1 University Departments of Obstetrics and Gynaecology, Queen Mother's Hospital, Yorkhill, Glasgow G3 8SJ, 2 Medicine and Therapeutics, Western Infirmary, Glasgow and 3 Obstetrics and Gynaecology, The Rosie Hospital, Cambridge, UK
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Abstract |
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Key words: cardiovascular disease/hormone replacement therapy/menopause/nitric oxide/oestrogen
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Introduction |
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The mechanisms underlying apparently favourable effects of estrogen on the cardiovascular system (Ross, 1993; St Clair, 1997
) are incompletely understood. Although they have commonly been attributed to changes in primary cardiovascular risk factors resulting in beneficial changes in lipid profiles (Bush et al., 1987
; Stevenson et al., 1993
), a number of other biological effects have also been proposed. These include changes in glucose and insulin metabolism (Walton et al., 1993
), body fat distribution (Ley et al., 1992
), coagulation and fibrinolysis (Winkler, 1992
) and in addition vascular endothelial function (Farhat et al., 1996
).
The endothelium produces a plethora of vasoactive mediators, including prostaglandins, endothelins, angiotensin II, adrenomedullin and nitric oxide (NO). In the present study, we were interested in the effects of estrogen on NO as there is now evidence from both animal (Wennmalm, 1994; Gislard et al., 1998
) and human (Hayasha et al., 1992
, Herrington et al. 1994
) studies that estrogen may be capable of acting via the L-arginine/NO pathway. Nitric oxide, synthesized constitutively by the endothelial isoform of the enzyme NO synthase (eNOS), and released by the vascular endothelium (Guetta et al., 1997
), is thought to protect against the development of atherosclerosis by a number of mechanisms including maintaining vascular tone, preventing platelet aggregation and inhibiting smooth muscle cell proliferation (Vallance and Collier, 1994
).
Estrogen acts principally by binding to specific nuclear receptors, which influence downstream events modulating gene expression. Until recently, only a single major form of the estrogen receptor (ER) had been identified (Greene et al., 1986
); however, a second protein encoding a separate subtype (ERß) has now been identified (Mosselman et al., 1996
; Enmark et al., 1997
). The ß receptor is smaller than the
receptor although there is similar conservation of amino acid sequences suggesting similar modes of action despite differing in their distribution and affinity for estrogen. Recent evidence suggests that estrogen receptors are not confined to the reproductive system, with differential expression of the receptor subtypes in a variety of tissues. ER
is found principally in the reproductive tissues (uterus, breast and ovaries), liver and central nervous system, whereas ERß is found primarily in blood vessels, bone, and urogenital tissues with some expression in the ovary and central nervous system, which may explain the selective actions of estrogen in target tissues. The presence of estrogen receptors in vascular tissues was originally inferred by a number of animal studies which demonstrated specific binding of estrogen to vascular cells (Colburn and Buonassisi, 1978
; Nakao et al., 1981
; Horwitz and Horwitz, 1982
). Subsequently, functional estrogen receptors have been identified in a variety of vascular tissues including vascular smooth muscle and endothelial cells (Karas et al., 1994
; Venkov et al., 1996
), supporting a receptor-dependent action. However, estrogen-mediated vascular effects have also been reported which are independent of the estrogen receptor (Austin, 2000
).
The aims of this study were: (i) to examine the effect of estrogen on basal endothelial NO production by examining the forearm vasoconstrictor responses to intrabrachial NG- monomethyl-L-arginine (L-NMMA), a substrate inhibitor of nitric oxide synthase (NOS), in healthy post-menopausal women before and after transdermal 17ß-estradiol (E2) therapy; and (ii) to examine the effect of acute (24 h) and chronic (7 days) E2 (10 pmol/l and 10 nmol/l) treatment on endothelial NO messenger RNA (eNOS mRNA) expression in cultured human aortic endothelial cells using Northern analysis. In addition, the estrogen receptor status of the cells was determined using RTPCR to amplify ER and ERß mRNA.
