Keywords
amphiregulin - follicular fluid - gene expression - mural granulosa cells - embryo
quality
Schlüsselwörter
Amphiregulin - Follikelflüssigkeit - Genexpression - murale Granulosazellen - Embryoqualität
Introduction
In the rapidly advancing field of reproductive medicine, identifying and transferring
the most viable embryo is a key goal, but the challenge of finding an optimal selection
method remains. Although there are well-designed and published algorithms for the
selection of embryos based on morphologic parameters [1]
[2], their use is not possible in countries such as Germany due to the German Embryo
Protection Act (EPA). Additionally, according to the EPA, in Germany the selection
of embryos with the highest potential for successful implantation must be made at
the pronucleus stage [3]. Defining possible parameters that might usefully serve as non-invasive biomarkers
for intracytoplasmic sperm injection (ICSI) outcomes is therefore crucial.
Many reports published over the past years on the predictive value of follicular fluid
(FF) biomarkers are still disputed. In addition to regular reproductive hormones which
have been the focus of research for over a decade, members of the epidermal-like growth
factor (EGF) family have increasingly become an object of interest as possible mediators
of crucial follicular processes [4]
[5]. It has been demonstrated that the epidermal growth factor receptor (EGFR) and its
ligands (epidermal growth factor [EGF], amphiregulin [AREG], betacellulin [BTC], epiregulin
[EREG]) influence numerous essential reproductive functions such as follicular development
and oocyte maturation processes [6]
[7].
The production of AREG, EREG, and BTC is an essential component of the paracrine function
of luteinizing hormone (LH) ovulatory signaling. These three proteins mediate a large
network of gene activation in mural granulosa cells (MGC) and cumulus oocyte complex
(COC), with AREG serving as a critical intermediary between those cells following
the mid-cycle LH surge [5]. Therefore, AREG, EREG, and BTC are not observable in FF before the LH surge but
rapidly increase to maximum levels before oocyte germinal vesicle breakdown, and decrease
immediately thereafter [8]. Following human chorionic gonadotropin (hCG) administration, AREG can be found
in FF whereas, even though BTC and EREG can potentially be up-regulated by hCG, their
protein levels in human FF are minimal. LH can also stimulate MGCs to secrete AREG,
which activates EGFR signaling
in cumulus cells and regulates processes such as oocyte maturation, cumulus development,
and ovulation [9].
According to Zamah et al., AREG is the most significant EGFR ligand in human FF and
might be used as a predictor of follicle growth, which could be important for in vitro
fertilization (IVF) patients [10]. Furthermore, Inoue et al. (2009) indicated that the amphiregulin concentrations
in FF affected oocyte quality and pregnancy outcomes [11].
The published data on AREG mRNA expression and infertility is still limited. Although
some studies have pointed to a significant correlation between LH-induced AREG mRNA
expression in human granulosa cells and various IVF parameters, such as the number
of retrieved oocytes and embryo quality [12], the signaling pathway of the LH receptor involved in regulating amphiregulin expression
has not yet been completely described [13].
The use of specific biomarkers and carrying out necessary changes to the EPA has been
a topic of constant discussion since the number of ICSI/IVF cycles in Germany increased
significantly [14]. Based on the aforementioned facts and due to the limitations of studies on IVF
patients [10]
[11] in which pooled follicular samples were used, the main aim of this study was to
define the possible impact of amphiregulin on oocyte maturation, fertilization rate,
and embryo quality. In addition, a special focus of the research was to define whether
there is a difference in amphiregulin mRNA expression based on oocyte maturity.
Materials and Methods
Ethical approval
Ethical approval for the study was obtained from the local ethics committee of the
Medical Association of Saarland (reference number: 146/19). Each study participant
provided written informed consent.
Participants
Thirty-three women undergoing ICSI were recruited at the Fertility Center of the University
Clinic of Saarland in Homburg, Germany, between May 2021 and May 2022. Patient ages
ranged between 23 and 40 years. Patients were recruited according to the following
criteria: age between 18 and 40; inability to achieve natural pregnancy over 12 months;
normal uterus and fallopian tubes; and normal menstrual cycle. Specific exclusion
criteria were: primary ovarian failure; two episodes of poor ovarian response (POR)
after maximum stimulation; history or presence of tumors; the presence of an ovarian
cyst > 25 mm; use of testicular or epididymal sperm; cryptozoospermia or strict teratospermia
(< 2% of normal sperm morphology).
