In
An association between IVF and hypertensive disorders of pregnancy or
preeclampsia has been thoroughly documented ( Tables 1 – 3 ). Several
groups of researchers reported increased frequency of hypertensive disorders of
pregnancy or preeclampsia in frozen embryo transfer (FET) vs fresh ET. However,
the FET protocol(s) were not delineated, and whether donor gametes were included
or not was only specified in one of the studies 21 – 23 . In the investigation by Opdahl and colleagues,
relative risk (RR) for hypertensive disorders of pregnancy was 7.0% and 4.7%,
respectively, for FET and spontaneous pregnancy, aOR 1.41, 95%CI
1.27–1.56 (adjusted for maternal age, parity, birth year, infant sex and
country). The same authors also noted higher risk in siblings conceived by FET
vs fresh ET, aOR 2.39, 95%CI 1.48–3.86 23 . More recently, the
risk of preeclampsia was also found to be increased for autologous FET in
artificial cycles (AC) vs fresh ET 24 – 26 . In
one of these studies, patients with polycystic ovary syndrome (PCOS) were
randomized to FET-AC or fresh ET cycles 24 . Finally, in another investigation, autologous FET-NC
and FET-stimulated cycles were employed, and the authors observed no significant
differences in the rate of hypertensive disorders among women conceiving by
FET-NC, FET-stimulated cycle, fresh ET or spontaneous conception 27 . Taken together, these studies
suggested that FET, and in particular FET-AC protocols may be associated with
increased rates of hypertensive disorders of pregnancy and preeclampsia as
compiled from Table 1 and summarized in
Tables 2 and 3 , respectively.
In a recently published prospective study, we recruited women during
early pregnancy with singleton intrauterine pregnancies who conceived using
autologous oocytes and delivered live born infants (n=878) 12 . No participants had an infertility
diagnosis of premature ovarian failure or were recipients of donor oocytes or
embryos. After adjustment for several preeclampsia risk factors (i.e., maternal
age, nulliparity, history of hypertension, BMI, PCOS, pre-gestational and
gestational diabetes), women conceiving by FET in artificial cycles, in which a
CL did not develop, had increased risk for preeclampsia (aOR 2.73, 95%CI
1.14–6.49) and preeclampsia with severe features (aOR 6.45, 95%CI
1.94–25.09) compared to sub-fertile women with one CL. In a sub-analysis
of FET in artificial cycles compared to FET in modified natural cycles with one
CL, the adjusted odds ratios were 3.55, 95%CI 1.20–11.94 for developing
preeclampsia, and 15.05, 95%CI 2.59–286.27 for preeclampsia with severe
features. Importantly, women conceiving by fresh ET in ovarian stimulation
cycles who had multiple CL did not show increased preeclampsia risk. This study
was the first to evaluate preeclampsia risk in IVF from the standpoint of CL
status. The findings implicated absence of the CL as a possible contributor to
the development of preeclampsia ( Tables 1
and 3 ).
In a parallel study, we serially evaluated cardiovascular function in
women before, during and after pregnancies, who conceived after controlled
ovarian stimulation (COS) (>1 CL), autologous FET or fresh donor
oocyte-derived embryos transferred in artificial cycles (0 CL), or spontaneous
conceptions (1 CL) 12 , 13 . We observed significant attenuation of
the gestational changes in numerous cardiovascular parameters during the first
trimester in women who conceived by IVF without a CL, which mostly recovered
during the second trimester. These findings were consistent with the hypothesis
that circulating CL factor(s) mediate cardiovascular adaptations to pregnancy
during the first trimester in spontaneous pregnancy, and placental factors
supersede after the corpus luteal-placental shift 7 . The cardiovascular adaptations to
pregnancy in the IVF participants with multiple CL were comparable to those
observed in spontaneous pregnancies. Although we established an association
between absent CL, dysregulated cardiovascular adaptations in the first
trimester, and increased preeclampsia risk, whether these factors were causally
linked remains to be proven.
