Key words
thin endometrium - IVF - LIF - VEGF - β
3 integrin - angiogenesis
Schlüsselwörter
dünne Gebärmutterschleimhaut - IVF - LIF - VEGF - β
3-Integrin - Angiogenese
Introduction
The human endometrium is an important and specialized structure in the reproductive
system. The main purpose of this type of tissue is to allow the embryo to implant,
through a complex process of embryomaternal cross-talk. Over the last few decades,
investigations of endometrial tissue during the implantation window have been carried
out in order to identify the key receptors, cytokines, immunocompetent cells, and
protein patterns involved in the implantation process. Marker molecules for endometrial
receptivity are thought to be involved in endometrial function and particularly in
the regulation of implantation. These markers include receptors such as αvβ3 integrin [1], [2] and the leptin receptor (OB-Rb) [3], [4], and cytokines such as leukemia inhibitory factor (LIF) [2], [5] and vascular endothelial growth factor (VEGF) [6], [7], [8].
The relevance of these molecules for the implantation process has been investigated
in animal models. In mice, it has been shown that LIF and OB-Rb are key molecules
for fertility. An absence of LIF or OB-Rb leads to sterility in female mice [9], [10].
αvβ3 integrin is expressed in murine endometrium and blastocysts at the time of implantation.
Carrying out a functional blockade of this integrin using specific neutralizing monoclonal
antibodies against αv or β3 integrin subunits, Arg-Gly-Asp (RGD)-containing peptides, or the disintegrin echistatin
was found to reduce the number of implantation sites in mice in comparison with controls
receiving bovine serum albumin (BSA) [11]. An experimental mouse model of polycystic ovarian syndromes was found to have endometrium
with an altered expression pattern of integrins such as αv, α4, β1, and β3 integrin in comparison with normal mice [12].
LIF induces a complex pattern of changes in endometrial epithelium, regulating murine
embryo implantation by increasing expression of 256 genes during the first hour and
with altered expression of 3987 genes after 3 hours. A distribution of key genes from
10 pathways has been confirmed, including VEGF and integrin receptors [13]. Gp130, the activating subunit of signal transducer and activator of transcription
3 (STAT3) is shared by all members of the interleukin-6 (IL-6) receptor family. Disruption
of gp130 leads to a phenotype identical to the knockout for LIF [14].
Following the identification of marker molecules in the endometrium in fertile women
and demonstration of their relevance for pregnancy in mice, interest has arisen in
investigating their function in subfertile and infertile patients. A lack of endometrial
αvβ3 integrin expression is associated with a poor prognosis for in vitro fertilization
(IVF) [15]. It has been shown that women with stronger LIF and weak claudin-4 immunoreactivity
during the window of implantation are more likely to become pregnant in comparison
with women with lower levels of the protein – suggesting the importance of LIF in
IVF [16].
LIF and gp130 influence the endometrial surface and regulate implantation at the human
fetal-maternal interface [17]. DNA sequence changes have been found in the LIF genes of women with negative IVF outcome. LIF gene mutation may thus contribute to IVF failure [18].
Clinical observations have revealed an association with abnormally thin endometrium,
detected on ultrasound, in a subgroup of subfertile patients. This thin endometrium
is the only clinically apparent defect, and it may possibly suggest there is an endometrial
factor that leads to infertility. An endometrial thickness of less than 7 mm is associated
with a reduced pregnancy rate [19], [20], [21]. Several groups have reported a significantly higher average value for endometrial
thickness measurements in conception cycles in comparison with nonconception cycles
[22], [23]. Other investigators have compared endometrial volumes with implantation and pregnancy
rates. Patients with an endometrial volume < 2 mL were found to have significantly
lower (p < 0.05) pregnancy and implantation rates in comparison with patients who
had endometrial volumes of more than 2 mL. No pregnancies were achieved with an endometrial
volume < 1 mL [24]. It has been shown that abnormal endometrial biopsies are obtained more frequently
in infertile (43%) than in fertile women (9%), in spite of adequate progesterone levels
[25], [26], [27], [28]. The thickness and pattern (e.g., trilinear) of the endometrium independently affect
pregnancy outcomes. The combined endometrial thickness and pattern was not predictive
for the outcome of IVF when the endometrial thickness was < 7 mm or > 14 mm, while
a triple-line pattern with a moderate endometrial thickness appeared to be associated
with a good clinical outcome [29]. Priming of thin endometria with 150 IU human chorionic gonadotropin (hCG) during
the proliferative phase in estrogen-substituted cycles is a highly promising form
of treatment, as the thickness of the endometrium improves and receptivity also becomes
normalized [30]. There is a higher incidence of pregnancy in IVF patients who have a thick endometrium
≥ 10 mm. According to Rinaldi et al., a thin endometrium is a prognostic indicator
for female infertility in IVF patients [31]. Other research groups have not found that the endometrial thickness measured on
ultrasound has any influence on pregnancy rates [32], [33].
