Angiotensin II receptor (type 1 and 2) expression peaks when placental growth is maximal in sheep

doi:10.1152/ajpregu.00070.2002

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Angiotensin II receptor (type 1 and 2) expression peaks when placental growth is maximal in sheep

Irene Koukoulas, Tomris Mustafa, Rebecca Douglas-Denton, and E. Marelyn Wintour

Howard Florey Institute of Experimental Physiology and Medicine, The University of Melbourne, 3010 Victoria, Australia

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In sheep, placental size is maximal by midgestation, but blood flow continues to increase until term. No nerves are presentand ANG II is thought to be a major regulator of vascular tone.We hypothesized that angiotensin type 2 receptors (AT₂) wouldpredominate over type 1 (AT₁) until late in gestation and be primarilyexpressed in the vasculature. Real-time PCR, hybridization histochemistry,and ligand-binding studies were performed on placentae and fetalmembranes at 27, 45, 66 ± 1, 100 ± 4, 130, and 140 days of gestation(term $approx$ 150 days) to determine quantitative changes and localization.The maximum level of AT₁ expression occurred in the 45-day placentaand was located predominantly in the maternal stromal cells. AT₁receptors were expressed in the endothelial cells of the chorionin the first half of pregnancy, where later in gestation, bothAT₁ and AT₂ receptors were predominant in blood vessels. Theseresults suggest that ANG II, via the AT₁ receptor, may have hithertounsuspected important roles in the growth/function on the ovineplacenta during the maximal growthphase.

AT₁ receptor; AT₂ receptor; placenta; pregnancy; real-time polymerase chain reaction

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

OPTIMAL GROWTH OF A FETUS depends on adequate provision of oxygen and substrates as well as the appropriate endocrine environment(33). Intrauterine growth retardation (IUGR), resulting in lowbirth weight for gestational age, is now known to be associatedwith an increased risk for the development of cardiovascular andmetabolic disease in the adult (39). Successful placental functiondepends on the appropriate growth and adequate perfusion of bothmaternal and fetal components of the placenta (42). In sheep,maximal placental growth occurs in the first half of pregnancy,whereas blood flow and exchange capacity continue to increaseuntil term, supporting the major growth of the fetus in the lastthird of gestation (42).

One system implicated in normal vascular placentation and blood flow control is the renin-angiotensin-system (RAS) and, inthe human, a complete RAS is found in the placenta (41). Proreninand angiotensinogen are produced by the decidua, a maternal tissuenot found in many other species (27). Angiotensin-convertingenzyme (ACE) mRNA is found in the human placenta (53), and ANGII receptors, predominantly of the AT₁ type, are present in boththe syncytiotrophoblasts and cytotrophoblasts (7, 28) andare reduced in IUGR. There is also evidence that abnormalitiesof AT₁ expression are important in preeclampsia (14). An autoagonistantibody to AT₁, which can stimulate the production of tissuefactor, has been shown to be produced in preeclampsia (48).Recently, it has been shown that AT₁ in the human placenta isupregulated at both the mRNA and protein level in preeclampsia(26).

Most studies of fetal physiology have been conducted in sheep, which is a nondeciduate species and in which there is no substantialevidence for the production of renin by the placenta. There havebeen extensive studies on the effects of ANG II on both the uterineartery and umbilical artery, although these have been done almostexclusively in the last third of pregnancy (8, 43). The AT₂receptor type has been found to predominate in the smooth muscleof the maternal uterine artery (34) and in the majority of fetalblood vessels with the notable exception of the external umbilicalartery, in which AT₁ predominates, at least in the second halfof pregnancy (5). There has been, however, no systematic studyof the proportions and location of AT₁/AT₂ expression throughoutpregnancy insheep.

The ovine placenta differs from that of the human in that it consists of 60-100 individual cotyledons, which are formed bythe attachment of the fetal trophoblast cells (which also formthe chorion) at predetermined sites (caruncles) in the uterinewall (52). The fetal membranes consist of the chorion, whichoverlies both the amnion and the allantois; the fetus developswithin the amniotic cavity. The allantoic cavity is a second fluid-filledsac that occupies the tip of the pregnant horn and all the non-pregnanthorn in a singleton pregnancy. Fetal urine enters the allantoicsac via the urachus, which arises in the bladder wall and travelsin the center of the umbilical cord (51).