A recent comprehensive publication from Sweden based on a retrospective
registry study of singleton pregnancies after autologous FET reported a
frequency of 8.2% for preeclampsia in artificial cycles (0 CL; n=1446) compared
to 4.4% in natural cycles (1 CL; n=6297)—aOR 1.78, 95%CI 1.43–2.21
(adjusted for maternal age, BMI, parity, year of birth of infant, maternal
smoking, chronic hypertension, child’s sex, level of maternal education,
and years of involuntary childlessness) 10 . The women conceiving by fresh ET with multiple CL
(n=24,365) showed a lower rate of preeclampsia closer to that of spontaneous
conceptions (n=1,127,566)—3.7% and 2.8%, respectively. Similar trends
were observed for hypertensive disorders of pregnancy. 10 Additional published studies
demonstrated that women conceiving by autologous FET in artificial cycles had
increased risk for hypertensive disease of pregnancy or preeclampsia compared to
autologous FET in natural cycles, or fresh ET in ovarian stimulation cycles.
However, a potential etiologic role for absent CL in the elevated risk of
hypertensive disorders of pregnancy or preeclampsia in artificial cycles was not
hypothesized in these reports (e.g., 24 – 26 , 28 ; Tables 1 – 3 ).
In summary, although not yet confirmed by a rigorous randomized
controlled clinical trial comparing autologous FET-AC and FET-NC or modified NC,
the emerging data suggest that use of IVF protocols which lead to suppression of
CL formation may increase preeclampsia risk. These data are concerning due to
the immediate- and long-term detrimental consequences of preeclampsia for both
mother and child. Thus, in addition to pre-pregnancy maternal characteristics in
many IVF patients such as older maternal age and subfertility, absence of the CL
as an etiological factor in the impaired maternal cardiovascular adaptations
during early pregnancy and increased preeclampsia risk should also be
considered. The absence of critical circulating CL factor(s) is perhaps the most
likely explanation for the dysregulation of maternal cardiovascular function
observed during early pregnancy in women conceiving by IVF without a CL, in part
because either full or partial recovery subsequently transpired after the
“corpus luteal-placental shift” coincident with secretion of
placental factors 12 , 13 . But, whether the absence of CL
factor(s) and of their vasodilatory and pro-decidualizing attributes, or the
possibility of suboptimal luteal support with estrogen and progesterone for
endometrial preparation in artificial cycles (dose and/or
timing —vide supra ) 5 , 8 ,
or both underlie increased preeclampsia risk is less clear. Ultimately, if
replacement of the missing CL factor(s) (e.g., relaxin) restores maternal
cardiovascular function in early pregnancy and reduces preeclampsia risk, then
this approach might be an alternative preventative strategy to autologous FET in
a natural cycle for some women, and perhaps the only approach available for
women who have ovarian failure requiring donor oocytes or embryos to conceive.
Mild ovarian stimulation, which would permit CL development in a FET cycle,
might be used is women who do not ovulate on a regular basis.
The absence of a CL and circulating CL product(s) likely contribute to
the increased risk of preeclampsia in autologous FET-AC vs FET-NC. However,
whether or not cryopreservation, in addition to absence of a CL, may confer
added risk of preeclampsia in FET-AC compared to fresh ET is difficult to test.
Close examination of the study by Sites et al. in the context of CL status may
shed some light on this question 26 . Autologous fresh embryo transfer (>1 CL) and
autologous frozen embryo transfer in an artificial cycle (0 CL) yielded rates of
PE of 4.29 and 7.51%, respectively ( Tables
1 and 3 ). The difference could
have been a consequence of embryo state (fresh vs frozen) and/or CL number
(>1 vs 0 CL). Donor fresh and frozen embryo transfer in artificial cycles
(0 CL) yielded rates of preeclampsia of 12.13 and 10.78%, respectively 26 (use of artificial cycles for
donor frozen embryo transfers was standard of care according to Dr. Sites,
personal communication). These preeclampsia rates were not significantly
different, which suggested that the freeze/thaw manipulation of embryos did not
confer increased risk for PE (although a ceiling effect cannot be excluded).