Taken together, these literature findings suggest that a thin and less developed endometrium
may be associated with a reduced pregnancy rate in women. In the present study, marker
molecules for endometrial receptivity that are involved in angiogenesis were therefore
investigated in this specific subgroup of subfertile patients.
Materials and Methods
Endometrial biopsies were obtained from 11 subfertile women (mean age 32.90 ± 3.03
years) in the late proliferative and mid-secretory phase of one cycle, without any
hormonal treatment. These patients, who had not achieved pregnancy within 1 year of
clinical investigation in an infertility center, were defined as subfertile. Their
clinical examinations had not revealed any pathological parameters, with the exception
of an endometrial thickness of less than 7 mm during several stimulated cycles. The
estradiol and progesterone values in peripheral blood in all of these patients had
been within the normal physiological range throughout the ovulatory cycles. These
patients represent a subgroup of individuals with idiopathic infertility, in whom
disturbed endometrial development is the only detectable abnormality. It was hypothesized
that they might have an endometrial factor leading to infertility.
36 endometrial biopsies of the late proliferative to the mid-secretory phase from
women with normal menstrual cycles and confirmed fertility (mean age 40.4 ± 4.7 years)
who were undergoing hysterectomy for benign uterine diseases were investigated and
used as positive controls. None of the women with confirmed fertility had received
any hormonal treatments during the previous 3 months.
The following parameters were taken into account for analyzing the menstrual phase
in endometrial biopsies from fertile patients (controls) and subfertile patients:
-
clinical reports;
-
histological phase [34]; and
-
assessment of serum hormone concentrations (progesterone, estradiol, luteinizing hormone,
and follicle-stimulating hormone) on the day of the biopsy procedure.
All of the biopsies from fertile and subfertile patients were investigated immunohistochemically
to detect progesterone receptors and estrogen receptors, as well as the proliferation
marker Ki-67. This combination of clinical, serological, and immunohistological parameters
provided optimal assessment of the phase of the endometrial cycle.
Approval for the study was obtained from the ethics committee in the Medical Faculty
of the University of Aachen.
Immunohistochemistry
Immunohistochemical analysis was carried out on paraffin sections (4 µm) using a streptavidin-biotin
peroxidase method, as described previously [3]. Endogenous peroxidase activity was blocked by incubation in 0.3% hydrogen peroxide
for 30 min. For the negative control, phosphate-buffered saline (PBS; Dulbecco) without
Ca2+ and Mg2+/1.5% bovine serum albumin (BSA) replaced the primary antibody. In addition, rabbit
immunoglobulin G (IgG; Dako, Hamburg, Germany), goat IgG (Dianova, Hamburg, Germany),
normal mouse IgG (Dianova, Hamburg, Germany), and mouse IgG 1 kappa (Dako, Hamburg,
Germany) were used as controls at the same concentration as the primary antibody.
All primary antibodies ([Table 1]) were applied overnight at 4 °C. A Histostain-SP Kit (Zymed Laboratories Inc.) was
used for monoclonal antibodies. Sections for polyclonal antibodies were incubated
for 10 min at room temperature with normal swine serum (Dako; dilution 1 : 20 in PBS/1.5%
BSA) prior to incubation with the first antibody. Subsequently, the sections were
incubated with a biotinylated second antibody (multi-link, swine, anti-goat, rabbit,
mouse; Dako) for 30 min at room temperature. The dilution for the second antibody
was 1 : 150 in PBS/1.5% BSA. Incubation with streptavidin peroxidase conjugate (Dako)
at a dilution of 1 : 333 in PBS/1.5% BSA followed for 10 min at room temperature.