Stimulation protocol
Twenty patients of the study group underwent controlled ovarian stimulation with the
antagonist GnRH protocol, where the starting doses of recombinant follicle-stimulating
hormone (rFSH) (Gonal-F; Merck Europe, Darmstadt, Germany) were based on serum AMH
levels, antral follicle counts, or previous responses to ovarian stimulation. Subsequent
doses were adjusted based on monitoring of ovarian responses using serial ultrasound
and serum estradiol measurement. A different type of stimulation protocol was used
for 13 patients aged more than 35 years or with AMH levels lower than 1.0 ng/ml. Ovarian
stimulation was initiated on the second day of the menstrual cycle by administering
combined recombinant follicle-stimulating hormone (rFSH) and recombinant luteinizing
hormone (rLH) (Pergoveris, Merck Europe, Darmstadt, Germany). From the fifth day of
stimulation therapy, a daily dose of 0.25 mg GnRH antagonist (Cetrotide; Merck Europe,
Darmstadt, Germany) was administered. In each
case, a human chorionic gonadotropin (Ovitrelle; Merck Europe, Darmstadt, Germany)
injection was used to trigger final oocyte maturation, and ultrasound-guided ovum
retrieval was performed approximately 36 h later.
Follicular fluid aspiration and mural granulosa cell isolation
Oocyte retrieval was performed transvaginally at 34 to 36 hours after hCG administration.
The FF contained in each follicle was collected independently. For each patient, between
one and five follicles were aspirated individually. Due to the possible risk of bleeding
and the prolonged time required for the procedure, a maximum of 5 follicles was retrieved
by individual aspiration, even in patients with more than 5 follicles.
In the time following COC harvesting, FF was replaced using a sterile spinal needle
and syringe from the dish to the sterile tube (Vitrolife, Sweden) and centrifuged
at 2000 rpm for 5 minutes to isolate mural granulosa cells. The supernatant was stored
at −80 °C in CryoTube vials (Nunc, Denmark) in aliquots until assayed.
Subsequently, 2 ml of phosphate buffer saline (PBS) were added to the pellet, and
the diluted solution was slowly layered using a 40:80% PureSperm (Sigma Aldrich) density
gradient and centrifuged at 2500 rpm for 30 min. After centrifugation, the middle
layer was collected, resuspended in 2 ml of PBS, and washed two times by centrifugation
for 10 minutes at 3000 rpm. The supernatant was discarded and the pellet was resuspended
with 200 μL of RNALater Stabilization Reagent (Qiagen, Germany) and cryostored at
−80 °C until RNA isolation.
ICSI, embryo culture, and embryo assessment
Each COC was denuded separately and the maturation status was determined as mature
oocyte (MII), immature oocyte (MI), germinal vesicle (GV), or empty zona pellucida.
Oocytes (M II and MI) were fertilized using conventional ICSI procedures and placed
immediately after injection in the sequential culture medium G-1 Plus (Vitrolife,
Goteborg, Sweden) and incubated at 37 °C, with 18% O2, and 6% CO2. The oocytes were examined for fertilization on the following day within 18 hours
after the injection, and only normally fertilized oocytes (those with two pronuclei)
were cultivated further.
On day 2 (44–48 h after injection) and day 3 (68–72 h after injection), the embryos
were evaluated based on the following characteristics:
-
Number of blastomeres
-
The degree of fragmentation: 0 = no fragmentation; 1 = < 10% fragmentation; 2 = 11–25%
fragmentation; 3 = 26–50% fragmentation and 4 = > 50% fragmentation
-
The size of the blastomeres: 0 = equally sized blastomeres; 1 = slightly unequal blastomeres
(25–50% size difference); 2 = unequal blastomeres (> 50% size difference) [15].
A good-quality embryo (GQE) was defined on day 2 as a 4-cell stage embryo with less
than 25% fragmentation and with equally or slightly unequally sized blastomeres. On
day 3, a GQE was defined as a 7–9 cell stage embryo with less than 25% fragmentation
and with equally or slightly unequally sized blastomeres. Embryo transfer was performed
on day 2 or day 3, depending on the patient’s age and the embryo quality.