Comparing autologous (4.29%) and donor fresh (12.13%) ET revealed that the
difference, 7.17%, was PE risk attributable to “donor” (vs
autologous) and “CL” (>1 vs 0 CL) effects. Comparing
autologous (7.51%) and donor frozen (10.78%) ET both using artificial cycles (0
CL) revealed that the difference, 4.62%, was the contribution to PE attributable
to “donor” (vs autologous) effect, alone. Thus, the difference
between the PE rates attributable to “donor” and
“CL” effects (7.17%) and “donor” (4.62%) effect,
2.55%, must be due to the “CL” effect, alone. Although any
conclusion based on these rough estimates must be regarded cautiously, the
artificial cycle (0 CL), in addition to a donor embryo source appeared to
account for the considerably higher rates of preeclampsia in women who were
recipient of donor-oocyte derived embryos.
Why
The emerging evidence suggests that perhaps not all IVF protocols are
created equal with respect to increased risk for hypertensive disorders of
pregnancy and preeclampsia. Although IVF protocols were frequently not presented
in sufficient detail in many of the publications, after close inspection of
those in which they were delineated, the balance of evidence implicated the
artificial (or programmed) cycle protocol. That is, elevated risk for
hypertensive disorders of pregnancy and preeclampsia primarily resulted from
FET-AC, not FET-NC or FET-stimulated, or fresh ET cycles ( Table 1 ). Perhaps not coincidentally, the maternal
hemodynamic adaptations to pregnancy were perturbed in AC, but not COS cycle
protocols 12 , 13 . Close inspection of the grand averages
of the rates for hypertensive disorders of pregnancy and preeclampsia listed in
Table 1 further highlight that
increased risk is associated with the artificial cycle ( Tables 2 and 3 ).
In most of the studies that reported increased risk for preeclampsia in
autologous FET-AC protocols, the gestational age of preeclampsia onset and the
severity of disease were not specified ( Table
1 ). However, a few did provide these details. Chen and coworkers
observed increased risk for term, but not preterm preeclampsia or preeclampsia
with severe features 24 ;
increased frequency of term preeclampsia and preeclampsia with severe features,
but not preterm preeclampsia were noted by both von Versen-Hoynck et
al. 12 and Barsky and
colleagues 25 ; and
Sites and coworkers reported increased incidence of both preterm and term
preeclampsia, and preeclampsia with severe features in autologous
FET-AC 26 . Although the
number of studies are too few to draw any definite conclusions, with the
exception of Sites and coworkers, term preeclampsia both with and without severe
features was associated with autologous FET-AC protocols. A recent theory for
the pathogenesis of term preeclampsia proposes that it arises from villous
overcrowding, which leads to compression of intervillous spaces that, in turn,
impedes blood flow causing placental ischemia. That is, villous growth outstrips
uterine capacity 29
( vide supra ).
Interestingly, women with low circulating relaxin concentration in early
pregnancy were observed to be at increased risk of developing late onset
preeclampsia (≥34 weeks) 30 . Possibly, the vasodilatory attributes of relaxin are
important in some women to mitigate the physiological rise in circulating
vasoconstrictors such as sFLT1, thereby restraining the normal restoration of
the maternal circulation to the non-pregnant state of relative vasoconstriction
towards the end of pregnancy 13 , 31 , 32 . In fact, circulating sFLT1 and the sFLT1/PLGF ratio
were significantly higher at the end of pregnancy in women conceiving by IVF
especially for AC (0 CL) protocols 33 , perhaps reflecting villous overcrowding and placental
ischemia. Whereas circulating relaxin is absent in artificial cycles,
concentrations are either comparable to spontaneous pregnancy or markedly higher
in controlled ovarian stimulation cycles, the latter possibly explaining the
equivalent rates of preeclampsia in COS and spontaneous pregnancies as noted
above ( Tables 1 and 3 ).
The finding by Sites et al. of increased preterm, in addition to term
preeclampsia after autologous FET-AC protocol should not be ignored
( vide supra ) 26 . Indeed, this investigation may have identified increased
risk for both term and preterm PE due to larger cohort sizes, and hence,
increased study power. However, on the surface, it is difficult to reconcile
preterm and term PE based on a common decidual etiology. Preterm preeclampsia is
widely believed to be associated with impaired trophoblast invasion and spiral
artery remodeling, while recent theory suggests that term preeclampsia does not
involve deficient placentation, but rather villous overcrowding ( vide
supra ). Conceivably, villous overcrowding might be exacerbated by
post-term delivery and larger placentas associated with large for gestational
age or macrosomic infants—adverse pregnancy outcomes also associated with
artificial (programmed) IVF cycles (e.g., 10 , 34 ). Indeed,
post-term delivery itself has been associated with increased preeclampsia and
eclampsia risk 35 presumably as
a consequence of the mechanisms outlined above being exacerbated by prolonged
time for placental growth 29 .