After each incubation step, the tissues were washed three times with PBS. Visualization
of the specific antigen was achieved with peroxidase catalyzing the substrate and
converting the chromogen aminoethyl carbazole (AEC; Zymed Laboratories Inc., San Francisco,
CA, USA) into a red deposit.
Table 1 Antibodies used for immunohistochemistry.
|
Antibody
|
Antigen
|
Dilution
|
Source
|
|
ER, estrogen receptor; LIF, leukemia inhibitory factor; PR, progesterone receptor;
VEGF, vascular endothelial growth factor.
|
|
Monoclonal (mouse)
|
|
BTC41
|
β3 integrin
|
1 : 1000
|
TaKaRa/British Biotechnology
Biermann Diagnostica, Germany
|
|
PR-10A9
|
PR
|
1 : 50
|
Immunotech, Hamburg, Germany
|
|
ER-1D5
|
ER
|
1 : 50
|
Immunotech, Hamburg, Germany
|
|
MIB-1
|
Ki-67
|
1 : 60
|
Immunotech, Hamburg, Germany
|
|
Polyclonal antibodies (goat)
|
|
Anti-human LIF
|
Human LIF
|
1 : 100
|
R & D Systems/Biermann Diagnostica, Germany
|
|
VEGF (A20)
|
VEGF (121,165,189)
|
1 : 30
|
Santa Cruz Biotechnology, Heidelberg, Germany
|
Pretreatment for antigen retrieval was used for antibodies against Ki-67, estrogen
receptors, and progesterone receptors. The slides were heated in a sodium citrate
buffer (pH 6.4) by microwave (4 × 5 min, 600 W) after rehydration. The antibodies
against VEGF and β3 integrin were pretreated with trypsin (Dako) for 15 min at room temperature. The
antibody against LIF was used without any pretreatment of the tissue. The antibodies
used are listed in [Table 1].
Results
Histology
Histomorphological analysis of tissue from the subfertile patients showed endometrial
transformation from the proliferative phase to the secretory phase. Development of
the endometrial glands into the secretory phase was evident from comparison of the
first and second biopsies. The glandular epithelium lost signs of pseudostratification
and in three cases included a few glycogen vacuoles, indicating the influence of progesterone.
The second biopsies corresponded to the end of the early to mid-secretory phase (days
18 – 21).
Detection of steroid hormone receptors and proliferation markers
The pattern of hormone receptor expression and its down-regulation was similar to
the expression pattern in fertile patients. The proliferation marker Ki-67 was adequately
expressed in the glandular epithelium and the stromal fibroblasts in the first biopsies.
In the second biopsies, localized Ki-67 was only expressed in some stromal fibroblasts,
similar to the expression seen in the secretory endometrial tissues of fertile patients
([Fig. 1]).
Fig. 1 Endometrial biopsies from a subfertile patient taken during one menstrual cycle on
days 13 and 22. Immunohistochemical stains on paraffin-embedded tissue sections. The
scale bars in b (only for b) and h (for all other images) represent 100 µm. a Hematoxylin-stained biopsy from day 13, showing proliferating glandular epithelium
and stromal edema. b Hematoxylin-stained biopsy from day 22, showing transformed secretory glands. c Progesterone receptor (PR) on day 13, showing strongly positive-stained nuclei in
epithelial glands and stromal cells. d PR on day 22, showing negative glandular epithelium and scattered positive stromal
cells. e Estrogen receptor (ER) on day 13, showing strongly positive-stained nuclei in epithelial
glands and stromal cells. f ER on day 22, showing a few weakly positive nuclei in glandular epithelial cells
and stromal cells. g Ki-67 on day 13, showing positive-stained nuclei in glandular and stromal cells.
h Ki-67 on day 22, showing scattered positive-stained nuclei in stromal cells and negative
nuclei in glandular cells.
Detection of marker molecules
The glands in the first biopsies (from the late proliferative phase) were negative
for β3 integrin and LIF. The stromal fibroblasts showed only weakly positive localizations
for these two marker molecules. The glands in all of the second biopsies (from the
mid-secretory phase) were negative for β3 integrin, and two biopsies showed weakly atypical staining for LIF in some glands.