Enzyme-linked immunosorbent assay (ELISA)
Quantitative determination of AREG concentrations in FF was done with ELISA according
to the instructions for Human Amphiregulin Quantikine Kit (R&D Systems Inc., Minneapolis,
MN, USA). All samples were analyzed in duplicate, and all reagents were prepared according
to the manufacturer’s instructions. Amphiregulin concentrations (pg/ml) were converted
and presented as ng/ml.
Since production of AREG is an essential component of the paracrine function of the
LH ovulatory signal, LH concentrations were also determined. The automated Cobas 8000
analyzer (Module e801; Roche Diagnostics, Germany) and Elecsys Kits (Roche Diagnostics)
were used to measure the concentration of LH in FF.
Gene expression of amphiregulin (AREG) and luteinizing hormone/chorionic gonadotropin receptor (LHCGR) in mural granulosa cells
RNA isolation
Total RNA extraction of individual MGCs was carried out using the High Pure RNA Isolation
Kit (Roche Applied Science, Mannheim, Germany), and all reagents were prepared according
to the manufacturer’s instructions. RNA samples were stored at −80 °C until reverse
transcription of complementary DNA (cDNA).
Reverse transcription and quantitative real-time PCR
From each sample, cDNA was synthesized using the High Capacity RNA-to-cDNA Kit (4387406;
Applied Biosystems, CA, USA). Reverse transcription reactions were performed with
the Bio-Rad S1000 (Bio-Rad, USA). Samples were stored at −20 °C until a real-time
quantitative polymerase chain reaction (RT-qPCR) was carried out.
Expression of AREG and LHCGR was analyzed with the StepOnePlus Real-Time PCR System (Applied Biosystems, CA, USA)
using TaqMan Fast Advanced Master Mix (Applied Biosystems) and the TaqMan gene expression
assays for AREG (Hs00950669_m1) and LHCGR (Hs00174885_m1).
All listed components were pipetted by the liquid handling robot QIAgility (Qiagen,
Germany) into a 96-well plate (MicroAmp, Applied Biosystems) and subsequently loaded
into the StepOnePlus. Each sample was analyzed in triplicate, with no template control
(NTC) included in each run.
The samples were normalized with the actin-beta reference gene [ACTB] (Hs99999903_m1) using the relative quantification 2−ΔΔCt method where the mean value of mRNA transcripts from each probe is set as one for
each gene [16].
Statistical analysis
All variables were analyzed using IBM SPSS version 27 (IBM Corp., Armonk, NY, USA).
Mann-Whitney U-test was used to compare the medians of the two group variables. Univariate
logistic regression analysis was used to detect a correlation between the concentrations
of proteins and gene expression levels, based on the number of mature oocytes, fertilization
rate, and the percentage of good-quality embryos. Receiver operating characteristic
(ROC) analysis was used to investigate the diagnostic performance of the parameters
using area under the curve (AUC). The fold change was calculated using the equation
2−
ΔΔ
C. Differences with p ≤ 0.05 were considered statistically significant.
Results
Clinical characteristics of participants
A total of 108 oocytes from the 33 patients were included in the study. Details on
the case series are given in [Fig. 1]. For the study, proposed oocytes were divided into groups based on maturity and
fertilization, while embryos were divided according to quality.
Fig. 1
Details of the case series (fertilization rate and embryo quality). 2PN = fertilized
oocyte; GQE = good quality embryo; GV = germinal vesicle; MI = immature oocytes; MII
= mature oocytes; PQE = poor quality embryo.
Patient age and stimulation protocol
The results obtained in the present study did not show any significant differences
between AREG and LH concentrations in FF based on the stimulation protocol or patient
age. Further evaluation based on different groups could be carried out because the
obtained results were not biased by age or stimulation protocol.
Impact of AREG and LH concentrations on oocyte maturation
Out of the total number of retrieved oocytes (n = 108), 84 (77.77%) were mature MII
oocytes, nine (8.33%) were immature MI, five (4.62%) cells were at the GV stage, and
10 (9.25%) cells had degenerated. A comparative analysis of protein concentrations
within the FF was done and the results indicated that the concentrations of AREG and
LH differed significantly between the mature and immature oocyte groups ([Table 1]). Moreover, the concentrations of both AREG and LH were elevated in the mature oocyte
group.
