Published online before print December 21, 2007

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(American Journal of Pathology. 2008;172:77-85.)
© 2008 American Society for Investigative Pathology
DOI: 10.2353/ajpath.2008.070640

Severe Intrauterine Growth Restriction Pregnancies Have Increased Placental Endoglin Levels

Hypoxic Regulation via Transforming Growth Factor-β3

Yoav Yinon^*, Ori Nevo^*, Jing Xu^*, Ariel Many^*, Alessandro Rolfo^*, Tullia Todros, Martin Post and Isabella Caniggia^*

From the Department of Obstetrics and Gynecology,^*Mount Sinai Hospital, Samuel Lunenfeld Research Institute, the Department of Pediatrics,Hospital for Sick Children, and the Department of Physiology,University of Toronto, Toronto, Canada; and the Department of Obstetrics and Gynecology,University of Turin, Turin, Italy

	Abstract

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Endoglin, a co-receptor for transforming growth factor (TGF)-β₁ and -β₃ is expressed in the human placenta and plays an important role in the pathogenesis of preeclampsia. Because preeclampsia is associated with hypoxia, and because TGF-β3 is overexpressed in preeclamptic pregnancies, we examined the effect of oxygen and TGF-β3 on placental endoglin expression and investigated its expression in pathological models of placental hypoxia such as intrauterine growth restriction (IUGR) pregnancies. Endoglin expression was high at 4 to 9 weeks of gestation, when oxygen tension is low, and decreased after 10 weeks, when oxygen tension increases. Exposure of villous explants to low oxygen (3% O₂) resulted in elevated expression of both membrane and soluble endoglin compared to standard conditions (20% O₂). Moreover, addition of TGF-β₃ to villous explants under low oxygen conditions increased the expression of endoglin compared to nontreated explants whereas addition of TGF-β₃-neutralizing antibodies inhibited the low oxygen stimulatory effect on endoglin expression. Endoglin and soluble endoglin expression were significantly increased in placentas of IUGR singletons compared to controls and in the IUGR twin placentas relative to both the control co-twin and the normal twins. These data demonstrate that oxygen regulates the placental expression of endoglin via TGF-β₃. Reduced placental perfusion leading to placental hypoxia might contribute to the increased expression of endoglin in IUGR pregnancies.

	Materials and Methods

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Tissue Collection

Local ethics committee approvals were obtained for the study, and all women gave written informed consent. The tissues were collected at Mount Sinai Hospital, Toronto, Canada, and at Ospedale Infantile Regina Margherita S.Anna Hospital, Turin, Italy. All women were healthy nonsmokers, with no signs of preeclampsia, infections, or other known causes of IUGR. The clinical characteristics of the singleton pregnancies are shown in Table 1 . Gestational age was determined by the date of the last menstrual period and first trimester ultrasound measurement of crown-rump length. IUGR was defined as birth weight below the fifth percentile accompanied by abnormal umbilical artery Doppler defined as absence or reverse of end diastolic velocity and in most of cases with increased resistance to flow in uterine arteries defined as early diastolic notch or pulsatility index >1.45. None of the neonates had evidence of infection, anomalies, or abnormal chromosomes. Umbilical blood gas analysis at delivery of the IUGR cases demonstrated low oxygen tension indicating impaired oxygenation of these IUGR fetuses. The mean arterial and venous pO₂ was 13 ± 4.64 mmHg and 24.2 ± 4.55 mmHg, respectively. Controls were selected as age-matched and term healthy pregnancies with normal grown fetuses that did not have signs of placental dysfunction. Data regarding maternal characteristics, mode of delivery, birth weight, gestational age, laboratory values, and ultrasound findings were collected from the clinical records. Patients suffering from diabetes, essential hypertension, or renal disease were excluded. The preterm control group included only spontaneous preterm deliveries without an identifiable cause. All preterm and term control groups did not show clinical or pathological signs of preeclampsia, infections, or other maternal or placental disease. Specimens were randomly collected immediately after delivery from normal-looking cotyledons. Areas with calcified, necrotic, or visually ischemic tissue were omitted from sampling. The samples were stored at –80°C. All placentas from preterm deliveries were examined by a perinatal pathologist, and cases that had histological evidence of chorioamnionitis were excluded.