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Materials and methods |
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Thirteen post-menopausal women (FSH >30 IU/l) were recruited either following total abdominal hysterectomy and bilateral salpingo-oophorectomy for a benign indication (n = 8) or by advertisement locally (n = 5). The women who participated were non-obese, had no personal history of cardiovascular disease, hypertension or diabetes mellitus, had no contraindications to E2, and were deemed to be fit on the basis of physical examination, ECG and routine haematological and biochemical screening investigations, including standard hormone assays. The pre-HRT study was conducted at 36 weeks post-operatively, to allow for stabilization of gonadotrophins and other metabolic processes, without unnecessarily delaying the relief of symptoms. Women who were previous HRT users (n = 3) were asked to discontinue their HRT (Trisequens; Novo Nordisk) for 4 weeks prior to the initial assessment. All women attended for two identical study days 4 weeks apart, before and after 4 weeks administration of transdermal E2 (80 µg) (Fematrix 80; Solvay Healthcare Limited, Southampton, Hants, UK). Women were asked to fast from midnight on the evening prior to each study day, and to avoid caffeine-containing beverages in the preceding 24 h. Body mass index (BMI) and baseline measurements of pulse and blood pressure were recorded using an automated blood pressure monitoring device (Dinamap; Critikon, Tampa, FL, USA) after resting supine for 5 min. Circulating estradiol concentrations were measured using a chemiluminescence method (Immulite; DPC, Glyn Rhonwy, Wales).
Forearm blood flow (FBF) during intra-arterial (brachial) infusion of L-NMMA was measured by bilateral forearm venous occlusion plethysmography using standard protocols as previously described by our group (Petrie et al., 1998). After 30 min of stabilization (saline infusion), two sets of measurements at 10 min intervals were used as a measurement of baseline FBF. Ascending doses of L-NMMA (2, 4, 8 µmol/min) were then infused for periods of 7 min each. Blood flow measurements were recorded over a 3 min period commencing 3 min from the start of each infusion.
Forearm blood flow was derived from the gradient of the plethysmographic trace according to a published method (Whitney, 1953). Each blood flow measurement was the mean of five sequential recordings. Co-ordinates of data points were acquired using MacChart software (AD Instruments) and pasted into a customized spreadsheet (Microsoft Excel). Data were expressed as the percentage change in FBF ratio from baseline. A mean response across doses was used as a summary measure.
Study 2. In-vitro study using cultured human aortic endothelial cells
Human aortic endothelial cells (HAEC) were purchased from Clonetics Inc. (UK supplier: TCS Biologicals, Claydon, Buckinghamshire, UK), and cultured in growth medium (Clonetics) following standard protocols as previously described by our group (Devlin et al., 1998). Cells were initially recovered and grown in 25 cm2 flasks. Cells were characterized as endothelial cells on the basis of positive immunostaining with antibodies specific for von Willebrand factor and also on the basis of morphology (Wagner et al., 1982
; Polak and Van Noorden, 1996
).
Total RNA was extracted from the cells using RNAzol B (Biogenesis Ltd., Poole, Dorset, UK) (Chomczynski and Sacchi, 1987). The integrity of the RNA was demonstrated by ethidium bromide stained agarose gel electrophoresis and the RNA yield was quantified spectrophotometrically using an Ultraspec 2000 UV/Visual Spectrophotometer (Pharmacia Biotech, St Albans, Herts, UK).
RTPCR was carried out using 2.6 µg of RNA and primers specific for ER and ERß cDNA. The primers for ER
nested RTPCR have recently been described (McLaren et al., 1996
). Primer 1 (GGAGACATGAGAGCTGCCAA) and primer 4 (TCATCATGCGGAACCGAGAT) were used for the first round and primer 2 (CCAGCAGCATGTCGAAGATC) and primer 3 (CTTTGGCCAAGCCCGCTC) for the second round. First round PCR profile: 95°C, 1 min (95°C, 30 s; 60°C, 30 s; 72°C, 30 s)x20 cycles, 72°C, 3 min. The product of the first round was diluted 1:20 for the second round reaction, performed with the following profile: 95°C, 1 min (95°C, 30 s; 58°C, 30 s; 72°C, 30 s)x20 cycles, 72°C, 3 min. Primers for ERß were designed from the published sequence [primer 1, TTACAGCATTCCCAGCAATG; primer 2, GAACCTGGACCAGTAACAG; 95°C, 1 min (95°C, 30 s; 56°C, 30 s; 72°C, 30 s)x30 cycles, 72°C, 3 min] and the amplified product verified by cloning and sequencing.