Enhanced frequency of LGA and macrosomia in autologous FET during artificial
cycles are also consistent with the increased risk of term preeclampsia, insofar
as it is not infrequently accompanied by a large for gestational age (LGA)
fetus 36 , 37 and large placenta 38 . Whether term preeclampsia may be
associated with excessive trophoblast invasion, albeit to lesser degree than
accreta spectrum disorders that also occur more frequently in artificial IVF
cycles (e.g., 11 ), is not
known.
On the one hand, excessive trophoblast invasion is
observed in tubal pregnancy and accreta spectrum disorders, in which decidua is
deficient and/or dysregulated 39 – 41 . On
the other, dysregulated decidualization is associated with preterm preeclampsia
with severe features, in which trophoblast invasion is
deficient 2 – 4
( vide supra ). These apparently disparate actions of the
decidua on trophoblast invasion are difficult to reconcile mechanistically,
i.e., how can decidual pathology lead to both excessive and deficient
trophoblast invasion? One potential explanation is that activation of different
molecular pathways account for these divergent actions of the decidua on
trophoblast behavior that may be regulated, at least in part, by factors derived
from the corpus luteum, or lack thereof. A priori, it seems logical to presume
that decidual pathology would not be restricted to one phenotypic expression of
excessive trophoblast invasion as in some cases of placental accreta disorders,
but rather different molecular pathology could also arise, which leads to
impaired trophoblast invasion frequently observed in preterm preeclampsia.
Future
In light of the association between dysregulated decidualization and
preeclampsia, the underlying molecular mechanism(s) of the pathologic decidua now
need to be identified, in order to design prophylactic or corrective interventions.
Eventually, efforts to improve decidualization before and during early pregnancy
might be indicated in those women at increased risk for the disease (e.g., by
administration of hormones known to promote decidualization). Finally, circulating
or urinary biomarkers or a panel of biomarkers reflecting endometrial dysfunction
might be helpful in identifying women at increased risk (e.g., low circulating
IGFBP-1 or glycodelin before and/or during early pregnancy) 3 .
Given the perturbed maternal physiology and increased risk of several
adverse pregnancy outcomes in IVF cycles involving autologous frozen embryo transfer
in artificial (programmed) cycles, what can be done to intervene? Careful inspection
of the data revealed that the increased risk for hypertensive disorders of pregnancy
and preeclampsia was not observed in frozen embryo transfer using natural or
stimulated cycles, or controlled ovarian stimulation cycles. Based on this
revelation, it is reasonable to propose that a large multi-site, randomized clinical
trial be conducted comparing pregnancy outcomes between autologous FET-AC and
FET-NC, FET-modified NC, or FET-stimulated cycles 12 . In a subgroup of patients, maternal
physiology could be intensively investigated, in order to determine whether it would
be normal after FET-NC, FET-modified NC or FET-stimulated cycles in contrast to
FET-AC as predicted 7 , 12 , 13 , 42 . If a RCT confirms the hypothesis
that maternal physiology and pregnancy outcome will be improved, then FET-NC,
FET-modified NC or FET-stimulated cycles might be preferred protocols in many women.
A common denominator is the absence of a corpus luteum in artificial IVF cycles,
whereas at least one CL develops in FET-NC, FET-modified NC and FET-stimulated
cycles 7 , 12 , 13 .
All CL product(s) are missing in FET-AC (except for E2 and P4 administered for
luteal support), and therefore, the absence of any one or several of them could
underlie the dysregulated maternal cardiovascular adaptations to pregnancy and
increased risk for adverse pregnancy outcomes. Indeed, both the cardiovascular
system and endometrium are known targets of at least one CL factor that is not
replaced in AC protocols, relaxin ( vide supra ; 42 , 43 ).