Villous explant cultures were established from first trimester human placentas (5 to 8 weeks of gestation) obtained from elective terminations of pregnancies by dilatation and curettage. Villous explant cultures were established as described previously.¹⁶ To explore O₂ effects, explants were maintained in either standard condition of 20% O₂ (5% CO₂ in 95% air) or in an atmosphere of 3% or 8% O₂ (5% CO₂ in 92% or 87% N₂, respectively) for 48 hours at 37°C. Six sets of explants from six different placentas were used. To validate the effect of low oxygen on villous explants, we performed Western blot analysis using rabbit polyclonal antibody to HIF-1 (no. 3716; Cell Signaling Technology, Danvers, MA). In separate experiments, villous explants, prepared from placentas of 5 to 8 weeks of gestation, were incubated under different oxygen tensions (3% O₂, 8% O₂, and 20% O₂) in the presence or absence of TGF-β₃ or TGF-β₁ (5 ng/ml). Five sets of explants from five different placentas were used for these experiments. In addition, villous explants were incubated at 3% and 20% O₂ with or without neutralizing antibodies to TGF-β₃ (10 µg/ml). For each experimental condition a minimum of three explants harvested from the same placenta were used.

RNA Isolation and Real-Time Reverse Transcriptase-Polymerase Chain Reaction (qPCR)

Total RNA, extracted from placental tissues, was treated with DNase I to remove genomic DNA contamination After column purification (Qiagen, Mississauga, Canada), 1 µg of total RNA was reverse transcribed using random hexamers (Applied Biosystems, Inc., Foster City, CA). The resulting templates (50 ng of cDNA for Eng and 5 ng for 18S) were quantified by real-time PCR (MJ Research Inc., Waltham, MA) as previously described.²⁰ TaqMan Universal MasterMix and specific TaqMan primers and probe for Eng and 18S were purchased from Applied Biosystems, Inc. (Assay ID HS00164438_m1). Relative quantification of data were performed using logarithmic curves. Expression level of Eng was normalized based on 18S expression using the 2Ct formula as previously described.²⁰

Western Blot Analysis

Western blot analysis for Eng was performed using 50 µg of total placental protein lysates that were subjected to 8% (w/v) sodium dodecyl sulfate-polyacrylamide gel electrophoresis. After electrophoresis, proteins were transferred to polyvinylidene difluoride membranes. Nonspecific binding was blocked by incubation in 5% (w/v) nonfat dry milk in Tris-buffered saline containing 0.1% (v/v) Tween-20 (TBST) for 60 minutes. Membranes were then incubated with 1:1000 diluted rabbit polyclonal antibody to human Eng (Santa Cruz Biotechnology, Santa Cruz, CA) in 5% milk in TBST at 4°C. After overnight incubation, membranes were washed with TBST and incubated for 60 minutes at room temperature with 1:5000 diluted horseradish peroxidase-conjugated anti-rabbit IgG (Santa Cruz Biotechnology) in 5% milk in TBST. After washing with TBST, blots were visualized by enhanced chemiluminescence (Amersham Pharmacia Biotech, Oakville, Canada).

Immunohistochemistry

Paraffin sections were mounted on glass slides, dewaxed in xylene, and rehydrated in descending ethanol gradient. Antigen retrieval was performed by heating in 10 mmol of sodium citrate solution. Endogenous peroxidase was quenched with 3% (v/v) hydrogen peroxide in phosphate-buffered saline (PBS) for 30 minutes. After blocking (5% normal goat serum for 1 hour), the slides were incubated overnight with 1:600 diluted primary antibody (H-300, SC-20632; Santa Cruz Biotechnology). Slides were washed in PBS and exposed to biotinylated secondary antibody (1:300, goat anti-rabbit; Vector Laboratories, Burlingame, CA) for 45 minutes at room temperature. Finally, avidin biotin complex (Vector Laboratories) was applied for 1 hour, and positive staining was detected with the diaminobenzidine chromogen. Slides were counterstained with hematoxylin. In negative controls, primary antibody was omitted and replaced by blocking solution. Six samples of IUGR, four samples of preterm and term control, and six pairs of discordant twins were used for immunohistochemistry.