Table 1
Comparison of protein concentrations in FF between mature and immature oocyte groups
(n = oocyte number; p ≤ 0.05 was considered statistically significant).
|
Parameter
|
Mature oocyte (n = 84)
|
Immature oocyte (n = 24)
|
p value
|
|
|
Median
|
Minimum
|
Maximum
|
Median
|
Minimum
|
Maximum
|
|
|
AREG (ng/ml)
|
121.99
|
27.69
|
227.54
|
81.31
|
25.08
|
236.83
|
0.004
|
|
LH (mIU/ml)
|
1.21
|
0.10
|
9.97
|
0.88
|
0.10
|
7.72
|
0.046
|
Univariate logistic regression analysis was performed to evaluate the impact of AREG
and LH on oocyte maturation. The results demonstrated that AREG (OR: 1.01; Cl: 1.002–1.025;
p = 0.020) as well as LH (OR: 0.762; Cl: 0.600–0.967; p = 0.026) concentrations in
FF could significantly affect oocyte maturation. Predictive strength was quantified
using the area under the curve (AUC) of the receiver operating characteristic (ROC),
where the area under the ROC curve for AREG was AUC = 0.691 and for LH was AUC = 0.633
([Fig. 2]).
Fig. 2
ROC curves of the predictive performance of AREG and LH concentrations for oocyte
maturation. The AUC indicates moderate predictive values for both factors.
Since the univariate logistic regression analysis confirmed statistical significance,
AREG and LH were included in a multiple regression analysis. The data confirmed the
significant impact of both studied proteins on oocyte maturation ([Table 2]).
Table 2
Multiple regression analysis: the impact of AREG and LH concentrations in FF on oocyte
maturation.
|
Model
|
B
|
Std. Error
|
Beta
|
T
|
p value
|
|
(Constant)
|
0.612
|
0.108
|
|
5.645
|
0.000
|
|
AREG (ng/ml)
|
0.002
|
0.001
|
0.246
|
2.652
|
0.009
|
|
LH (mIU/ml)
|
0.058
|
0.022
|
0.243
|
2.622
|
0.010
|
Correlation between gene expression and oocyte maturation
The relative concentrations of mRNA (mean ΔCt values) for the AREG differed significantly differently between the mature and immature oocyte groups
(p = 0.031) ([Table 3]).
Table 3
Comparison of AREG and LHCGR gene expression levels (ΔCt) in mature and immature oocyte
groups.
|
Parameter
|
Mature oocyte (n = 84)
|
Immature oocyte (n = 24)
|
p value
|
|
|
Median
|
Minimum
|
Maximum
|
Median
|
Minimum
|
Maximum
|
|
|
ΔCt AREG
|
3.07
|
0.33
|
5.87
|
3.37
|
2.24
|
6.10
|
0.031
|
|
ΔCt LHCGR
|
9.94
|
5.15
|
13.01
|
10.21
|
8.01
|
14.41
|
0.39
|
In addition, univariate logistic regression analysis confirmed that AREG expression correlated with oocyte maturity (OR: 0.49; CI: 0.26–0.91; p = 0.024).
Since the correlation between ΔCt and the level of gene expression is inverse, higher
ΔCt values indicate a decrease in gene expression. Therefore, [Table 4] shows that gene expression of AREG was downregulated in the immature oocyte group.
Table 4
Comparative analysis of AREG expression levels and fold changes in mature and immature
oocyte groups.
|
Genes
|
Mean ΔCt
Mature oocyte
|
Mean ΔCt
Immature oocyte
|
ΔΔCt
|
Fold change
|
Log2Fold change
|
Regulation
|
|
AREG
|
3.12
|
3.58
|
0.46
|
0.73
|
−0.46
|
down
|
Impact of AREG and LH concentrations on fertilization rate
Out of the 108 oocytes included in the study, ICSI was carried out with 93 oocytes
(84 MII and 9 MI). The fertilization rate was 67.74 % (n = 63), and 61 oocytes were
correctly fertilized (2 PN). Of the nine MI oocytes, two were correctly fertilized.
However, due to possible bias in the result, MI oocytes were excluded from further
statistical analysis. When protein concentrations in FF between fertilized and unfertilized
oocytes were compared, the results indicated that AREG and LH differed significantly
between the fertilized and unfertilized oocyte groups ([Table 5]). Moreover, the AREG and LH concentrations were significantly elevated in the fertilized
oocyte group.