Therefore, including the missing CL factor(s) like relaxin with E2 and P4 for luteal
support in artificial cycles might be investigated, in order to determine whether
the addition of CL factor(s) like relaxin to the IVF medical regimen would correct
the dysregulated maternal cardiovascular physiology and reduce the risk for adverse
pregnancy outcomes. For women with ovarian failure for which natural IVF cycles are
unattainable, replacing the missing CL factor(s) may be the only option.
Endometrium
One widely held theory is that preeclampsia originates within the
placental bed during early gestation in many women. Normally, the fetal
extravillous trophoblast emanating from the anchoring villous tips invade the
gestational endometrium (decidua) and inner 1/3 of the myometrium, remodeling
the uterine spiral arteries from low caliber, high resistance to high caliber,
low resistance blood vessels. These physiological changes of the spiral arteries
facilitate increased maternal blood flow into the intervillous space. In
contrast, preeclampsia is often associated with impaired trophoblast invasion
and spiral artery remodeling, thereby restricting blood flow into the
intervillous space leading to placental ischemia. These placentation
deficiencies may not be unique to preeclampsia, as they have also been
described, albeit not universally so, in late sporadic miscarriage, normotensive
fetal growth restriction, placental abruption, and preterm labor 6 .
It should be noted that the classical view of the biological consequences
of spiral artery remodeling or lack thereof, as presented above, has been
recently called into question. Revised computational modeling suggested that
spiral artery remodeling is unlikely to contribute substantially to reducing
uterine vascular resistance and increasing blood flow in normal pregnancy,
rather the (proximal) radial artery is a more significant resistance
site 14 . Computational
modeling further revealed that spiral artery remodeling in normal pregnancy
reduces the velocity of increased blood flow into the intervillous space,
thereby protecting delicate villi from mechanical damage and increasing the
transit time of blood flow through the intervillous space allowing for adequate
exchange of oxygen and nutrients across the syncytiotrophoblast layer 15 . According to this model,
failure of spiral artery remodeling in preeclampsia would lead to the opposite
chain of events, i.e., mechanical damage of villi by high velocity blood flow
and rapid transit time of blood flow through the intervillous space precluding
adequate oxygen and nutrient exchange across the syncytiotrophoblast
layer 15 . Nevertheless,
regardless of which model is apropos, each predicts that failure to remodel
spiral arteries would impair placental function. In both scenarios,
ischemia-reperfusion injury would also occur as a consequence of spontaneous and
hormone-induced constriction or relaxation of spiral arteries that were not
remodeled and retained vascular smooth muscle.
Because uterine invasion and spiral artery remodeling by trophoblast can
be deficient in preeclampsia, this fetal cell has been intensively investigated.
Moreover, the paternal genetic contribution to disease etiology could be
manifest, at least in part, through impairment of trophoblast invasion. The
seminal work of Fisher and colleagues revealed the extensive molecular and
functional aberrations of the extravillous trophoblast in early onset, severe
preeclampsia as investigated at the end of pregnancy in situ ,
and after trophoblast isolation, in vitro 16 . However, a potential caveat to this
methodological approach is that molecular pathology at the end of pregnancy may
be more related to the phenotypic expression of the disease, which typically
emerges at that time or may even be a consequence of the
disease (e.g., sFLT1 could conceivably be injurious to endometrium, in addition
to endothelium). Therefore, the molecular pathology of tissues procured at
delivery is likely to be unrelated to the molecular etiology which
caused the disease months before, when the physiological
processes of uterine trophoblast invasion and spiral arterial remodeling
transpired. That is, the large temporal gap between the acquisition of placental
tissues for molecular studies at delivery and the critical period of trophoblast
invasion and spiral artery remodeling occurring in early pregnancy, may preclude
any insights into the molecular genesis of preeclampsia. One potential solution
to this conundrum is prospective acquisition of early placental
tissues (surplus chorionic villous samples or CVS) months before onset of
clinical manifestations. Although the advent of noninvasive prenatal screening
(NIPs) has markedly reduced the number of CVS procedures performed world-wide,
collaboration among large medical centers with the greatest volume of CVS cases
annually, could lead to acquisition of sufficient sample numbers for molecular
and functional investigation of preeclampsia etiology targeting the
trophoblast.
