Hormone replacement therapy and cardiovascular disease: lessons from a monkey model of postmenopausal women

Concerns exist about the cardiovascular effects of hormone replacement therapy (HRT) in postmenopausal women because results from the Women's Health Initiative (WHI) and the Heart and Estrogen/Progestin Replacement Study (HERS) are contradictory. In both of these studies, postmenopausal conjugated equine estrogens + medroxyprogesterone acetate did not reduce risk, and somewhat increased the risk of myocardial infarction in both primary (WHI) and secondary (HERS) prevention. These results appear to contradict numerous observational clinical trials and animal studies, which reported profound beneficial effects of HRT on cardiovascular disease risk. Results of both human and monkey studies indicate that estrogen replacement therapy (ERT)/HRT is effective in inhibiting progression of early stage (fatty streak) atherosclerosis but that ERT/HRT is much less effective in inhibiting progression of more advanced (established plaque) atherosclerosis. Results of these monkey studies are consistent with those of studies in women wherein ERT/HRT was initiated in postmenopausal women with different initial amounts of atherosclerosis. Based on these findings, it is speculated that ERT/HRT may be more cardioprotective in younger postmenopausal women with less coronary artery disease, and less effective in women with established coronary artery disease. Researchers are challenged to define the relative cardiovascular risk/benefit in different populations of postmenopausal women based on differences in age, amounts of pre-existing atherosclerosis, and risk factors.     

Nomegestrol acetate and vascular reactivity: nonhuman primate experiments

Prevention of coronary artery disease has been recognized as a major benefit of estrogen replacement therapy (ERT) in postmenopausal women. However, endometrial hyperplasia induced by unopposed ERT has raised important safety concerns. Progesterone or synthetic progestins have been used in combined hormone replacement therapy (HRT) to prevent endometrial cancer risk. Therefore, a major concern has been to ensure that the vascular beneficial effects of estrogens are not opposed when combined with progestins. Nomegestrol acetate (NOMAC) is an orally active progestin widely prescribed for HRT. Its vascular effects were evaluated in two models of coronary vascular reactivity in primates: 1) the paradoxical vasoconstriction to acetylcholine (Ach) coronary infusion after 5 months of mildly atherogenic diet in ovariectomized (OVX) Cynomolgus monkeys and 2) the pharmacologically evoked coronary vasospasm in the OVX Rhesus monkey. In the first model, after 3 months of continuous oral administration in the diet at 0.1 mg/kg/day, E2 prevented the paradoxical response to Ach, alone as well as combined with 0.25 mg/kg/day NOMAC, whereas NOMAC counteracted the endometrial stimulation. In the second model, after one artificial cycle consisting of 28 days of E2 subcutaneous (s.c.) implant and of daily oral gavage with 1 mg/kg/day of NOMAC for the last 14 days, no vasospasm (0 of 11 tested animals) occurred when the complete challenge protocol, including serotonin and the thromboxane agonist U46619, was administered to OVX Rhesus monkeys. In the balanced crossover design, identical artificial cycles with medroxyprogesterone acetate (MPA) at the same dose resulted in 7 vasospasms in 12 animals. In parallel, effective progestative activity was demonstrated by a secretory pattern in endometrial sections obtained at the end of the cycle. In these two nonhuman primate cardiovascular models, NOMAC did not have the negating effects observed with MPA.     

Serum Lipoprotein(a) Dynamics before/after Menopause and Long-term Effects of Hormone Replacement Therapy on Lipoprotein(a) Levels in Middle-aged and Older Japanese Women.