The immunohistochemical results for VEGF in the first and second biopsies from the
subfertile patients showed reduced or inadequate expression. In the second biopsies
from the mid-secretory phase, VEGF was not expressed in seven cases, but weak staining
in some glands was detected in four biopsies. Interestingly, typical staining for
VEGF was not observed in the glands from the first biopsies. VEGF detection would
have been expected in tissue from the proliferative phase, as reported previously
by our group in endometrium from fertile women with normal menstrual cycles [8]. The stromal cells were weakly positive for VEGF ([Fig. 2]).
Fig. 2 Comparison of endometrial biopsies from subfertile and fertile patients, taken during
the mid-secretory phase. Immunohistochemical stains on paraffin-embedded tissue sections.
The scale bar represents 100 µm. a β3 integrin: negative glands and a weakly positive stromal reaction in endometrial biopsies
from subfertile patients. b β3 integrin: positive-stained glands and a weakly positive stromal reaction in endometrial
biopsies from fertile patients. c Leukemia inhibitory factor (LIF): negative glands and a weakly positive stromal reaction
in endometrial biopsies from subfertile patients. d LIF: positive-stained glands and a weakly positive stromal reaction in endometrial
biopsies from fertile patients. e Vascular epithelial growth factor (VEGF): negative glands and weakly positive surface
epithelium, with some positive-stained stromal cells in endometrial biopsies from
subfertile patients. f VEGF: positive-stained glands and weakly positive stromal cells in endometrial biopsies
from fertile patients.
Discussion
In subfertile patients who have a thin endometrium (< 7 mm) throughout the menstrual
cycle, in the presence of normal steroid hormone receptor expression and regulation,
endometrial biopsies were found to lack several marker molecules that are considered
characteristic for endometrial receptivity. Histomorphological analysis showed that
the endometrial tissue in the samples was in the mid-secretory phase or approaching
the end of the early secretory phase. Surprisingly, it lacked or showed inadequate
and weak expression of the relevant markers.
As a possible limitation of our study no quantification of the results has been performed.
However, the lack of marker molecules in the subfertile patients was very obvious
and the pattern of hormone receptor expression and its down-regulation was completely
similar between fertile and subfertile women.
An earlier investigation carried out by our group on the expression of the leptin
receptor in endometrial tissue showed similar findings [3]. Biopsies taken during the proliferative phase were deficient for vascular endothelial
growth factor (VEGF) and leptin receptor, although these markers are expressed in
normal proliferative endometrium in fertile women. The endometrial maturation defect
apparently already starts in the proliferative phase and becomes clearly evident during
the secretory phase. There is evidence that a certain network of interactions exists
among the different marker molecules. The leptin receptor is able to influence the
expression of VEGF and vascular endothelial growth factor receptor (VEGF-R) [35], [36], [37], [38], [39], [40], β3 integrin [41], and leukemia inhibitory factor (LIF) [42]. LIF has a positive influence on VEGF [13], [43] and integrin expression [17], [44], [45]. VEGF in turn is able to influence integrin expression [46]. The integrin αvβ3 again is involved in the activation of VEGF-R2 after binding of the L1 cell adhesion
molecule (L1Ig6), a ligand of this integrin receptor [47] ([Fig. 3]) [13], [17], [36], [37], [38], [39], [40], [41], [42], [43], [44], [45], [46], [47], [48].
Fig. 3 Interactions among marker molecules that influence angiogenesis. The leptin receptor
influences vascular epithelial growth factor (VEGF) and vascular epithelial growth
factor receptor-1 (VEGF-R1) [36], [37], [38], [39], [40]; β3 integrin [41]; and leukemia inhibitory factor (LIF) [42]. LIF influences VEGF [13], [43] and integrin [17], [44], [45]. VEGF influences integrin [46], [48]. Integrin influences VEGF-R2 [47].
VEGF
The thin endometrium correlates with a lack of the molecules that are involved in
angiogenesis. VEGF was only detectable in a few endometrial glands during the secretory
phase in subfertile patients. However, the endometrium in patients with proven fertility
(the control group) showed strong regular staining of VEGF during this phase. The
lack of VEGF may possibly lead to inadequate blood vessel growth in patients with
thin endometrium. VEGF is able to up-regulate the expression of von Willebrand factor
(vWF) mRNA and protein in cultured endothelial cells [49], [50]. The number of vessels was not reduced, as revealed by detection of vessels with
vWF (data not shown), but their growth may be retarded, in turn inhibiting the transformation
process in the endometrium.