Another potentially relevant tissue that has received little attention in
the context of adverse pregnancy outcomes is the maternal decidua
(“soil”), which extravillous trophoblast (“seed”)
invade ( vide supra ). Conceivably, insufficient or defective
endometrial maturation (decidualization) that begins in the secretory phase and
continues after implantation may impede trophoblast invasion and spiral artery
remodeling, thereby contributing to the genesis of preeclampsia 1 , 17 . This alternative, but not mutually exclusive
hypothesis is perhaps intuitive or self-evident, in light of the close
apposition of endometrial stromal, glandular epithelial and maternal immune
cells with trophoblast and spiral arteries in the placental bed. Furthermore,
the maternal inheritance pattern of preeclampsia could be manifest, at least in
part, through dysregulation of decidualization. Normally, massive molecular and
functional changes occur in endometrial stromal and epithelial cells, spiral
arteries and immune cells during decidualization in the secretory phase and
early pregnancy. Implantation and placentation depend on the optimal and timely
progression of decidualization. Decidualization of the glandular epithelium is
prerequisite to histiotrophic nutrition during early gestation prior to onset of
maternal blood flow; uterine [natural killer] NK cells become the major immune
cell type in the placental bed and assume an immunomodulatory rather than
cytotoxic phenotype, and they initiate spiral artery remodeling and stimulate
trophoblast invasion; uterine macrophages accumulate and they adopt an
“M2” or alternatively active rather than pro-inflammatory
phenotype; and T regulatory cells contribute to immune tolerance at the
maternal-fetal interface in the face of the fetoplacental
semi-allograft 3 , 18 . In essence, decidualization
is preparation of the “soil” for the “seed”, i.e.,
embryo implantation and subsequent placentation. Impairment of this process as
one possible etiology of preeclampsia would seem to be a reasonable hypothesis
to explore.
In order to investigate relevant reproductive tissue temporally related
to decidualization, trophoblast invasion and spiral artery remodeling, we
prospectively obtained surplus CVS at ~11.5 gestational weeks in women
who developed preeclampsia with severe features (sPE) or who experienced normal
pregnancy (NP) outcome 5–6 months later 1 . These tissue samples were snap frozen in
liquid nitrogen and ultimately analyzed by DNA microarray. Contrary to our
hypothesis, we did not detect a molecular signature consistent with ischemia or
ischemia-reperfusion, rather many genes identified as biomarkers of
decidualization were downregulated in the CVS from women who developed sPE
relative to NP outcome including insulin-like growth factor binding protein-1
(IGFBP-1), glycodelin or progesterone-associated endometrial protein (PAEP),
prolactin (PRL) and IL-15. These initial observations prompted a wider text
mining approach, which revealed many other dysregulated decidual genes that, in
turn, provided the justification for a formal bioinformatics reanalysis of the
raw data from our CVS microarray data 2 .
The bioinformatics reanalysis of the CVS microarray data revealed 396
differentially expressed genes (DEGs) between CVS from sPE and NP-CVS, of which
154 or 40% overlapped with DEGs changing during endometrial maturation either in
the secretory phase or early pregnancy (p=4.7 × 10 −14 ),
the latter DEGs obtained by reanalyzing publically available microarray datasets
of normal decidualization. Moreover, approximately 73% of these 154 DEGs changed
in the opposite direction compared to normal endometrial
maturation (p=0.01), and 75% overlapped significantly with DEGs between
proliferative vs late secretory endometrium or DEGs between decidualized vs
nondecidualized endometrium obtained from tubal ectopic pregnancies (p=4.4
× 10 −9 ). Neither of these endometrial tissues contain
extravillous trophoblast, thus suggesting a primary role for
dysregulated decidualization. Moreover, 16 DEGs normally
upregulated in uterine compared to peripheral NK cells were
downregulated in sPE- compared to NP-CVS (p<0.0001).
DEGs normally upregulated in uterine relative to peripheral
macrophages were downregulated in sPE- vs NP-CVS (p=9.5
× 10 −3 ) and vice versa (p=1.1 ×
10 −6 ) 3 .
Taken together, these observations suggested deficient or defective endometrial
maturation including uterine NK cells and macrophages may precede the
development of preeclampsia with severe features. The concept that dysregulated
decidualization is involved in the genesis of preeclampsia was supported by 6
studies published throughout the last 10 years or so, which demonstrated a
reduction of circulating concentrations of IGFBP1 during early pregnancy in
women who later developed PE (reviewed in 3 ).