Statistics

Statistical analyses were performed using GraphPad Prism software (San Diego, CA). For comparison of data between multiple groups one-way analysis of variance with posthoc Dunnett’s test was used. For comparison between two groups Wilcoxon matched paired test and unpaired t-test were performed when applicable. Significance was defined as P < 0.05. Results are expressed as the mean ± SEM (SE).

	Results

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Placental Eng Expression Is Increased at the Early Stages of Pregnancy

Early placental development is marked by a switch in oxygen tension, which is low at 5 to 9 weeks and increases at 10 to 12 weeks.^21,22 To establish whether the expression of Eng is affected by this physiological change in placental oxygenation, we examined its expression in placentas from different stages of pregnancy. Eng mRNA expression was significantly higher in early first trimester placental samples (4 to 9 weeks of gestation) compared to samples from 10 to 19 weeks of gestation (3.48 ± 0.5 versus 1.3 ± 0.4, P < 0.05) and term placentas (3.48 ± 0.5 versus 1.02 ± 0.1, P < 0.05) (Figure 1A) . Eng expression was not different between late first/second trimester and term placental samples. Quantitative PCR analysis of GAPDH, which is a housekeeping gene, showed no difference in its placental mRNA expression levels between early first trimester, late first/second trimester, and term gestation (1.084 ± 0.3, 0.8 ± 0.02, and 1.17 ± 0.6, respectively), excluding the possibility that early placentas are more transcriptionally active than the later first trimester and term placenta. Western blot analysis of placental lysates demonstrated increased expression of both Eng and its soluble form (sEng) in placental samples from 4 to 9 weeks of gestation compared to samples from 10 to 19 weeks of gestation (Figure 1B) . Densitometric analysis revealed that both Eng and sEng protein levels were significantly increased in early first trimester samples compared to late first/second trimester samples (Eng: 2.43 ± 0.28-fold increase, P < 0.01; sEng: 3.01 ± 0.22-fold increase, P < 0.01) (Figure 1C) .

View larger version (27K): [in this window] [in a new window]   Figure 1. Eng expression during placental development. A: Expression of Eng mRNA in early first trimester placental samples versus late first and second trimester and term placental samples as assessed by qRT-PCR (4 to 9 weeks, n = 7; 11 to 19 weeks, n = 6; term, n = 4); *P < 0.01, 4 to 9 weeks versus 11 to 19 weeks and 4 to 9 weeks versus term. B: Representative Western blot analysis for Eng and sEng in first and second trimester placental samples. C: Eng (left) and sEng (right) protein densitometric analysis in placental tissues from early first trimester (4 to 9 weeks, n = 7) compared to late first and second trimester (11 to 19 weeks, n = 7), *P < 0.01.

We next examined the effect of different oxygen conditions on Eng expression. Exposure of villous explants to 3% O₂ resulted in a significant increase in Eng message levels compared to explants kept at 20% O₂ (2.37 ± 0.5-fold, P < 0.05; Figure 2A ). Exposure to 8% O₂ resulted in a trend toward increased Eng mRNA expression, although not statistically significant, compared to 20% O₂ (Figure 2A) . Both Eng and sEng protein levels were greater in explants kept at 3% O₂ compared to those maintained at 20% O₂ (Figure 2, B and C) . As anticipated, exposure of explants to low oxygen levels also increased HIF-1 protein levels (Figure 2B , bottom).