LIF
LIF plays a functional role in angiogenesis. In cardiac myocytes, LIF is able to activate
VEGF expression via signals through gp130/STAT3. Intravenous administration of LIF
has been shown to augment the expression of VEGF mRNA in murine heart tissue. Myocardial
tissue from transgenic mice overexpressing dominant-negative STAT3 showed reduced
expression of VEGF mRNA, which was not induced after LIF stimulation. Stimulation
of rat cardiac myocytes in a cell culture system with LIF resulted in a rapid increase
in VEGF mRNA and protein expression [43], [51]. LIF may also play a critical role in controlling angiogenesis in the placental
villi, since human fetal endothelial cells express leukemia inhibitory factor receptor
(LIF-R), and mice that lack a functional LIF receptor gene show altered vascular development
in the placenta [52]. Inhibition of LIF during mid-gestation impairs trophoblast invasion and spiral
artery remodeling during pregnancy in mice [53]. Blocking endogenous LIF during placental development in mice leads to abnormal
placentation and pregnancy loss [54]. There is thus abundant evidence that LIF may be involved in angiogenesis in the
endometrium and placenta. LIF may possibly also affect VEGF expression in the human
endometrium.
Evidence from animal studies [9] has shown that LIF is essential for blastocyst implantation. The absence of LIF
observed in glandular epithelial cells in endometrial biopsies obtained from subfertile
patients may also contribute to subfertility. Hambartsoumian [55] reported differences between fertile and infertile women in relation to LIF secretion
in endometrial explant cultures. In fertile women, endometrial LIF secretion was 2.2
times higher in the secretory phase than in the proliferative phase. Infertile women
were not found to have this elevation of LIF production during the secretory phase
[56]. Heterozygous LIF gene mutations have also been detected in infertile women (in three of 74 patients)
[57]. The authors considered that these mutations might be responsible for the reduced
LIF protein production described by Laird et al. [58] and Hambartsoumian [55]. A study including 25 women with unexplained infertility found that they had a significantly
reduced level of LIF mRNA. LIF was not detectable in 88% of the infertile women while
it was fairly detectable in 12% of them. Significantly fewer LIF and gp130 molecules
were found in uterine flushing in infertile women in comparison with normally fertile
women. Tawfeek et al. suggested that expression of LIF mRNA in the endometrium could
be used as a molecular marker for unexplained infertility [59].
Treatment with recombinant human LIF (rhLIF) has been investigated in preclinical
and clinical trials as a method of improving endometrial receptivity in patients with
recurrent implantation failure (RIF). It was suggested that compensating for low levels
of endometrial LIF expression might have a positive effect on the outcome of IVF in
women with recurrent implantation failure. Unfortunately, rhLIF administration during
the secretory phase after embryo transfer failed to improve implantation rates in
women with recurrent implantation failure [60]. It is possible that the endometrium had not shifted into the secretory phase sufficiently;
rhLIF administration alone is thus not able to provide the wide range of factors present
in a receptive endometrium.
αvβ3 integrin
Several studies have reported that αvβ3 integrin is related to angiogenesis and VEGF. Expression of αvβ3 integrin in endothelial cells is induced by VEGF in vitro [46]. Both αvβ3 integrin and VEGF up-regulation have also been shown to prevent endothelial cell
apoptosis in vitro [48], [61]. The lack of αvβ3 seen in the endometrium of the subfertile patients included in the present study
might therefore be due to a VEGF deficiency. αvβ3 integrin is able to promote endothelial cell migration in a calcium-dependent manner
[62]. It has been demonstrated that this receptor is involved in vacuolation and lumen
formation in human umbilical vein endothelial cells in a fibrin matrix [63]. The receptor is expressed in blood vessels in human wound granulation tissue, but
not in normal skin [64]. Integrin αvβ3 antagonists have been reported to promote tumor regression by inducing apoptosis
of angiogenic blood vessels in a chick chorioallantoic membrane [64]. Exposure of human endothelial cells to tumor necrosis factor (TNF) and interferon
gamma (IFN-γ) results in reduced activation of αvβ3 integrin and leads to decreased αvβ3-dependent endothelial cell adhesion and survival. Preclinical studies have shown
that RGD peptidomimetics and a monoclonal antibody to αvβ3 integrin can inhibit tumor growth by blocking tumor-induced angiogenesis [65]. αvβ3 integrin in particular has an important impact on the regulation of normal and tumor
cell migration, as well as on angiogenesis and tumor metastasis [66]. Coughlan et al. did not detect any significant differences in αvβ3 integrin expression in any compartment of the endometrium between women with recurrent
implantation failure (RIF) and control women. It is possible that only a few patients
in the study group had the endometrial defect lacking αvβ3 integrin that leads to infertility. Coughlan et al. did not focus on patients with
suspected endometrial defects, and the endometrial tissue studied may therefore not
have had any significant differences in comparison with the control group [67].