Another notable finding from the CVS microarray study was that the
average mRNA expression of a cohort of 20 decidual genes uniquely
upregulated in normal late secretory compared to proliferative
endometrium were downregulated in sPE- vs NP-CVS by ~
2-fold (p<0.0001) 2 . This
observation suggested that the dysregulation of endometrial maturation in the
women who developed PE with severe features may have started
before pregnancy during the secretory phase. Indeed, the
idea that endometrial pathology may reside in the secretory endometrium was
strongly reinforced by Garrido-Gomez and coworkers, who reported marked
impairment of in vitro decidualization of endometrial stromal
cells isolated and then cultured from mid-secretory endometrial biopsies of
women who experienced sPE during the previous 1–5 years 4 . In fact, there was significant
overlap of DEGs that arose from sPE-CVS vs NP-CVS as reported by Rabaglino and
colleagues with the DEGs observed by Garrido-Gomez and coworkers in cultured
endometrial stromal cells decidualized in vitro that were
derived from women who experienced prior sPE vs normal pregnancy 5 .
A priori, decidual tissue at delivery is likely to be markedly
dissimilar from decidual tissue in the secretory phase or early pregnancy
( vide supra ). This important point was highlighted by
additional bioinformatics analysis of differential gene expression in these
temporally disconnected decidual tissues from women who experienced sPE vs NP,
insofar as there was little or no overlap 5 . Thus, designing strategies to address the molecular
genesis of PE which resides in the secretory endometrium and/or placental bed of
early pregnancy based upon the molecular pathology of delivered tissue may be
misleading, and unlikely to lead to preventative or early corrective
measures.
In summary, emerging evidence supports the concept that preeclampsia may
arise at least in some women from dysregulated decidualization including
aberrant endometrial immune cell number and/or function in the secretory phase
and during early pregnancy 1 , 2 , 4 ( Fig. 1 ). In
delivered placentas, decidual function is also perturbed, which may contribute
to or arise from deleterious circulating placental factors like sFLT1
(e.g. 19 , and reviewed
in 3 ). But, as discussed
above, the transcriptomics of delivered decidua are distinct from those of early
pregnancy or the secretory phase in women who developed preeclampsia, and as
such, may not be relevant to disease etiology 3 , 5 . Perhaps not
totally unexpected in light of this potential link between aberrant
decidualization and preeclampsia, an elegant recently published study provided
evidence that intrauterine growth restriction, another disease entity classified
under the great obstetrical or placental syndromes, may also have origins in
impaired decidualization 20 .
Because dysregulated decidualization was associated with preeclampsia,
we asked the question whether there might be molecular overlap with other
endometrial disorders 5 . To this
end, we reanalyzed 8 microarray databases in the public domain from normal and
pathologic endometrium or decidua. A significant proportion of the DEGs up- or
downregulated in CVS from women who experienced PE with severe features compared
to NP, or in cultured endometrial stromal cells decidualized in
vitro derived from mid-secretory biopsies of women who experienced
severe PE relative to NP ( vide supra ), demonstrated overlap
with, and the same directional change as DEGs in recurrent implantation failure
(RIF), recurrent miscarriage (RM) and endometriosis (OSIS) compared to their
respective control tissues 5 .
In order to further explore this idea, a functional analysis and
pathway-driven approach was taken 5 . The cytokine-cytokine receptor interaction pathway (264
genes) was one of the most prominent and significant molecular pathways in
common among normal and pathological endometrium. Principal component analysis
(PCA) was employed to compare gene expression in this pathway among the
different normal and pathological endometrial tissues represented by 8
microarray databases ( Fig. 2 ). CVS and
in vitro decidualized endometrial stromal cells derived
from mid-secretory phase biopsies of women who suffered sPE segregated with the
three endometrial disorders. In contrast, decidua procured at delivery from
women affected by sPE clustered with normal endometrium, indicating that the
expression pattern of the genes of these tissues at least in the
cytokine-cytokine receptor pathway more resembled the normal than pathological
endometrium. Of course, this does imply that other molecular pathways in the
decidua obtained at delivery from women who suffered sPE may not be abnormal.