View larger version (13K): [in this window] [in a new window]   Figure 2. Effect of low oxygen on Eng expression in first trimester villous explants. A: Expression of Eng mRNA in explants cultured at 3%, 8%, and 20% O2 measured by qRT-PCR (n = 6; *P < 0.05, 3% versus 20%). B: Top: Representative Western blot of Eng and sEng shows full-length Eng (90 kDa) and sEng (65 kDa), which are highly expressed in first trimester villous explants exposed to 3% O2 compared to 8% O2 and 20% O2; bottom: representative Western blot of HIF-1. C: Eng protein densitometric analysis in first trimester villous explants exposed to different oxygen conditions, n = 6. *P < 0.05, 3% versus 20%.

To study the effect of TGF-β₃ on Eng expression we performed a series of experiments in which explants were maintained overnight at 3% and 20% O₂ and then cultured in the presence or absence of TGF-β₃ for 24 hours. Addition of TGF-β₃ to explants exposed to 3% O₂ significantly increased Eng mRNA expression compared to explants maintained at 3% O₂ alone (4.1 ± 0.3-fold increase, P < 0.05) (Figure 3A) . Addition of TGF-β₃ to explants cultured at 20% O₂ also increased Eng mRNA levels, but the effect was not significant (2.1 ± 0.5-fold increase, P = 0.07) (Figure 3B) . Similar to the mRNA expression, addition of TGF-β₃ resulted in elevated Eng protein levels in explants cultured in 3%, but not 20%, O₂ when compared to explants maintained in 3% and 20% O₂ alone, respectively (Figure 3, C–E) . In contrast to TGF-β₃, we found no significant difference in Eng mRNA and protein expression after TGF-β₁ treatment (data not shown). To examine whether the effect of low oxygen on the expression of Eng is mediated via TGF-β₃, we cultured explants maintained at 3% O₂ with neutralizing antibodies to TGF-β₃ for 24 hours. Addition of TGF-β₃-neutralizing antibodies inhibited the 3% O₂-induced expression of Eng (Figure 3, F and G) . No changes were noted after addition of TGF-β₃-neutralizing antibodies to explants maintained at 20% O₂ (Figure 3, F and G) .

View larger version (25K): [in this window] [in a new window]   Figure 3. Effect of TGF-β3 on Eng expression in first trimester villous explants exposed to different oxygen conditions. A: Eng mRNA levels in explants cultured at 3% oxygen with and without TGF-β3 as measured by qRT-PCR (n = 3, *P < 0.05). B: Eng mRNA levels in explants cultured at 20% oxygen with and without TGF-β3 as measured by qRT-PCR (n = 3, P = 0.07). C: Representative Western blot of Eng in villous explants with and without TGF-β3 in different oxygen conditions. D: Eng protein densitometric analysis of explants exposed to 3% oxygen with and without TGF-β3 (n = 5, *P < 0.01). E: Eng protein densitometric analysis in explants exposed to 20% oxygen with and without TGF-β3 (n = 5). F: Representative Western blot of Eng in villous explants maintained at 3% and 20% oxygen and treated with neutralizing antibodies to TGF-β3. G: Eng protein densitometric analysis of explants exposed to 3% and 20% oxygen with and without TGF-β3-neutralizing antibodies (n = 5, *P < 0.05).