AIM: To assess lipoprotein(a) Lp(a) dynamics before and after menopause and to examine long-term changes during hormone replacement therapy (HRT) in middle-aged and older Japanese women. METHODS: (1) Serum total cholesterol, low-density lipoprotein cholesterol, high-density lipoprotein cholesterol, and Lp(a) concentrations of 526 patients were compared. The patients were divided into 3 groups on the basis of menopausal status (premenopause, perimenopause, postmenopause). (2) Serum markers of lipid metabolism were measured at baseline and at 6-month intervals in 161 postmenopausal women who continuously received HRT with conjugated equine estrogen (CEE) and medroxyprogesterone acetate (MPA) for 4 years. (3) Changes in serum concentrations of markers were compared among 120 women with hypercholesterolemia who were randomly assigned to receive HRT (CEE plus MPA, or transdermal estradiol plus MPA) or pravastatin. RESULTS: (1) Lp(a) concentrations were significantly higher in the postmenopausal women than in the premenopausal or perimenopausal women. (2) The mean Lp(a) concentration after 6 months of HRT decreased by about 19%, and similar levels were maintained for 4 years (3). The mean Lp(a) concentration after 6 months of HRT decreased by 19.9% in the CEE plus MPA group, but did not change significantly in the transdermal estradiol plus MPA group or the pravastatin group. CONCLUSION: Our results suggest that HRT with CEE plus MPA is useful for the management of elevated serum Lp(a) concentrations in middle-aged and older women. However, follow-up studies are needed to determine whether this finding is related to the future prevention of coronary heart disease events.     

Progestins and estrogens and Alzheimer's disease

Sex-specific incidence rates for Alzheimer's disease (AD) are higher in women than men. Many fundamental researches and some clinical investigations have reported therapeutic and preventive effects of estrogens on AD. But WHIMS [S.A. Shumaker, C. Legault, S.R. Rapp, L. Thal, R.B. Wallace, J.K. Ockene, S.L. Hendrix, B.N. Jones IIIrd, A.R. Assaf, R.D. Jackson, J.M. Kotchen, S. Wabertheil-Smoller, J. Wactawsk-Wende, WHIMS investigators, Estrogen plus progestin and the incidence of dementia and mild cognitive impairment in postmenopausal women. The women's health initiative memory study: a randomized controlled trial, JAMA 289 (2003) 2651–2662], which used daily continuous hormone replacement therapy (HRT), reported that the hazard ratio of the HRT for probable dementia was 2.05.

Effect of progestins, and continuous (not cyclically) HRT, even only with estrogen should be reconsidered.

In our clinical study, conjugated equine estrogen (CEE) alone showed good changes of psychiatric tests for AD on the 3rd week, but addition of medroxyprogesterone acetate (MPA) or norethindrone since 4th week suppressed these tests. Using human umbilical vein epithelial cell (HUVEC), levonorgestrel (LNG), norethindrone acetate (NETA), MPA increased intercellular adhesion molecule-1 (ICAM-1), vascular cell adhesion melocule-1 (VCAM-1) and E-secretin but dienogest (DNG) showed no effect. In vitro flow system, estradiol (E₂), suppressed adhesion of white cell, but LNG, NETA, MPA increased the adhesions. DNG showed less effect.

Non-feminizing estrogen J 861, which has Δ8,9 double bond and straight in its structure and has less effect on sexual organs. J 861 has shown ameliorative effects on central nervous system (CNS) (increasing of cholineacetyltransferase immunoreactive cells in substantia innominata (SI), etc.) like E₂.

More investigations about progestins and estrogens and AD should be done.     