Table 5
Comparison of protein concentrations in FF between the fertilized and unfertilized
oocyte groups (n = oocyte number; p ≤ 0.05 was considered statistically significant).
|
Parameter
|
Fertilized oocyte (n = 59)
|
Unfertilized oocyte (n = 23)
|
p value
|
|
|
Median
|
Minimum
|
Maximum
|
Median
|
Minimum
|
Maximum
|
|
|
AREG (ng/ml)
|
126.98
|
71.63
|
227.54
|
89.05
|
43.19
|
170.96
|
0.001
|
|
LH (mIU/ml)
|
0.93
|
0.15
|
5.77
|
0.64
|
0.16
|
3.45
|
0.025
|
Univariate logistic regression analysis was additionally performed to evaluate the
impact of AREG and LH on the fertilization rate. The results demonstrated that AREG
concentration could significantly predict oocyte fertilization (OR: 1.02; CI: 1.00–1.03;
p < 0.003). The predictive strength was assessed by quantifying the area under the
curve of the receiver operating characteristic. In this case, the area under the ROC
curve was determined to be AUC = 0.735 ([Fig. 3]). In contrast, according to the results of the univariate logistic regression analysis,
LH concentrations did not significantly affect oocyte fertilization (p = 0.123).
Fig. 3
The ROC curve of the predictive performance of AREG concentrations for oocyte fertilization.
The AUC indicates a fair level of accuracy in distinguishing between fertilized and
unfertilized oocytes based on AREG concentration.
Correlation between gene expression and oocyte fertilization
Despite the fact that protein concentrations in FF differed between fertilized and
unfertilized oocyte groups, gene expression did not differ significantly between the
groups ([Table 6]).
Table 6
Comparison of AREG and LHCGR gene expression levels (ΔCt) in fertilized and unfertilized
oocyte groups.
|
Parameter
|
Fertilized oocyte (n = 59)
|
Unfertilized oocyte (n = 23)
|
p value
|
|
|
Median
|
Minimum
|
Maximum
|
Median
|
Minimum
|
Maximum
|
|
|
ΔCt AREG
|
3.09
|
0.33
|
5.36
|
3.22
|
1.69
|
6.10
|
0.342
|
|
ΔCt LHCGR
|
10.23
|
5.15
|
13.01
|
9.71
|
7.27
|
12.02
|
0.278
|
Impact of AREG and LH concentrations on embryo quality
Because of the Embryo Protection Act, 13 zygotes of the 61 fertilized oocytes were
frozen, while 48 were cultivated. Thirty-four embryos (70.8%) were good quality (GQE)
and 14 (29.2%) were poor quality (PQE).
A comparison of protein concentrations in FF between GQE and PQE showed that AREG
and LH concentrations were elevated in the good-quality embryo group, and the difference
was statistically significant ([Table 7]).
Table 7
Comparison of protein concentrations in FF between Good Quality Embryo and Poor Quality
Embryo groups (n = oocyte number; p ≤ 0.05 was considered statistically significant).
|
Parameter
|
Good Quality Embryo group (n = 34)
|
Poor Quality Embryo group (n = 14)
|
p value
|
|
|
Median
|
Minimum
|
Maximum
|
Median
|
Minimum
|
Maximum
|
|
|
AREG (ng/ml)
|
126.44
|
71.63
|
227.54
|
95.28
|
43.19
|
166.50
|
0.016
|
|
LH (mIU/ml)
|
1.15
|
0.37
|
5.77
|
0.64
|
0.46
|
1.39
|
0.017
|
Univariate logistic regression analysis was performed to determine the impact of AREG
and LH concentrations on embryo quality. The results demonstrated that AREG concentrations
could significantly affect embryo quality (OR: 1.02, Cl: 1.00–1.04; p = 0.003). In
this case, the area under the ROC curve was determined to be AUC = 0.723 ([Fig. 4]). In contrast, univariate logistic regression analysis showed that LH concentrations
did not significantly affect embryo quality (p = 0.072).
Fig. 4
The ROC curve of the predictive performance of AREG concentrations for embryo quality.
The AUC indicates a good level of accuracy in distinguishing between good and low-quality
embryos based on AREG concentrations.
Correlation between gene expression and embryo quality
Differences in the relative expression level of studied genes (AREG, LHCGR) did not reach statistical significance when GQE and PQE were compared ([Table 8]).