The hypothesis tested in the current study was that AT₁/AT₂ expression would be confined to blood vessels in the ovine placentaand fetal membranes and that AT₂ expression would predominateuntil late in pregnancy. The unexpected finding was that AT₁ wasmost highly expressed early in pregnancy and that the maternalstroma of the placenta was the major site of expression, whichraises exciting new possibilities for the function of ANG II inearly placental growth/function.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Animals. Animals were killed by an overdose of pentobarbital sodium (Lethabarb, Arnolds, Boronia, Australia; 100 mg/kg body wt). Allantois,amnion, chorion, and cotyledon tissue samples were collected fromfour fetuses from the following age groups: 65-67, 96-104, and140 days of gestation (term is 145-150 days) for real-time PCRstudies. Cotyledon tissue samples were also collected from fourfetuses at 27 days of gestation and six fetuses at 45 days ofgestation. Intercarunculi uterine tissue was collected from fourpregnant ewes at 27 days of gestation. Additional cotyledon sampleswere also collected at 41 and 51 days of gestation as well as130 days of gestation for in situ hybridization histochemistryand receptor binding assays. Fresh tissues were rinsed in physiologicalsaline (0.9%) and cleaned with gauze to remove excess blood beforefixing and freezing. After being cleaned, tissue was immediatelyfrozen in liquid nitrogen and stored at $-$ 80°C until further useor fixed in 4% paraformaldehyde in 0.1 M phosphate buffer for4 h at room temperature and routinelyprocessed.

Isolation of total RNA. Total RNA was extracted from frozen tissue by the acid guanidinium thiocyanate-phenol-chloroform extraction method (6).

DNase treatment of total RNA. For each total RNA sample, 20 µg was DNase treated in a 100-µl reaction containing 10 mM DTT, 5 mM MgCl₂, 40 mM Tris · HCl(pH 7.5), 0.2 U/µl of RNase inhibitor, and 0.03 U/µl of RNase-freeDNase I. The reactions were incubated at 37°C for 15 min priorto a heat inactivation step at 65°C for 10 min followed by threephenol extractions and one chloroform extraction. The total RNAsamples were ethanol precipitated to remove residual organic solventcontamination and resuspended in milli Q water (0.05% DEPC treated).The total RNA quality and content was established after obtainingabsorbance readings at 260 and 280 nm. The integrity of the totalRNA was examined after fractionating 1 µg onto a formaldehydeagarose gel. Samples were stored at $-$ 80°C until furtheruse.

cDNA synthesis. Each cDNA synthesis reaction consisted of 1 × TaqMan RT buffer, 5.5 mM MgCl₂, 500 µM of each dNTP, 2.5 µM of random hexamers,0.4 U/µl of RNase inhibitor, 1.25 U/µl of MultiScribe RT, and10 ng/µl of total RNA. All of the above reagents were suppliedin an RT reagents kit (Applied Biosystems). The reverse transcriptionreactions were performed in a GeneAmp PCR System 9600 (AppliedBiosystems) with incubations at 25°C for 10 min, 48°C for 30 min,and 95°C for 5 min. EDTA was added at a final concentration of0.01 M to each reaction tube before storage at $-$ 80°C.

Real-time PCR. For the relative quantitation of gene expression, real-time PCR was performed (16) using an ABI PRISM 7700 Sequence DetectionSystem (Applied Biosystems). Primers and TaqMan probes for real-timePCR were designed using Primer Express version 1.5 (Applied Biosystems).The nucleotide sequences for the AT₁ and AT₂ primers and probeshave been published elsewhere (36) where their positions relativeto GenBank/EMBL data entries are also provided. Ribosomal 18S(18S) TaqMan probe and primers were supplied by Applied Biosystemsin a reagentskit.

For the relative quantitation of gene expression, a multiplex comparative threshold cycle (C_T) method was employed. A C_T valuereflects the cycle number at which fluorescence is first detected.PCR product formation during the cycling process is able to bedetected because of the accumulation of fluorescence via the cleavageof an internal TaqMan probe that has fluorescent dyes attachedto both the 5' and 3' ends. Due to different dyes being attachedto different TaqMan probes (FAM for the AT₁ and AT₂ receptorsand VIC for 18S), different PCR products can be detected in theone tube. Separate AT₁ and AT₂ reactions were set up where 18Swas detected in both of these reactions, although the primersfor 18S were limited. In pilot experiments, multiplex vs. non-multiplexC_T values were compared, where for all genes studied, the C_T valueswere identical, suggesting that multiplex reactions did not affectC_T values. A validation experiment was also performed to testwhether the comparative C_T method could be used for the relativequantitation of gene expression. Here, approximately equal efficienciesof AT₁ and AT₂ amplifications together with 18S were tested usingdifferent template concentrations and, in both sets of multiplexreactions, approximately equal PCR efficiencies wereobtained.

PCR reactions were carried out in 25-µl volumes consisting of 1× TaqMan Universal Master Mix (including the passive referenceROX), 50 nM 18S TaqMan probe, 20 nM 18S forward primer, 80 nMreverse primer, 150 nM AT₁ TaqMan probe, 900 nM forward and reverseprimers or 75 nM AT₂ TaqMan probe, and 300 nM forward and reverseprimers. cDNA (5 ng) and no RT preparations (no RT preparationswere cDNA reactions minus RT) were amplified using the followingconditions: 50°C for 2 min and 95°C for 10 min followed by 40cycles of 95°C for 15 s and 60°C for 1min.

