and ovarian stimulation characteristics of infertile woman in GnRHR (rs3756159) SNP with CC vs. CT/TT genotype. The data are presented with median (25% to 75%).
| Characteristics of Patients | GnRHR rs3756159 CC n = 78 | GnRHR rs3756159 CT/TT n = 191 | p Value |
|---|---|---|---|
| Woman age (years) | 36.0 (34.0 to 41.0) | 38.0 (35.0 to 41.0) | 0.0513 |
| Duration of infertility (years) | 3.0 (2.0 to 4.0) | 3.0 (1.5 to 5.0) | 0.5970 |
| Baseline AMH (ng/mL) | 0.60 (0.43 to 0.94) | 0.60 (0.28 to 0.90) | 0.2619 |
| Baseline FSH (IU/L) | 7.60 (4.76 to 9.50) | 7.40 (5.35 to 10.38) | 0.6122 |
| Baseline LH (IU/L) | 3.60 (2.45 to 5.40) | 4.40 (2.91 to 6.48) | 0.0308 |
| Baseline E2 (ng/mL) | 37.0 (25.0 to 59.0) | 37.0 (22.0 to 66.5) | 0.8942 |
| E2 on Day of trigger (ng/mL) | 775.5 (485.0 to 1267.0) | 823.0 (524.8 to 1208.0) | 0.4533 |
| P4 on Day of trigger (pg/mL) | 0.66 (0.37 to 0.90) | 0.66 (0.46 to 1.02) | 0.3235 |
| Day of stimulation (days) | 14 (13 to 15) | 14 (13 to 15) | 0.8692 |
| Number of retrieved oocytes | 4 (3 to 7) | 4 (3 to 6) | 0.4028 |
| Number of mature oocytes | 3 (2 to 6) | 3 (2 to 5) | 0.2512 |
| Number of Day3 embryos | 3 (2 to 5) | 3 (2 to 5) | 0.3711 |
| Day3 good embryo rate (%) | 70.8 (50.0 to 100.0) | 66.7 (50.0 to 100.0) | 0.4837 |
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Weng, S.-L.; Tzeng, S.-L.; Lee, C.-I.; Liu, C.-H.; Huang, C.-C.; Yang, S.-F.; Lee, M.-S.; Lee, T.-H. Association between GnRH Receptor Polymorphisms and Luteinizing Hormone Levels for Low Ovarian Reserve Infertile Women. Int. J. Environ. Res. Public Health 2021, 18, 7006. https://doi.org/10.3390/ijerph18137006
AMA Style
Weng S-L, Tzeng S-L, Lee C-I, Liu C-H, Huang C-C, Yang S-F, Lee M-S, Lee T-H. Association between GnRH Receptor Polymorphisms and Luteinizing Hormone Levels for Low Ovarian Reserve Infertile Women. International Journal of Environmental Research and Public Health. 2021; 18(13):7006. https://doi.org/10.3390/ijerph18137006
Chicago/Turabian StyleWeng, Shun-Long, Shu-Ling Tzeng, Chun-I Lee, Chung-Hsien Liu, Chun-Chia Huang, Shun-Fa Yang, Maw-Sheng Lee, and Tsung-Hsien Lee. 2021. "Association between GnRH Receptor Polymorphisms and Luteinizing Hormone Levels for Low Ovarian Reserve Infertile Women" International Journal of Environmental Research and Public Health 18, no. 13: 7006. https://doi.org/10.3390/ijerph18137006
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