Estrogens, progestins, and coronary artery reactivity in atherosclerotic monkeys

It has been known for many years that sex hormones modulate vasodilator responses of arteries supplying the uterus with blood. Recently, it has been shown that sex hormones such as estrogen modulate vasomotor responses of other arteries, including coronary arteries. It is thought that modulation of vasodilator and constrictor responses of coronary arteries may be one mechanism by which estrogen affects the risk of coronary heart disease. Although several studies have examined the effects (and potential mechanisms) of estrogen on vasodilator responses of nonatherosclerotic arteries, few have focused on estrogen's effects on atherosclerotic coronary arteries. In studies of ovariectomized atherosclerotic female cynomolgus monkeys, both long-term (2 years) and short-term (20 min) estradiol treatment augments dilator responses to acetylcholine, but not nitroglycerin. Presumably, this indicates an effect of estradiol on endothelium-mediated dilator responses of coronary arteries. Addition of the progestin medroxyprogesterone acetate diminishes the beneficial effect of conjugated equine estrogens on these dilator responses. This is significant because a progestin is usually added to estrogen replacement to reduce the risk of endometrial and breast cancer associated with unopposed estrogen therapy. However, it would seem that not all progestins act similarly on vascular reactivity. Studies in monkeys indicate that addition of progesterone or the progestin medroxyprogesterone acetate does not diminish the beneficial effects of estrogen on coronary dilator responses. Thus it would appear that different estrogen/progestin combinations may affect vascular reactivity in different manners, There is also an effort being made to examine the potential of different kinds of estrogens on cardiovascular risk. Studies in monkeys indicate that one of the estrogens found in conjugated equine estrogens (17 alpha-dihydroequilenin) has estrogen effects on vascular reactivity without having detrimental effects on uterine pathology. The isoflavones “plant estrogens” found in soy protein also have estrogenic effects on vascular reactivity and inhibition.     

Hormone replacement therapy increases renal kallikrein excretion in healthy postmenopausal women

Hypertension and its related increase in cardiovascular morbidity in postmenopausal women is a major public health problem. The hypotensive property of urinary kallikrein has been described since 1909. Despite the controversy surrounding the effects of hormone replacement therapy on blood pressure regulation, its mechanisms remain incompletely understood, and no evidence has yet been provided for its effects on renal kallikrein excretion in postmenopausal women. In a double-blind, randomized study we examined the effects of hormone replacement therapy in the form of 2 mg 17-beta estradiol (ERT) or 2 mg 17-beta estradiol combined with continuous 5 mg medroxyprogesterone acetate (HRT) on urinary kallikrein excretion in postmenopausal women. Thirty-nine postmenopausal women collected their urine for 24 hours on two separate occasions 3 months apart. During the 3 month period women were randomized to placebo, ERT, or HRT. Urine samples were assayed for kallikrein activity, normalized to urine creatinine and expressed as mU/gm creatinine. Urinary kallikrein excretion increased significantly after 3 months in the ERT (p < 0.001) and HRT (p < 0.01) groups, and decreased non-significantly in the placebo group (p > 0.06). There were no significant blood pressure changes after 3 months of therapy. The findings demonstrate that hormone replacement therapy in the form of estrogen or estrogen combined with continuous medroxyprogesterone is effective in increasing urinary kallikrein excretion. Given that a decrease in kallikrein excretion may mark risk for development of hypertension, the findings of this study are of value in demonstrating a novel mechanism underlying cardioprotective properties of postmenopausal hormone replacement therapy in women without pre-existing coronary disease.     

Progestins in the menopause

While the benefits of progestin use in hormone replacement therapy (HRT) are well recognised as far as endometrial protection is concerned, their risks and drawbacks have generated controversial articles. The data related to the progestin effect on breast tissue has been interpreted differently from country to country. However it has been admitted that, according to the type of progestin used, the dose and duration of its application, a predominant antiproliferative effect is observed in the human breast cells. As far as breast cancer risk is concerned, most epidemiological studies do not suggest any difference between the estrogens given alone or combined to progestins in HRT. When the cardiovascular risk factors are considered, some molecules with a higher androgenic potency than others, attenuate the beneficial effects of estrogens on the lipid profile and the vasomotion as well. On the other hand, other progestins devoid of androgenic properties do not exert these deleterious effects. The epidemiological data does not suggest any negative effect of the progestins administered together with estrogens on cardiovascular morbidity or mortality.

However, recent results suggest that in women with established coronary heart disease (CHD), HRT may not protect against further heart attacks, when the progestin selected possesses androgenic properties.

Complying with the classic contra indications of HRT and selecting molecules devoid of estrogenic, androgenic, or glucocorticoid effect should allow a larger use of the progestins without any major drawback.     