Real-time PCR calculations. Determining the relative quantitation of gene expression using the comparative C_T method has been described in detail elsewhere(19). Comparative C_T calculations for AT₁ and AT₂ gene expressionwere all relative to a chosen calibrator. The first ontogeny studyfocused on the placenta at 27, 45, 66 ± 1, 100 ± 4, and 140 daysof gestation and included the 140-day placenta as the calibrator.In the second ontogeny study, where gene expression was studiedin the fetal membranes at 66 ± 1, 100 ± 4, and 140 days of gestation,the amnion at 66 ± 1 days of gestation was chosen as the calibrator.Every AT₁ and AT₂ study was performed separately. A multiplexreaction was performed in each assay, where both a test gene (AT₁or AT₂) and 18S were amplified together. To achieve quantitativevalues, 18S C_T values were first subtracted from a test C_T valuefor each well to give a $Delta$ C_T value. $Delta$ $Delta$ C_T values were achieved bysubtracting the average calibrator $Delta$ C_T value from the $Delta$ C_T valuein every other tissue at each age group. AT₁ and AT₂ gene expressionrelative to the calibrator at each gestational age was evaluatedusing the expression 2^C_T.

In vitro transcription of riboprobes. After the recombinant plasmids were linearized, both antisense and sense (negative control) riboprobes were prepared by invitro transcription using the Promega riboprobe kit (Promega,Madison, WI), where [ $alpha$ -³⁵S]UTP (100 Ci/mmol) was incorporated (Bresatec, Thebarton, Australia).The riboprobes were hydrolyzed (9), precipitated, and resuspendedin 10 mM DTT before hybridization histochemistry. Plasmid constructsconsisting of the ovine AT₁ and AT₂ receptor sequences were kindlyprovided by Dr. Jean Robillard, Ann Arbor,MI.

In situ hybridization histochemistry. Paraffin sections (4 µm) were cut and mounted onto silanized slides and dried overnight at 37°C. The slides were subsequentlydewaxed and rehydrated before sections were digested at 37°C for10 min with Pronase E (Sigma) at a final concentration of 125µg/ml. The sections were rinsed twice in 0.1 M phosphate buffer(pH 7.4) before postfixing in 4% paraformaldehyde for 10 min atroom temperature. Again, the sections were rinsed twice in 0.1M phosphate buffer (pH 7.4) before dehydration and air drying.Hybridization was performed by applying ~60 µl of riboprobe, ata final concentration of 0.02 ng/µl, onto each section, whichwere subsequently covered with a coverslip. The hybridizationbuffer consisted of 10% of 10× salts (100 mM Na₂HPO₄, 3 M NaCl,pH 6.8, 100 mM Tris · HCl, pH 7.5, 50 mM EDTA, pH 8.0, 0.2% bovineserum albumin, 0.2% Ficoll 400, 0.2% polyvinyl pyrolidone), 50%formamide, 0.7 mg/ml yeast tRNA, 10 mM DTT, and 10% dextran sulfate.Sections were hybridized overnight at 50°C in a sealed humidifiedchamber. On the following day, coverslips were removed after thoroughwashing in formamide buffer (50% formamide, 10% 10× salts) at50°C and three subsequent washes at 1 h each with gentle rocking.The sections were rinsed in RNase A buffer (0.5 M NaCl, 10 mMTris · HCl, pH 7.5, 1 mM EDTA, pH 8.0), followed by RNase A (150µg/ml; Sigma-Aldrich) treatment at 37°C for 2 h with gentle rockingto remove free riboprobes. Once the digestion was complete, nonspecificbinding was removed after three washes with 2× SSC at 65°C for30 min each. The sections were finally rinsed briefly in milliQ water to remove residual salt, dehydrated, air dried, and exposedto Fuji phosphorimaging plates (BASII) overnight to determinepotential hybridizing sites after scanning on a Fujix BAS 2000scanner. Slides were dipped in liquid emulsion (Ilford, Essex,UK) and exposed for 10 days at room temperature before developingin filtered Kodak D19 developer for 2 min and fixing in IlfordHypam fixer (1/5 dilution) for 2 min. Sections were finally stainedwith hematoxylin andeosin.

Image acquisition. For in situ hybridization histochemistry, light and dark images were captured on a Nikon Microphot microscope linked to aSony 930P video camera (Sony, Australia). Digitized images weresubsequently processed using microcomputer imaging device software(Imaging Research, St. Catherine's,Canada).

Membrane fraction preparation. Frozen placental tissues were moderately thawed, diced, and homogenized in ice-cold hypotonic buffer consisting of 50 mM Tris,5 mM EDTA, pH 7.4. After centrifugation at 600 g for 5 min at4°C to remove cellular debris, supernatants were centrifuged at50 000 g for 20 min at 4°C and the recovered membrane pelletswere resuspended in isotonic binding buffer consisting of 10 mMNa₂HPO₄, 150 mM NaCl, 5 mM EDTA, and 0.02% NaN₃, pH 7.4. Proteincontent was subsequently determined using the Bradford proteinassay (3).

Radioligand. The ANG II antagonist ¹²⁵I-labeled [Sar¹,Ile⁸]ANG II was radioiodinated using the lactoperoxidase-glucose oxidase method and subsequentlypurified by HPLC on a C₁₈ reverse-phase column (32).