Overall, however, the differentially expressed genes affected in delivered
tissues were not overlapping with those found in the CVS or in
vitro decidualized endometrial stromal cells from mid-secretory
phase biopsies of women who suffered sPE. In the same vein, proliferative
endometrium and non-decidualized early pregnancy endometrium as histologically
assessed, clustered with pathological endometrium in the context of the
cytokine-cytokine receptor interaction pathway.
Taken together, integration of multiple microarray datasets derived from
normal and pathologic endometrium suggested that, at least in some women,
preeclampsia may be part of a continuum of endometrial disorders involving
varying degrees of molecular dysregulation affecting implantation, placentation
or both. Indeed, other disease entities classified as placental syndromes may
also fall along this continuum ( Fig. 3 ).
That PE has, in common with the classical endometrial disorders, many
differentially expressed genes and gene pathways strengthens the concept that
the genesis of the disease may reside in the decidua at least for some women.
Viewing PE in this light may also partly explain why women with endometriosis
who become pregnant experience increased PE risk as reported by some, but not
all investigators. Similarly, recurrent miscarriage was also associated with
increased PE risk (see 5 for
citations).
Introduction
Adverse pregnancy outcomes may have antecedents in the pre- and
peri-conception periods, and first trimester of pregnancy. This idea was supported
by studies implicating dysregulation of endometrial maturation (decidualization)
during the secretory phase and early pregnancy in the genesis of
preeclampsia 1 – 4 . The concept of “endometrium
spectrum disorders” then emerged 3 , which was underpinned by the integration of multiple
endometrial transcriptomic databases available in the public domain 5 . These bioinformatics analyses
provided evidence for dysregulation of molecular pathways in common among the
classic endometrial disorders—recurrent implantation failure, recurrent
miscarriage, endometriosis—and one of the great obstetrical or placental
syndromes, preeclampsia 5 , 6 . Conceivably, other adverse pregnancy
outcomes that may arise from placental pathology including normotensive intrauterine
growth restriction and preterm birth, also fall within the continuum of endometrial
spectrum disorders affecting implantation, placentation or both depending upon the
specific molecular pathways disrupted and the severity of disruption 3 . Although the genesis of the great
obstetrical syndromes including preeclampsia is likely to be multifactorial, in some
women these disease entities may have antecedents in endometrial dysregulation
during early pregnancy or even before pregnancy.
In vitro fertilization (IVF) is another setting in which
pre- and peri-conception, as well as early pregnancy factors may impact obstetrical
outcome. In pregnancies conceived by IVF using artificial (programmed) cycles
involving hypothalamic-pituitary suppression and development of the endometrium with
estradiol and progesterone, a corpus luteum (CL) does not develop 7 . These IVF protocols were observed to perturb
endometrial gene expression in the mid-secretory phase 8 , 9 , and
to be associated with greater risk of post-term delivery, large for gestation age
infants and macrosomia, as well as placental accreta 10 , 11 .
In addition, artificial cycles were also linked to maternal hemodynamic
dysregulation in the first trimester, and hypertensive disorders of pregnancy and
preeclampsia 12 , 13 . Because the CL is a key regulator of
endometrial function including decidualization in the secretory phase and early
pregnancy, one potential explanation for increased incidence of these adverse
obstetrical outcomes is that, despite luteal support with exogenous estradiol and
progesterone, the absence of other crucial circulating CL factors(s) negatively
affects endometrial maturation in artificial IVF cycles 7 , 10 , 12 . Another potential, albeit not
mutually exclusive explanation is that the dosage and timing of estradiol and
progesterone administration for luteal support is suboptimal 8 , 9 .
In this review, the molecular evidence of impaired decidualization in
preeclampsia, and the emerging concept of “endometrial spectrum
disorders”, in which dysregulated decidualization of preeclampsia, recurrent
implantation failure, recurrent miscarriage and endometriosis demonstrated
significant overlap of molecular pathology will be presented. In addition, the
discovery of dysregulated maternal hemodynamics during the first trimester of
artificial (programmed) IVF cycles, as well as the association with increased risk
for hypertensive disorders of pregnancy and preeclampsia will be also be presented
in the context of the corpus luteum, or more precisely, the lack thereof, in the
case of artificial cycles.
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