Progestins and cardiovascular risk markers

Several risks are attributed to progestins as a class-effect; however, the progestins used in hormone replacement therapy (HRT) have varying pharmacologic properties and do not induce the same side effects. Natural progesterone (P) and some of its derivatives, such as the 19-norprogesterones, do not exert any androgenic effect and, hence, have no negative effect on the lipids. On the other hand, the 19-nortestosterone derivatives and even some 17-hydroxyprogesterones have a partial androgenic effect, which may explain some of the negative effects observed on surrogate markers of cardiovascular risk. The relevance of the lipid changes induced by sex steroids has been questioned, and studies in the female cynomolgous monkey have not shown a direct relationship to atherosclerosis. Results suggest that estrogens (E) have antiatherogenic effects and that P does not reverse the beneficial effect of estradiol. Also, sex hormones modulate the vasomotor response of the main arteries. E preserves the normal endothelium-mediated dilation of coronary arteries, and P does not reverse this potential cardioprotective mechanism. In the same animal model, the addition of cyclic or continuous medroxyprogesterone acetate (MPA) to E inhibited vasodilatation by 50%, while nomegestrol acetate did not diminish the E-induced vasodilatation. Not all progestins act similarly on vasomotion or affect cardiovascular risk factors in the same way. Progestins, such as MPA or norethisterone acetate (NETA), exert a partial detrimental effect on the beneficial actions of estrogens with regard to lipid changes, atheroma development, or vasomotion. In contrast, progesterone itself does not have this inhibitory effect on lipid changes and vascular reactivity in animal models or on exercise-induced myocardial ischemia in humans. Nonandrogenic molecules of P itself and of derivatives, such as 19-norprogesterones, would appear neutral on the vessels. Several ongoing randomized controlled trials of HRT are focusing on primary or secondary prevention of coronary heart disease. Unfortunately, most of these large trials have selected the same HRT regimen for their study design. Further studies with other treatment regimens are thus needed and should consider the various steroids used in different countries.     

Medroxyprogesterone acetate attenuates long-term effects of 17beta-estradiol in coronary arteries from hyperlipidemic rabbits

OBJECTIVE: The progestin component in hormone replacement treatment may oppose the effects of estrogen on vascular function. This study examined the effect of long-term treatment with 17beta-estradiol (E(2)) alone and in combination with two progestins on K(+) and Ca(2+)-mediated mechanisms in coronary arteries. METHODS: Watanabe heritable hyperlipidemic rabbits were treated orally with either E(2) (4 mg/day), medroxyprogesterone acetate (MPA) (10 mg/day), norethindrone acetate (NETA) (2 mg/day), E(2)+MPA, E(2)+NETA, or placebo for 16 weeks (n=10 in each group). Coronary arteries were used for mRNA and myograph studies. RESULTS: E(2) increased vasodilatation induced by sodium nitroprusside and decreased vasocontraction induced by potassium. The first but not the latter response was opposed by MPA. The combination of MPA and E(2), but neither compound alone enhanced nimodipine-induced vasodilatation and increased the expression of L-type voltage-gated Ca(2+) channel mRNA. NETA had no opposing effects. Hormone treatment did not affect large-conductance Ca(2+) activated or ATP-sensitive K(+) channels or cGMP-dependent protein kinase mRNA expression. Hyperlipidemia had no effect on vascular reactivity. CONCLUSION: When E(2) is administered with MPA, effects of E(2) on nitric oxide and Ca(2+)-mediated vascular reactivity in rabbit coronary arteries are modulated. The results suggest that the progestin component in hormone replacement treatment may interfere with the supposed beneficial vascular effects of estrogen.     

Serum estradiol concentration as measured by HPLC-RIA and bone mineral density in postmenopausal women during hormone replacement therapy