Receptor binding assays. Saturation binding studies were carried out by incubating 20 µg of freshly prepared placental membranes (45 or 130 day, n= 4 for each age) in the presence of increasing concentrations(1-12,000 pM) of ¹²⁵I-[Sar¹, Ile⁸]ANG II in binding buffer (10 mM Na₂HPO₄, 150 mM NaCl, 5 mM EDTA,0.02% NaN₃, 0.2% BSA, 0.5 mg/ml bacitracin, 100 µM PMSF, pH 7.4)for 1 h at 22°C. Nonspecific binding was determined in the presenceof 10 µM unlabeled ANG II. Free from bound radioligand was separatedby vacuum filtration through a cell harvester (Brandel) usingWhatman GF/B glass fiber filter paper (Whatman International)presoaked in 1% polyethylenimine. Ice-cold wash buffer consistingof 10 mM Na₂HPO₄, 150 mM NaCl, 5 mM EDTA, 0.02% NaN₃, pH 7.4,was used to wash the filter paper before the retained radioactivitywas measured using an automatic gamma counter (Packard, Meriden,CT). Triplicates were performed where all eight samples were studiedsimultaneously and the raw data were averaged and analyzed usingGraphPad Software, version 3.0 (San Diego,CA).

AT₁ and AT₂ levels were determined by incubating 30 µg of freshly prepared placental membranes with 0.5 µCi/ml of ¹²⁵I-[Sar¹, Ile⁸]ANG II in the presence of 1 µM PD 123319 (AT₂ receptor antagonist)or 1 µM candesartan (AT₁ receptor antagonist) for 1 h at 22°C.Nonspecific binding was determined in the presence of 1 µM ofcold ANG II. Free from bound radioactivity was then separatedusing the standard filtration method describedabove.

Statistical analyses. Data in different groups were measured by one-way ANOVA with all pairwise multiple comparison procedures (Tukey test). Alldata are reported as means ± SE, unless otherwise stated. Thelevel of significance for all tests was set at P < 0.05.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Quantitation of AT₁ and AT₂ gene expression. Five different placental ages were studied (27, 45, 66 ± 1, 100 ± 4, and 140 days of gestation) as well as 27-day intercaruncular(uterus between cotyledons) and adult kidney samples. All of thesamples studied were compared with the mean of one 140-day placentasample assayed four times. A statistically significant increasein AT₁ gene expression was detected in the 45-day cotyledon (12.2± 1.1) compared with the 27 (2.7 ± 0.24), 66 ± 1 (4.6 ± 0.17),100 ± 4 (1.9 ± 0.48), and 140 (1.1 ± 0.066) day cotyledons (Fig.1). AT₁ gene expression in the intercaruncular part of the uterusat 27 days of gestation (2.3 ± 0.67) was very similar to the 27-daycotyledon (2.7 ± 0.24). The adult kidney displayed a marked amountof AT₁ gene expression (8.5 ± 0.54) compared with most of theplacenta samples studied (P < 0.05). Only the 45-day cotyledonhad a greater amount of AT₁ gene expression (1.5-fold) comparedwith the adult kidney, although this comparison was not statisticallysignificant.

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Fig. 1. AT₁ gene expression in the placenta at 27, 45, 66 ± 1, 100 ± 4, and 140 days of gestation (open bars). Intercotyledonary uterus at 27 days of gestation (filled bar) and adult kidney (hatched bar) are also presented. Fold expression is relative to the 140-day placenta. Values are expressed as the means ± SE (n = 4, except for the 45-day placenta, where n = 6, and adult kidney, where n = 3). d, Day; R, receptor. * Statistically significant difference (P < 0.05).

The greatest amount of AT₂ gene expression was detected in the 45-day cotyledon (5.3 ± 1.6) compared with the 140-day cotyledon,although this was not significant (Fig. 2). Therefore, AT₂ geneexpression followed a similar pattern to that of AT₁. SimilarAT₂ mRNA levels were also observed in the 66 ± 1-day cotyledon(4.8 ± 0.93). Once again, at 100 ± 4 days of gestation (3.3 ±0.45), AT₂ gene expression was not significantly lower comparedwith the 45- and 66 ± 1-day cotyledons. The lowest levels of AT₂mRNA were observed in the 27 (0.36 ± 0.22)- and 140 (0.7 ± 0.29)-daycotyledons as well as the 27-day uterus (0.75 ± 0.39) and adultkidney (0.33 ± 0.19).

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Fig. 2. AT₂ gene expression in the developing placenta (open bars) at 27, 45, 66 ± 1, 100 ± 4, and 140 days of gestation (term = 145-150 days), as well as at 27 days of gestation in the intercotyledonary uterus (filled bar) and adult kidney (hatched bar). Fold expression is relative to the 140-day placenta. Values are expressed as the means ± SE (n = 4, except for the 45 day placenta, where n = 6, and adult kidney, where n = 3).