Using 10 mg of RNA, Northern blots were prepared according to a standard glyoxalation method previously described by our group. Human eNOS (pHu NOS endo PM831221) (Marsden et al., 1992) and glyceraldehyde-3-phosphate dehydrogenase (GAPDH; internal control) probes were prepared using a random priming kit (Gibco, Life Technologies, UK) with radiolabelled dCTP as previously described (Devlin et al., 1998
). After probing, blots were exposed to radiographic film (Kodak X-Omatic) overnight, and subsequently scanned into a Biorad Phosphoimager (Biorad, UK, Hemel Hempstead, Herts, UK). The eNOS mRNA signal was then quantified densitometrically with respect to GAPDH by outlining the band to be measured, selecting a volumetric integration of the area defined, and expressing the signal in relation to the background density.
The effect of acute and chronic E2 treatment on eNOS mRNA levels was determined following exposure of the cells (passages 36) to 10 pmol/l and 10 nmol/l concentrations of soluble E2 (Sigma, Poole, Dorset, UK) for 24 h and 7 days, prior to Northern analysis and probing with a human eNOS probe (pHu NOS endo PM831221) (Devlin et al., 1998). The results of five separate experiments performed under identical conditions are presented.
Unless otherwise indicated, results are expressed as mean ± SD. Statistical significance was assessed using the Student's t-test. P < 0.05 was considered statistically significant.
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Results |
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Discussion |
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Basal release of NO from the vasculature is generally greater in vessels from female animals than in those from males, suggesting that female sex hormone status is important in regulation of basal vasomotor tone (Sudhir et al., 1996). A cyclical variation in expired NO production in women, with levels peaking in the middle of the menstrual cycle, is also highly suggestive of an influence of gonadal hormones on the synthesis and release of NO (Kharitonov et al., 1994
).
The vascular response to estrogen depends on the animal species and also the vascular bed studied. Oestrogen induces endothelium-dependent relaxation of vessels. Oestrogen facilitates the normal vasodilator response to acetylcholine (ACh) in rabbit femoral arteries (Gislard et al., 1998) and in porcine coronary vessels (Bell et al., 1995
). Acute (Williams et al., 1990
) and chronic (Williams et al., 1992
) oestrogen administration attenuates or reverses the vasoconstriction effect of ACh in ovariectomized cynomolgus monkeys with coronary atherosclerosis.
In humans, there is also a suggestion of a role for the endothelium in the mediation of estrogen-induced vessel relaxation. Studies of the coronary vasculature have shown that estrogen attenuates or abolishes ACh-induced vasoconstriction when administered acutely in post-menopausal women with angiographically proven coronary artery disease (Reis et al., 1994; Collins et al., 1995
). Similar responses to acute intracoronary E2 have been reported in post-menopausal women in healthy coronary vessels (Gilligan et al., 1994
). The response of coronary arteries is also gender dependent, with evidence of E2-induced modulation of ACh-induced coronary artery responses of female but not male atherosclerotic coronary arteries (Collins et al., 1995
). Studies of the peripheral vasculature, most commonly the forearm, have also reported beneficial effects of estrogen on vascular reactivity. A study of 40 post-menopausal women, of whom half had risk factors for vascular dysfunction, assessed forearm vascular responses to the endothelium-dependent vasodilator ACh, before and during intra-arterial infusion of E2. Potentiation of the vasodilator response to ACh in both healthy and potentially diseased blood vessels (Gilligan et al., 1994
) occurred following the E2 administration. Similar findings have been reported using forearm plethysmography. The response to an intra-arterial infusion of ACh was augmented after 3 months of estrogen replacement therapy (50 µg transdermal estradiol), in a small group of women (10 subjects) after bilateral oopherectomy (Pinto et al., 1997
). Endogenous estrogen deprivation following bilateral oophorectomy resulted in a reduction in ACh-induced vasodilation compared with baseline, but this was subsequently restored by estrogen supplementation. In contrast to these findings, a small randomized double-blind, placebo-controlled study, also examining FBF using venous occlusion plethysmography, showed no evidence of any alteration in the vasodilator responses to ACh following estrogen supplementation (2 mg estradiol valerate daily for 8 weeks duration) (Sudhir et al., 1996
). However, enhanced vasoconstrictor response to the NO synthase inhibitor L-NMMA was observed, suggesting that there was enhanced basal NO release in the forearm vasculature of peri-menopausal women following estrogen supplementation.