We next examined the expression of Eng and sEng in placentas of IUGR singleton pregnancies with documented absence or reverse of end diastolic velocity in the umbilical artery and without signs of preeclampsia. Placentas from age-matched preterm deliveries (preterm control, PTC) and term deliveries (term control, TC) were used as controls. Quantitative PCR analysis revealed a significant increase in the number of Eng transcripts in IUGR placentas compared to PTC (3.15 ± 1.0 versus 1.05 ± 0.1, P < 0.05) (Figure 4A) . In accordance with the qPCR results, Western blot analysis demonstrated increased levels of both Eng and its soluble form (sEng) in placental tissue of IUGR pregnancies compared to preterm and term controls (Eng: IUGR, 3.4 ± 0.4 versus PTC, 1.6 ± 0.2 versus TC, 1 ± 0.6, P < 0.05; sENG: IUGR, 2.29 ± 0.27 versus PTC, 0.93 ± 0.08 versus TC, 1 ± 0.14, P < 0.05) (Figure 4, B–D) . No difference in Eng levels was noted between the IUGR cases with normal uterine Doppler and the ones with abnormal uterine Doppler (data not shown). Immunohistochemical analysis showed that Eng expression was primarily restricted to the trophoblast layer (see Figure 6A ). In line with the protein data, strong positive immunoreactivity for Eng was observed in the IUGR placentas compared to the absent/low staining found in sections from placentas of preterm and term control. We also tested the expression of Eng in placentas of discordant twin pregnancies, in which one twin exhibited IUGR with birth weight below the fifth percentile for gestational age and abnormal umbilical artery flow, whereas the other twin was appropriate for gestational age. Normal twin pregnancies without discordancy were used as controls. Real-time PCR demonstrated significant elevated transcript levels of Eng in the placentas of IUGR discordant twins compared to their normal co-twins and compared to twin controls (IUGR twin: 1.6 ± 0.3 versus normal co-twin: 0.9 ± 0.14 versus twin control A: 0.98 ± 0.23 and twin control B: 0.93 ± 0.12; P < 0.05) (Figure 5A) . Analysis of the data according to the chorionicity of the twins showed significantly greater Eng transcript levels in the dichorionic IUGR twin compared to the normal co-twin (1.39 ± 0.2 versus 0.8 ± 0.1, P < 0.05) and increased transcript levels, reaching the borderline of statistical significance in the monochorionic IUGR twin compared to the normal co-twin (1.75 ± 0.5 versus 1 ± 0.2, P = 0.06) (Figure 5B) . Concurrent with the qPCR results, Western blot analysis demonstrated increased expression of both Eng and its soluble form (sEng) in the placentas of dichorionic and monochorionic IUGR discordant twins compared to their normal co-twins and compared to twin controls (Eng: small discordant, 2.09 ± 0.25 versus large discordant, 1.1 ± 0.1, respectively, P < 0.05; sEng: small discordant, 1.8 ± 0.2 versus large discordant, 1 ± 0.25, respectively, P < 0.05) (Figure 5, C and D) . Immunostaining of sections of discordant twins demonstrated a stronger immunoreactivity for Eng in the placentas of the IUGR discordant twin compared to the normal co-twin placenta in both dichorionic and monochorionic discordant twins (Figure 6B) .

View larger version (26K): [in this window] [in a new window]   Figure 4. Eng and sEng expression in placentas of IUGR pregnancies. A: Eng transcript levels in IUGR placentas versus preterm controls (PTC) measured by qRT-PCR (IUGR, n = 11; PTC, n = 10; *P < 0.05). B: Representative Eng and sEng Western blot in placentas of IUGR, preterm controls (PTCs), and term controls (TCs). C: Eng protein densitometric analysis of IUGR placentas (n = 12) compared to PTC (n = 8) and TC (n = 8, *P < 0.05). D: sEng protein densitometric analysis of IUGR placentas (n = 12) compared to PTCs (n = 8) and TCs (n = 8, *P < 0.05).

View larger version (50K): [in this window] [in a new window]   Figure 6. Immunohistochemical staining of Eng in IUGR, discordant twins, and control placentas. A: Term control (TC); preterm control (PTC), and IUGR placentas. Brownish staining represents positive Eng immunostaining. B: Negative control (NC), control twin (C-Twin), monochorionic large twin (MC-LTwin), monochorionic small twin (MC-STwin), dichorionic large twin (DC-LTwin), dichorionic small twin (DC-STwin). Original magnifications, x100.

View larger version (30K): [in this window] [in a new window]   Figure 5. Eng expression in discordant twins’ placentas. A: Eng mRNA levels in discordant twins (S,: small IUGR twin; L,: large normal co-twin; n = 8) compared to control twins (n = 5), assessed by qRT-PCR (*P < 0.05). B: Eng mRNA levels in dichorionic discordant twins (DC, n = 3) and in monochorionic discordant twins (MC, n = 5) as assessed by qRT-PCR (*P < 0.05). C: Representative Eng and sEng Western blot in placentas of discordant dichorionic and monochorionic twins and of normal control twins. D: Eng protein densitometric analysis in placentas of discordant twins (n = 9) compared to placentas of normal control twins (n = 4, *P < 0.05).