The fetal membranes, together with the placenta, at 66 ± 1, 100 ± 4, and 140 days of gestation were also studied for AT₁ andAT₂ gene expression (Fig. 3). The mean of 66 ± 1-day amnion samplesfrom four different animals was used as a calibrator in thesestudies. In support of the above findings, no statistically significantdifference in AT₁ mRNA content was observed between the 66 ± 1(2.3 ± 0.35)-, 100 ± 4 (1.1 ± 0.29)-, and 140 (0.61 ± 0.15)-daycotyledons (Fig. 3). A statistically significant increase in AT₁gene expression, however, was observed in the 66 ± 1-day chorion(3.23 ± 0.63) compared with the 140 (0.72 ± 0.37)-day chorionbut not the 100 ± 4-day chorion (1.7 ± 0.36) (Fig. 3). No statisticallysignificant change in AT₁ gene expression was observed betweenthe 66 ± 1 (0.63 ± 0.17)-, 100 ± 4 (1.4 ± 0.55)-, and 140 (0.57± 0.24)-day allantois groups as well as the 66 ± 1 (1.0 ± 0.0)-,100 ± 4 (0.67 ± 0.19)-, and 140 (0.35 ± 0.13)-day amnion groups(Fig. 3).

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Fig. 3. AT₁ (filled bars) and AT₂ (open bars) gene expression in ovine placenta and fetal membranes at 66 ± 1, 100 ± 4, and 140 days of gestation (term = 145-150 days). Fold expression was relative to the 66 ± 1-day amnion. Values are expressed as the means ± SE (n = 4, except 66 ± 1-day allantois, where n = 3). * Statistically significant difference (P < 0.05).

Once again, no statistically significant difference in AT₂ gene expression was observed between the 66 ± 1 (4.1 ± 1.1)-, 100± 4 (2.9 ± 0.31)-, and the 140 (1.8 ± 1.3)-day cotyledons (Fig.3). No statistically significant difference in AT₂ gene expressionwas observed between the 66 ± 1 (5.4 ± 1.4)-, 100 ± 4 (3.3 ± 0.86)-,and 140 (2.1 ± 0.55)-day chorion groups (Fig. 3). This also appliedto the allantois groups studied, where at 66 ± 1, 100 ± 4, and140 days of gestation, the levels of AT₂ gene expression were1.1 ± 0.18, 1.9 ± 0.87, and 1.8 ± 0.49, respectively (Fig. 3).No difference in AT₂ gene expression was observed between the66 ± 1 (1.0 ± 0.0)-, 100 ± 4 (2.5 ± 1.1)-, and 140 (2.7 ± 1.1)-dayamnion groups (Fig. 3). The 66 ± 1-day chorion displayed the greatestamount of AT₂ gene expression (Fig. 3) and a statistically significantdecrease (107-fold) was observed in the adult kidney (0.05 ± 0.025),where the lowest levels of AT₂ mRNA were found (data notshown).

Localization of AT₁ and AT₂ gene expression. Abundant levels of AT₁ gene expression were observed in the cotyledon at 41 and 51 days of gestation. AT₁ mRNA localizationwas observed in the maternal component of the cotyledon surroundingthe fetal villi (Fig. 4, A and C). AT₁ mRNA was also localizedin the blood vessels of the chorion at 140 days of gestation,where both the endothelial and smooth muscle cells demonstratedhybridization (see Fig. 6A). Earlier in gestation, little AT₁mRNA was present in the epithelial cells of the chorion (67 days)and none in the blood vessels (see Fig. 6E). Only sparse AT₁ receptorgene expression was observed in the 27-, 66 ± 1-, 100 ± 4- (datanot shown), and 140 (Fig. 4E)-day placenta, although still inthe maternal component of the placenta.

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Fig. 4. Dark-field (A, C, and E) and bright-field (B, D, and F) photomicrographs of tissue hybridized with the AT₁ riboprobe labeled with ³⁵S. Photomicrographs represent cotyledon samples at 41 (A and B; magnification, ×100), 51 (C and D; magnification, ×40), and 130 (E and F, magnification, ×100) days of gestation. Hybridization is clear in the maternal stromal cells of the cotyledon (C and D) surrounding the fetal villi (A and B). Insets in photomicrographs A, C, and E represent the corresponding sense slide. ft, fetal trophoblasts; ms, maternal stromal cells.

AT₂ mRNA localization was less prevalent in the placenta (Fig. 5). Gene expression was also confined to the maternal componentof the cotyledon although primarily adjacent to the fetal villi(Fig. 5, A and C). This part of the placenta is the syncytiumwhere fetal binucleate cells and uterine epithelial cells fuse,therefore establishing a fetomaternal hybrid tissue. AT₂ mRNAis clearly absent, however, in the fetal trophoblast cells (Fig.6A). Hybridization was also present in the blood vessels of thechorion, although, in contrast to the AT₁, gene expression wasonly present in the smooth muscle cells and not the endothelialcells (Fig. 6C). AT₂ mRNA was absent in the chorion early in gestation(65 days) (Fig. 6G) and this was also true for the 27-, 66 ± 1-,100 ± 4- (data not shown), and 140 (Fig. 5E)-day placenta.