Table 8
Comparison of AREG and LHCGR gene expression levels (ΔCt) in Good Quality Embryo and
Poor Quality Embryo groups.
|
Parameter
|
Good Embryo Quality group (n = 34)
|
Poor Embryo Quality group (n = 14)
|
p value
|
|
|
Median
|
Minimum
|
Maximum
|
Median
|
Minimum
|
Maximum
|
|
|
ΔCt AREG
|
3.32
|
0.33
|
4.36
|
3.28
|
2.49
|
5.36
|
0.650
|
|
ΔCt LHCGR
|
10.27
|
5.15
|
11.75
|
9.81
|
8.57
|
12.85
|
0.586
|
Discussion
Recognizing the relationship between the possible causes of infertility such as factors
that regulate the expression of genes involved in fertility, inherited factors, hormonal
production, and disordered epigenetic mechanisms may lead to a clear understanding
of unknown causes of infertility. As the most important outcomes of ICSI are the fertilization
rate and embryo quality, identifying possible biomarkers that affect those parameters
is still one of the main challenges in reproductive medicine.
Unlike many other publications, single/individual aspiration of follicles was done
in the present study, which enabled a 1 : 1 correlation with retrieved oocytes. Moreover,
the oocytes retrieved after fertilization were followed and embryo quality was evaluated.
Because of the above-described study design, the results obtained are especially useful
and applicable in Germany due to the Embryo Protection Act.
Oocyte maturation and protein concentrations
Female fertility is highly dependent on normal oocyte development, and oocyte quality
is a significant rate-limiting factor in ART techniques such as ICSI. Considering
the EGF signaling network’s essential function in the ovulatory cascade, it can also
be expected to be crucial for oocyte developmental competence [5].
The results in our study indicate that AREG and LH concentrations in FF differ significantly
between immature and mature oocytes, and were higher in the mature group. Differences
in AREG concentration were in accordance with previously published data [10]
[17]. The impact of AREG on the oocyte maturation process was confirmed by Ben-Ami et
al. (2011), whose data indicated that the incubation of human GV-stage oocytes in
a standard medium supplemented with AREG resulted in a significantly higher rate of
MII oocyte development [18].
It is well known that the oocyte maturation process is initiated when an LH signal
is generated in the ovarian follicle. The results of our study confirm that the LH
concentration is lower in the follicles where immature oocytes are developed, which
is consistent with many published papers [19]
[20]
[21]. The impact of LH on oocyte maturation was confirmed in our study as well as in
many previous studies: the presence of LH in FF is crucial for oocyte development
[10]
[20]
[22].
Oocyte maturation and expression of studied genes
Some studies have indicated that AREG expression may play the most important role in oocyte maturation [23]
[24]
[25]. According to Huang et al., AREG mRNA induction in human granulosa cells (GCs) or COCs is connected to oocyte meiotic
development, the number of retrieved oocytes, as well as overall ICSI outcomes [12].
The results of our study are in accordance with the findings of other studies [17]
[26] that demonstrated a significant correlation between the expression of AREG and oocyte maturation. Ben-Ami et al. (2006) reported that human primary GCs display
increased expression of AREG 2–8 h after LH stimulation [23].
LHCGR is exclusively expressed in the MGCs of the ovarian follicle. Additionally, LHCGR expression in humans is highest in MGCs in preovulatory follicles [27]. However, LHCGR expression is suppressed by an LH surge, and the LH surge downregulates LHCGR expression in preovulatory follicles in women [28]
[29].
In the present study, the expression of LHCGR was higher in the group of mature oocytes compared to immature oocytes, which is
in line with the findings of Maman et al. [30]. However, the difference between the groups was not significant. Huang et al. reported
that LHCGR expression in MGCs did not differ or correlate with IVF outcomes [12].
Fertilization rate and protein concentrations
The main factor behind oocyte quality and oocyte maturation after ICSI is successful
fertilization [31]. The results of our study indicate that oocytes obtained from follicles with a high
concentration of AREG have a higher fertilization rate, which is in accordance with
the literature [12]. Contrary to our results, Inoue et al. reported a non-significant correlation between
AREG levels and fertilization rate [10]. However, in the study by Inoue et al., FF samples were pooled whereas our study
allowed correlations with individual oocyte developmental outcomes. Due to the limited
number of publications available, making a comparison with our results was difficult.