	Discussion

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The development of the placental villous tree during early pregnancy takes place in an environment of relatively low oxygen tension, which is essential for normal embryonic development.²¹ At 10 to 12 weeks of gestation, the intervillous space opens to maternal blood, and oxygen levels surrounding the placental villi increases.²² We found greater levels of Eng at the early stages of gestation, when oxygen tension is low, suggesting that low oxygen positively regulates placental Eng expression. Our explant studies confirmed that low oxygen triggers placental expression of Eng. These findings agree with previous reports regarding increased expression of Eng in pathological tissues associated with hypoxic conditions such as ischemic tissues and tumors.^23,24 Studies with endothelial cells have shown that hypoxia up-regulates Eng expression via hypoxia-inducible factor 1 (HIF-1), which binds to hypoxia-responsive elements in the Eng promoter.^25,26 We have previously shown that HIF-1 expression parallels that of TGF-β₃ during the first trimester of gestation.⁹ Their expression is high at 5 to 8 weeks of gestation and decreases at around 10 to 12 weeks when placental oxygen tension increases,⁸ mimicking exactly Eng’s pattern of expression. In addition, HIF-1, TGF-β₃, and Eng are overexpressed in preeclamptic placentas.^10,17,27-29 These observations together with TGF-β₃ being a HIF-1-responsive gene³⁰ led us to speculate that TGF-β₃ may be involved in the hypoxia-induced expression of placental Eng. Our finding of neutralizing TGF-β₃ antibodies inhibiting hypoxia-induced Eng expression in placental explants supports this concept. Moreover, our observation that TGF-β₃ increased Eng levels only under hypoxic conditions, suggests that hypoxia and TGF-β₃ have a synergistic effect on placental Eng expression. In agreement with our finding, Sanchez-Elsner and colleagues²⁶ demonstrated a transcriptional cooperation between hypoxia and TGF-β₁ leading to marked stimulation of Eng expression in endothelial cells. They suggested that the cooperative effect between both stimuli on endothelial cells could be an adaptive response aimed at optimizing angiogenesis under special conditions.²⁶ However, in the human placenta Eng is expressed at high levels by the syncytiotrophoblast cells,^12,31 but at relatively low levels on blood vessels, and herein we demonstrated that TGF-β₃, but not TGF-β₁, stimulated Eng production. The lack of TGF-β₁ effect on placental Eng expression could be explained by the fact that TGF-βs may exert their function in a tissue-specific manner. We have previously reported that blockage of Eng accelerates trophoblast migration and invasion, suggesting that Eng is a negative regulator of this system.¹⁶ Thus, we speculate that in pathological hypoxic conditions Eng is inappropriately up-regulated in part via TGF-β₃, which would lead to abnormal trophoblast invasion and complications such as preeclampsia and IUGR.