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Fig. 5. Dark-field (A, C, and E) and bright-field (B, D, and F) photomicrographs of tissue hybridized with a ³⁵S-labeled riboprobe for AT₂. Photomicrographs represent cotyledon samples at 41 (A and B; magnification, ×100), 51 (C and D; magnification, ×40), and 130 (E and F, magnification, ×100) days of gestation. AT₂ gene expression is localized in the maternal stromal cells, close to the invading fetal villi (A-D). AT₂ mRNA is clearly absent in the fetal villi (A and B, open arrow). Insets in photomicrographs A, C, and E represent the corresponding sense slide. fv, fetal villi.

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Fig. 6. Dark-field (A, C, E, and G) and bright-field (B, D, F, and H) photomicrographs of tissue hybridized with AT₁ (A, B, E, and F) and AT₂ (C, D, G, and H) ³⁵S-labeled riboprobes. Photomicrographs represent chorion samples at 140 (A-D; magnification, ×200), 67 (E and F; magnification, ×100), and 65 (G and H, magnification, ×100) days of gestation. AT₁ mRNA was localized in the primary placental arteries of the chorion, where both endothelial and smooth muscle cells displayed hybridization (A and B). In photomicrographs C and D, AT₂ mRNA was localized in the smooth muscle cell layer of the primary placental arteries only. AT₁ gene expression was observed in the chorion early in gestation, primarily in the epithelial cells and not the blood vessels (E and F). AT₂ gene expression, however, was very low in the 65-day chorion (G and H). bv, Blood vessels.

Angiotensin receptor levels in the 45- compared with the 130-day placenta. Scatchard plots generated from saturation binding studies indicated significantly higher levels of total ANG II binding sitesin the 45 [maximal binding (B_max) = 1 fmol/µg of protein]- comparedwith the 130 (B_max = 0.252 fmol/µg of protein)-day sheep placenta(Fig. 7). ¹²⁵I-[Sar¹,Ile⁸]ANG II bound with similar affinity to both 45- and 130-day placentalmembranes with K_d values of 0.5 and 0.6 nmol, respectively. Theseresults clearly suggest a change in total ANG II binding sitesin the 45-day placental tissue rather then a change in affinityfor the radioligand. Incubation of 45- and 130-day placental membranesin the presence of specific AT₁ and AT₂ antagonists indicatedsignificantly higher AT₁ levels in the 45-day placental tissuethan AT₂ (Fig. 8), where a 1.8-fold difference was observed. Inthe 130-day placenta, AT₁ and AT₂ levels were approximately equal(Fig. 8). Again, ANG II binding was greater in the 45- comparedwith the 130-day placenta, where a statistically significant increasewas observed in the total and AT₁ and AT₂ binding samples, where4.5-, 5.8-, and 3.4-fold differences were observed, respectively(Fig. 8). Nonspecific binding was also low for both placentalages (Fig. 8).

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Fig. 7. Saturation ligand binding studies in the 45 (A)- and 130 (B)-day placenta, where the amount of ¹²⁵I-labeled [Sar¹,Ile⁸]ANG II binding is presented on the x-axis (pM) and counts/min (cpm) on the y-axis. Insets of Scatchard plots are also presented, where maximal binding (B_max) and K_d values were derived. Values are means ± SE of 4 different animals.

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Fig. 8. ¹²⁵I-[Sar¹,Ile⁸]ANG II binding in the 45 (open bars)- and the 130-day placenta (filled bars). Binding is presented on the y-axis as cpm. Total, AT₁ receptor, AT₂ receptor, and nonspecific binding are presented on the x-axis. Values are means ± SE of 4 different animals. * Statistically significant difference (P < 0.05).

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Summary of results. In this study, using the sensitive real-time PCR technique, gene expression for both AT₁ and AT₂ receptors was detected inall the ovine fetal membrane and placental samples studied. Astatistically significant increase in AT₁ gene expression wasobserved in the 45-day placenta compared with 27, 66 ± 1, 100± 4, and 140 days of gestation as well as the 66 ± 1-day chorioncompared with 100 ± 4 and 140 days of gestation. By in situ hybridizationhistochemistry, AT₁ and AT₂ mRNA was localized in the blood vesselsof the chorion later in gestation, whereas earlier in gestation,AT₁ mRNA only was localized to the epithelial cells. AT₁ and AT₂mRNA was observed early in the placenta (41-51 days of gestation),primarily in the maternal stromal cells rather than in the bloodvessels. Receptor ligand binding studies supported the above findingwhere greater levels of angiotensin receptors were observed earlierin gestation than late and that the predominant receptor was ofthe AT₁ subtype. Because the receptor ligand binding studies representedintracellular membranes also, and recent findings have identifiedintracellular ANG II (47, 56), the role of intracellular angiotensinreceptor function in the placenta cannot beexcluded.