Data from in vivo and in vitro investigations show that αvβ3 integrin is able to regulate angiogenesis in human and animal tissues. Its expression
may therefore also play an important angiogenic role in the human endometrium.
Leptin receptor
The leptin receptor is involved in angiogenesis [68], [69]. Immunoreactivity for OB-R, VEGF, and matrix metalloproteinase (MMP) is up-regulated
in atherosclerotic plaque, predominantly in the endothelial lining of the intimal
neovessel [70]. Leptin induces endothelial cell proliferation and expression of matrix metalloproteinases
in vivo and in vitro. Immunohistological analysis of leptin-treated rat cornea showed
a definite increase in the expression of OB-R, MMPs, and TIMPs, and also of VEGF receptor-1
(VEGF-R1). Leptin induced proliferation of the human umbilical vein endothelial cells
(HUVECs) and elevation of MMP-2, MMP-9, TIMP-1 and TIMP-2 expression in a dose-dependent
manner [37]. These results once again demonstrate the involvement of leptin in angiogenesis
and further support the theory that a lack of leptin receptor may lead to inadequate
angiogenesis in the endometrium as well [36].
Leptin induces proliferation and angiogenic differentiation of endothelial cells,
up-regulates VEGF/VEGF-R2, and transactivates VEGF-R2 independently of VEGF. Leptin
induces angiogenic factors such as IL-1 and Notch, which can increase VEGF. Its pro-angiogenic
actions have been summarized in review articles by Gonzalez-Perez et al. [38], Krikun [39], and Adya et al. [40]. Reduced expression of anti-inflammatory and angiogenic cytokines has been observed
in women with idiopathic recurrent spontaneous miscarriage (IRSM). Markers of endometrial
receptivity were poorly expressed in women with IRSM [71].
As we have shown previously [3] the leptin receptor (long splice variant) is absent or inadequately expressed in
the endometrium in subfertile patients who have an abnormally thin endometrium.
Conclusions
Leukemia inhibitory factor (LIF), vascular endothelial growth factor (VEGF), and β3 integrin, which are marker molecules for endometrial receptivity, were found to be
inadequately expressed or completely absent in the endometrial tissue samples in this
specific group of subfertile patients with suspected endometrial deficiency. Although
these markers were initially identified and investigated independently of each other,
they have a positive influence on one other and are involved in angiogenesis ([Fig. 3]). The endometrial deficiency appears already to commence during the proliferative
phase, as shown by a lack of VEGF and leptin receptor [8]. Angiogenic defects may thus lead to insufficient secretory transformation, resulting
in a thin endometrium that is consequently incapable of providing a mature environment
for the implanting embryo. The endometrial deficiency observed is not merely due to
a phase delay with late maturation.
In these patients, the endometrium is unable to reach a fully receptive implantation
phase in most cycles, although the patients ovulate and have normal serum hormone
levels, followed by normal expression and down-regulation of steroid hormone receptors.
The fact that the patients become pregnant in a few cases, but never deliver, suggested
that the endometrial problem is a functional one, with different developmental and
maturation grades in each endometrial cycle.
The deficiency of the marker molecules concerned strongly supports the hypothesis
that there is disturbed angiogenesis, leading to insufficient secretory transformation
and resulting in a thin endometrium that causes a reduced implantation rate in this
group of subfertile patients. It may be suspected that there must be a regulatory
defect after the activation of steroid hormone receptors that precedes the translation
of these marker molecules. Further research is needed to identify the underlying regulatory
mechanisms involved in this endometrial maturation deficiency.