Our present data demonstrate that both Eng and soluble Eng are highly expressed in placentas of IUGR pregnancies, including singleton IUGR pregnancies and IUGR discordant twins that do not exhibit signs of preeclampsia. To our knowledge, this is the first report on increased Eng expression in placentas of IUGR pregnancies. Our findings are further strengthened by a recent report showing elevated sEng levels in the circulation of women with IUGR pregnancies.³² Both Eng and sEng are known to be increased in preeclamptic placentas, and the elevated circulatory levels of sEng in preeclamptic women have been correlated with its severity.¹⁷ It is important to emphasize that all of the IUGR pregnancies included in this study had evidence of abnormal flow in the umbilical artery (either AEDV or REDV), indicating that the growth restriction was because of placental insufficiency. Moreover, all pregnancies were characterized by an early onset of growth restriction, which necessitated delivery of the fetuses before 34 weeks of gestation. None of the patients exhibited clinical signs of preeclampsia and as such represented a pure group of IUGR. Consistent with our findings, Venkatesha and colleagues¹⁷ showed that co-administration of sEng and sFlt to pregnant rats resulted in fetal growth restriction in addition to preeclampsia-like syndrome. Because all our patients had sonographic indication of placental insufficiency and low oxygen stimulates Eng expression, it is plausible that the placental hypoxia because of reduced placental perfusion is responsible for the increased expression of Eng in IUGR pregnancies. Despite our assumption that reduced placental perfusion leading to placental hypoxia initiates the cascade of events leading to IUGR, there is no data in the literature demonstrating low placental pO₂ values in IUGR pregnancies. Pardi and colleagues³³ showed reduced oxygen extraction in IUGR pregnancies implicating a different mechanism leading to fetal hypoxia, although less rigorous clinical criteria than ours were used to classify IUGR because only birth weight and not abnormal umbilical artery flow was used.

Of note, all our IUGR pregnancies were delivered by cesarean section whereas only 44% of the preterm controls were delivered in this way. Mode of delivery can differently affect gene expression in placental tissue, and increased placental expression of VEGF and VEGFR-2 has been demonstrated in vaginal deliveries accompanied by birth asphyxia.³⁴ However, none of our preterm control deliveries were complicated by birth asphyxia, and we did not find any difference in Eng expression between normal vaginal deliveries and cesarean sections (data not shown).

Overexpression of Eng in IUGR placentas was also validated in our study of discordant twins, in which the expression of Eng and sEng was elevated in the placenta of the IUGR twin compared to the normal co-twin and compared to twin controls. Discordant twins as a model for IUGR has the advantage of both twins being exposed to the same maternal and uterine environment, and therefore, the normal co-twin can serve as an ideal control for the IUGR twin. All IUGR discordant twins included in the present study had evidence of abnormal flow in their umbilical artery. Thus, the growth restriction was likely because of placental hypoperfusion and villous hypoxia. Although the literature regarding molecular differences between discordant twins is limited, one study showed different expression of hypoxia-regulated genes in the IUGR-derived placenta compared to the placenta of the normal co-twin in dichorionic discordant twins.⁴ In the present study, Eng expression was elevated in the IUGR twin compared to its co-twin in both dichorionic discordant twins and monochorionic discordant twins, despite reaching statistical significance only in the dichorionic twins. This could be attributed to the small sample size but also to different mechanisms underlying growth restriction in discordant monochorionic compared to discordant dichorionic twins. Unlike monochorionic twins, in which discordancy has been attributed to placental vascular communication and uneven sharing of the placental disk, the most common accepted mechanism in dichorionic twins is placental insufficiency of the smaller fetus because placentas in discordant dichorionic twins may demonstrate lesions typical of singleton growth restriction.^35,36 However, other studies have found little evidence that anastomoses were a major cause of discordancy among monochorionic twins and suggested that abnormal placentation, rather than placental vascular anatomy, may be responsible for IUGR in monochorionic twins.^37,38

In summary, our study demonstrates that placental Eng expression is up-regulated by hypoxia via TGF-β₃ and that Eng is overexpressed in IUGR placenta, most likely secondary to placental hypoxia. Overproduction of Eng would cause inhibition of trophoblast differentiation and invasion,¹⁶ which could contribute to the development of IUGR. Furthermore, excessive production of Eng would lead to increased soluble Eng in the maternal circulation, which in turn may cause endothelial dysfunction resulting in preeclampsia and IUGR.¹⁷

	Footnotes

 
Address reprint requests to Isabella Caniggia, M.D., Ph.D., Mount Sinai Hospital, Samuel Lunenfeld Research Institute, 600 University Ave., Room 871c, Toronto, Ontario, Canada M5G 1X5. E-mail: caniggia{at}mshri.on.ca

Supported by the Canadian Institutes of Health Research (grant MT-14096).

Accepted for publication September 17, 2007.

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