However, since many studies as well as our results confirm the impact of AREG on oocyte
nuclear
maturity, we hypothesize that AREG affects oocyte quality, which may be the main reason
for the correlation between AREG and fertilization rate.
The results indicate that LH concentrations in FF differ significantly between fertilized
and unfertilized oocytes. The impact of LH on oocytes and fertilization has been researched
for decades. Our results are in accordance with many published studies [20]
[32].
Fertilization and gene expression
To date, numerous studies have been performed to identify gene markers, profile granulosa
or cumulus gene expression, and predict oocyte or embryo competence [33]
[34]
[35]. In the present study, the expression of the studied genes did not statistically
differ between fertilized and unfertilized oocytes. The results obtained for the expression
of AREG and LHCGR contrasted with the results obtained by Huang et al., who reported that AREG expression levels correlated positively with the number of 2PN while LHCGR correlated negatively with fertilization [12]. One of the possible reasons for
the discrepancy might be differing patient characteristics as well as ovarian responses.
Moreover, the time-dependent change of AREG expression after hCG stimulation in MGCs has been confirmed in previous studies [36]
[37]. Therefore, the variance in detection times might also account for the discrepancy.
Embryo quality and protein concentrations
The selection of high-quality embryos continues to be a major challenge for assisted
reproductive technology. Globally, there is a lack of a unique evidence-based and
globally accepted standards for evaluating embryos and identifying an embryo with
the highest implantation potential.
In this study, AREG differed significantly between good and poor-quality embryo groups:
the oocyte that created a good-quality embryo came from a follicle with a high AREG
concentration. Our results are in contrast with data published by Inoue et al., who
reported that AREG concentrations did not differ statistically between good and poor
embryos [11]. Due to the limited number of studies, we can only compare our results with those
of Inoue et al. However, the study design used by Inoue et al. involved pooled FF
samples which prevents a direct correlation with embryo quality outcomes.
In addition to AREG, the concentrations of LH differed statistically between good
and poor-quality embryo groups, which is in line with published data [32]
[38]
[39]. Although the biological role of LH has been confirmed in many studies, there are
only a few studies on IVF patients and the concentration of LH in FF [40]
[41]. Moreover, some recent studies have reported that recombinant LH supplementation
during GnRH antagonist cycles may improve embryo quality as well as the live birth
rate [42]
[43]. The obtained results are very promising and could easily be implemented in everyday
clinical practice as well as being very useful for embryo selection in specific countries.
Embryo quality and gene expression
Although the concentration of proteins differed between good and poor embryo quality
groups, gene expression did not differ significantly between these groups. To the
best of our knowledge, little information is available on AREG and LHCGR gene expression and in vitro embryo development. The results obtained in the present study for AREG expression are in line with previously published data (Feuerstein et al. [26]). Conversely, our findings contrast with data published by Huang et al., who reported
that AREG expression was positively correlated with embryo quality [12]. Additionally, the same group of authors reported that LHCGR expression did not differ according to embryo
quality, which is consistent with our results.
Study limitations
This study is limited by its exclusive focus on ICSI couples and its exclusion of
IVF patients, which may affect the applicability of the findings. The study design
also prevented correlation analysis between total oocyte yield and amphiregulin concentration,
potentially limiting insights into oocyte quality across the entire yield. Furthermore,
the study did not examine the relationship between amphiregulin concentration and
blastocyst quality or transfer outcomes, which could be explored in future studies.
Conclusion
The results of the current study indicate that AREG concentrations in FF affect oocyte
maturation, the fertilization rate, and, most importantly, embryo quality.
The concentration of LH in FF affects oocyte maturation and differs significantly
between fertilized and unfertilized oocyte groups as well as between good and poor
embryo quality groups.
The gene expression of the studied genes AREG and LHCGR indicates that only the AREG expression significantly affects oocyte maturation, with AREG expression being downregulated in the immature oocyte group. LHCGR did not differ between groups and did not affect maturation, fertilization, or embryo
quality.
In summary, given the complexity of the numerous independent processes involved in
oocyte development, a single biomarker is unlikely to predict the outcome of ICSI.
However, the obtained results, together with previous studies, are very important
for the future development of infertility treatment, especially in Germany due to
its EPA. AREG may offer prognostic information which could aid the selection of the
most viable embryos. Moreover, the availability and ease of analysis allow for the
results obtained in the present study to be easily implemented in everyday IVF procedures
and improve ICSI outcomes.