Source of ligand. AT₁ and AT₂ receptors are responsible for mediating the effects of ANG II; however, adequate amounts of renin, angiotensinogen,and ACE are required for ANG II to be produced. All three of thesecomponents are made in early ovine fetuses, where Wintour andcoworkers (49) demonstrated that by 41 days of gestation, thelung, brain, and liver tissues contained angiotensinogen and ACEgene expression. The kidney also, constituting the meso- and metanephros,contained renin and angiotensinogen mRNA, as well as protein (49).In the pregnant ewe, plasma renin concentrations have been observedto increase to 60 days of gestation (50); however, it is onlyuntil mid-pregnancy that this increased renin activity is observed.No renin mRNA can be detected in ovine placental and fetal membranes(unpublished results), which is not surprising because the mainintrauterine source of prorenin in deciduate species (e.g., humans)is the maternal decidua and the sheep is nondeciduate. ANG-(1-7)is also increased in the fetus compared with the ewe and couldpotentially affect the placenta, because renin, AT₁, and AT₂ receptorgene expression levels increase in the fetal kidneys with ANG-(1-7)administration (37).

Studies on the AT₁ receptor in the sheep. In the ovine placenta, the AT₁ gene appeared to be expressed largely at 45 days of gestation and decreased thereafter to term,whereas at 27 days of gestation, levels were similar to late gestation.Zheng and coworkers (55) also studied AT₁ expression in thesheep placenta, although only at 130 days of gestation. By immunohistochemistry,AT₁ binding was observed in the caruncular and intercaruncularcomponents of the uterus, as well as the fetal component of thecotyledons. Microvessels in these components stained positivefor AT₁ receptors, which consisted of both smooth muscle and endothelialcells. In the fetal component of the cotyledon, staining was predominantlyin the trophoblast and binucleate cells lining the fetal villi.AT₁ staining was also localized in nonvascular cells of the placentaand uterus, which included the epithelium, stroma, and smoothmuscle cells of the myometrium (55). The distribution of AT₁in the fetal component of the sheep placenta differs from thatfound in this study, where AT₁ gene expression was strictly localizedto the maternal component of the placenta in the stromal cellsthroughout gestation, even at 140 days of gestation where littleexpression wasobserved.

AT₁ and AT₂ receptor species differences in the placenta. AT₁ mRNA, as well as protein, has previously been identified in the human placenta throughout pregnancy (7, 20, 28,40). RT-PCR was employed by Cooper and coworkers (7), andAT₁ gene expression was demonstrated in the first, second, andthird trimesters of human pregnancy, although these results werenot quantitative. This group also observed greater AT₁ immunoreactivityin the first and second trimesters of human pregnancy comparedwith term (7). Again in the human, AT₁ receptors have beenobserved in ANG II-induced human placental lactogen secretionin vivo (22). Thus, in the human and sheep, the highest expressionof AT₁ receptors occurs early tomidgestation.

Unlike in the sheep, AT₂ receptors predominate in the cow placenta throughout gestation as determined by autoradiography andreceptor binding studies by Schauser and coworkers (45). However,AT₁ receptors do exist in the cow placenta, and, as in this study,higher proportions of AT₁ receptors were observed early in gestation(45). The primary difference between the sheep and cow placentais the distribution of the AT₂ receptors, where localization ispredominantly in the fetal component (45). However, AT₁ receptorswere primarily localized on the maternal side, similar to thesheep (45). Therefore, the localization of the AT₁ in the maternalcomponent of the sheep placenta is in agreement with the cow andhuman studies performed by others (7, 28, 45). Earlierstudies also demonstrated the presence of both AT₁ and AT₂ receptorsin the placenta of guinea pigs and rabbits (21, 23), althoughonly AT₁ receptors in the placenta of rats (13).

Differences in AT₂ mRNA and protein distribution have been reported in the placenta of other mammals also. Zero to ten percentof the angiotensin receptors have been classified as the AT₂ typein the human placenta (20, 25), where Cooper and coworkers(7) also identified no AT₂ gene expression by RT-PCR in thefirst, second, and third trimesters of human pregnancy. Again,no immunoreactive AT₂ labeling was observed at each of the threestages of pregnancy (7), although Li and coworkers (28) previouslydemonstrated little AT₂ binding in the human placenta at term.In the pig placenta, much higher AT₂ levels have been observedthroughout gestation compared with the AT₁ (38). This is alsotrue in the rabbit at term (23) and at midgestation in the rat(13). Probably due to the sensitivity of the real-time PCR techniquein this study, the sheep possessed detectable levels of AT₂ receptorgene expression throughoutgestation.

The differences in AT₁ and AT₂ receptor distribution between the bovine and ovine placentae is interesting because both sheepand cows are ruminants, and the sheep placenta resembles the humanin that predominantly AT₁ receptors exist, although in all threespecies, the level of AT₁ receptors do predominate early in gestation,unlike in the pig. Therefore, the distribution of AT₁ and AT₂receptor subtypes varies among different species, suggesting thatthe RAS may perform different functions in placentae of differentanimals (Table 1).