There are several reasons for the difference between the results of the present study and the previously documented studies. One possible explanation for these differences may be the route of administration of estrogen. Transdermal estrogen avoids any first pass metabolism, whereas oral E2 passes from the gut directly to the liver via the portal circulation giving high local concentrations, which profoundly affect hepatic metabolism. Hence any indirect effects of estrogen on endothelial function mediated by changes in hepatic lipid metabolism will be much greater. Although this study did not demonstrate an effect of transdermal estrogen in the forearm vascular bed, it clearly does not exclude an effect of estrogen on the forearm vasculature if delivered by an alternative route, or indeed an effect on a different vascular bed when delivered by the same route.
An up-regulation of eNOS protein levels in response to E2 has been observed in human aortic endothelial cells using Western blotting (Hayashi et al., 1995). In this study, the level of eNOS protein was determined after short (8 h)- and long (48 h)-term pre-treatment of cells prior to measurement of calcium-stimulated (ionomycin) NO production. Similar findings have been observed in human umbilical vein endothelial cells and bovine aortic endothelial cells (Hishikawa et al., 1995
). These investigators reported an increase in eNOS protein using Western blot analysis following estrogen pre-treatment for a minimum of 8 h, an effect which was inhibited by addition of the estrogen receptor antagonist tamoxifen. These effects were consistent in both of the cell populations studied. These findings suggest an involvement of the classic estrogen receptor ER
, a hypothesis which is supported by observation that knock-out mice lacking ER
have reduced NO production (Freay et al., 1995
). More recently, another group demonstrated that estrogens increase transcription of the human eNOS gene and has suggested that this may be mediated as a consequence of enhanced activity of transcription factor Sp 1 (Kleinert et al., 1998
).
This study examined eNOS mRNA expression in human endothelial cells following incubation with E2 using RNase protection assays. They also examined eNOS protein levels using Western blotting techniques. However, in the present study we were unable to detect any up-regulation of the human eNOS gene in cultured human endothelial cells. As with previous studies (Venkov et al., 1996) we have confirmed the presence of mRNA for both ER
and ERß receptors in human endothelial cell cultures, suggesting that our negative findings are not a result of low or absent estrogen receptor expression.
As in the present study, another team (Arnal et al., 1996) did not find a role for eNOS in the cardioprotective effect of estrogen; rather, they found an increase in the expression of the superoxide dismutase (SOD) gene, which, by scavenging the free radical superoxide, would improve vascular compliance by preventing the scavenging of NO.
In summary, the results of our present studies do not provide evidence for a role for an eNOS-mediated cardioprotective response to estrogen. Alternative cellular mechanisms whereby estrogen can protect the vascular system may include a role in preventing apoptosis, by inhibiting mitogen actuated protein (MAP) kinase, reducing levels of cytokines such as tumour necrosis factor- or by acting as a free radical scavenger; however, a great deal of estrogen cellular and molecular biology remains to be elucidated.
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Notes |
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References |
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Submitted on July 24, 2001; accepted on March 14, 2002.