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Table 1. AT₁ and AT₂ receptors in the placenta of different mammals during early and late pregnancy

AT₁ and AT₂ receptors in fetal membranes. In the human, significant amounts of AT₁ receptors have been noted in the amnion and predominantly AT₂ receptors in the chorion(21). Previously, few ANG II receptors were reported in boththe human amnion and chorion by others (15). In the cow, AT₂receptors are predominant in fetal membranes, similar to the mRNAfindings in this study compared with AT₁ receptor mRNA levels,where they have been localized in the mesenchyme cells adjacentto the trophoblast cell layer and surrounding arteries (45).Fewer AT₁ ligand binding sites were localized in these regions(45). AT₂ ligand binding was most dominant in the allantochorionicmembrane of the cotyledon and also at the fetal side on the mesenchymalcells (45). No AT₁ or AT₂ ligand binding was detected on theallantoic endoderm and trophoblast cells or the binucleate andtrinucleate cells in the trophoblast cell layer and maternal uterineepithelium (45).

Uterus. Little AT₁ and AT₂ gene expression was detected in the 27-day uterus by real-time PCR. AT₁ and AT₂ ligand binding studieswere previously performed in late gestation ovine uteri, whereonly AT₁ receptors were identified in the myometrium (35). Contraryto this, AT₂ receptors were found to be more abundant in the myometriumin nonpregnant sheep, where lower levels of both AT₁ and AT₂ receptorswere detected in the endometrium (35). In the human, however,AT₂ receptors were found to decrease in the myometrium as pregnancyproceeded (31); therefore, few are found near term such as inthe sheep. Most of the angiotensin receptors in the human endometriumhave also been classified as the AT₂ type during pregnancy (2).AT₁ receptors have only been localized in the glandular and vascularepithelial cells of the human endometrium (44). Overall, differencesexist in the distribution of the AT₁ and AT₂ receptors in uteriduring pregnancy among the different mammals studied todate.

Mediating effects of angiotensin receptors on growth. In this study, a significant increase in AT₁ mRNA at 45 days of gestation coincided with the period of maximum placental growth.Therefore, the AT₁ receptor may play a key role in ovine placentalgrowth/differentiation and/or function. It is generally acceptedthat ANG II, via the AT₁ receptor, promotes cell growth, whereasthe AT₂ receptor mediates antiproliferation and apoptosis as determinedin rat coronary endothelial, rat PC12W, and mouse R3T3 cells (46,54). This AT₁ receptor mitogenic effect has been demonstratedin cell types such as rat vascular smooth muscle cells and chickcardiac myocytes (1, 11). Other studies in mice also supportedthe opposing effects of the two receptor subtypes and that a functionalinteraction may exist (17). A cross-talk mechanism was subsequentlysuggested to exist between these two receptor subtypes, as determinedin rat catecholaminergic neurons (12). Recently, however, growth-promotingeffects of the AT₂ receptor have been suggested from rat opticnerve studies (29).

Perspectives

The major original finding in the current study is that AT₁ receptors are most highly expressed in the sheep placenta in thefirst third of pregnancy. It is now appreciated that ACE inhibitorsare contraindicated in pregnancy, but the main concern has beento avoid them in the second and third trimesters of pregnancy(24). This is largely attributed to the effects on the fetalkidney, in which ANG II is essential to maintain normal perfusionand urine flow (30) and the consequent anuria results in oligohydramniosand lung hypoplasia. However, more recent reports on the use ofspecific AT₁ antagonists from conception have indicated that thesemay also be associated with more serious toxic effects on thefetus (4). In the case reported by Briggs and Nageotte (4),intrauterine death occurred at 33 wk when the drug valsartan wasstopped at 24 wk of gestation. Interestingly, the placenta wasextremely small in weight (48% of the 10th percentile for gestationalage). RAS is also important early in gestation, particularly becauseelevated levels of prorenin are found in gestational sac fluid(18) and the placenta (10) in humans. These findings thatthe AT₁ receptor is highly expressed early in pregnancy in thematernal stroma of the ovine placenta, when maximal growth ofthe placenta occurs, suggest that ANG II, via the AT₁ receptor,may play a vital role in the growth/function of the placenta inthisspecies.

	ACKNOWLEDGEMENTS

The authors thank M. Goga for excellent technical assistance with the receptor ligand binding studies and K. Johnson for technicaladvice during the generation of the in situ hybridization histochemistryphotomicrographs. Dr. J. Burrell and Prof. E. Lumbers are alsothanked for technical advice with the receptor ligand bindingstudies.

	FOOTNOTES

The purchase of the ABI PRISM 7700 Sequence Detection System was possible due to funding from the following foundations: theClive and Vera Ramaciotti Foundation, the Harold and Cora BrennenBenevolent Trust, the Phillip Bushell Foundation, and the Sylviaand Charles ViertelFoundation.

Address for reprint requests and other correspondence: M. Wintour, Howard Florey Institute of Experimental Physiology andMedicine, The Univ. of Melbourne, Victoria 3010, Australia (E-mail:mwc{at}hfi.unimelb.edu.au).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.Section 1734 solely to indicate thisfact.

10.1152/ajpregu.00070.2002

Received 4 February 2002; accepted in final form 20 June 2002.

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