OBJECTIVE: To determine the relationship between the serum estradiol concentration and bone mineral density (BMD) of the lumbar spine in postmenopausal women treated with conjugated equine estrogen (CEE) and medroxyprogesterone acetate (MPA) every other day and every day. METHODS: Eighty-four postmenopausal women were randomly treated with hormone replacement therapy (HRT) every other day and every day. Forty-seven women received oral administration of 0.625 mg CEE and 2.5 mg MPA every other day, and 37 women received oral administration of 0.625 mg CEE and 2.5 mg MPA every day. BMD of the lumbar spine at 12 months and serum concentrations of estradiol and estrone at 6 and 12 months after treatment were examined. RESULTS: The estradiol concentration in subjects treated every other day showed a significant (p < 0.001) positive correlation with the percentage change in lumbar BMD, while that in subjects treated every day was not correlated with the percentage change in BMD. The differences between serum estradiol concentrations after 12 months of treatment and initial serum estradiol values in women treated every other day and every day also showed a significant (p < 0.01 and 0.05, respectively) positive correlation with percentage changes in BMD. In women treated every other day, body mass index (BMI) in the subjects in whom BMD did not increase was significantly (p < 0.01) lower than that in the subjects in whom BMD did increase. CONCLUSIONS: The serum estradiol concentration in women treated every other day has a strong positive correlation with the percentage change in lumbar BMD, but a higher estradiol concentration may be needed for women in whom BMD did not increase with HRT every other day after due consideration of individual characteristics such as BMI.     

Risk of breast cancer with progestins: critical assessment of current data

Whether progestins protect against the risk of breast cancer or enhance that risk has been a major area of controversy over the past several years. Observational studies have reported conflicting results and experimental studies examining whether progestins exert mitogenic or anti-mitogenic actions on breast tissue report divergent results. Based upon a wide range of animal, epidemiologic and clinical data, most investigators agree that estrogens contribute to the development of breast neoplasms. However, the additional effect of progestins on this risk has been the subject of substantial discussion and controversy. A variety of experiments have been carried out using human breast cancer cells grown in vitro and as xenografts in nude mice. These studies demonstrated both mitogenic and anti-mitogenic effects depending upon the precise experimental conditions. Two potential reasons for these differences include differential metabolism of progestins into inhibitory pregnenes or stimulatory 5-alpha-reduced pregnanes or the presence of a protein (GPR 30) which allows the anti-mitogenic effects of progestins to be manifest. Based upon the conflicting nature of the results in experimental studies, we believe that only data in patients provide substantial insight into the actions of progestins on the intact human breast. Studies have now demonstrated that cell proliferation and breast density is higher during the luteal than during the follicular phase of the menstrual cycle. In postmenopausal women, long-term exposure to estrogen plus a progestin results in a marked enhancement of proliferation of the terminal duct lobular units as well as in breast density. These data, taken together, provide substantial evidence that progestins are mitogenic on the human breast when given long term to postmenopausal women. To critically evaluate the observational studies regarding breast cancer risk from progestins, we developed a set of stringent criteria for acceptance of individual studies. Four of the five studies meeting these criteria reported a greater risk of breast cancer with combination estrogen/progestin regimens than with estrogen alone. More importantly, the first randomized, prospective, controlled trial of the risk of breast cancer with an estrogen/progestin combination (the Women's Health Initiative Study) has now been published. This study reported a 26% increased relative risk of breast cancer with the estrogen/progestin combination. Based upon these data, we believe that progestins do add to the risk of breast cancer over and above that imparted by estrogen alone. The attributable risk during use for 5 years or less is small but increases logarithmically during long-term use. The majority of data regarding progestins are derived from regimens using MPA. However, we conclude from our analysis that the burden of proof regarding progestins has now shifted. One must now prove that an estrogen/progestin combination is safe with respect to breast cancer rather than having to prove it harmful.     

Effect of postmenopausal hormone replacement therapy on lipoprotein and homocysteine levels in Chinese women.

Epidemiological studies have revealed that postmenopausal estrogen replacement therapy results in a marked reduction in the risk for cardiovascular diseases. In the present study, we evaluated plasma lipoprotein profile as well as homocysteine levels in 145 postmenopausal and premenopausal Chinese women living in Hong Kong. We also investigated the effect of hormone-replacement therapy (HRT) with estrogen or estrogen combined with progestin on plasma lipoprotein profile and homocysteine concentrations in those individuals. Postmenopausal women displayed significantly higher plasma levels of total cholesterol, LDL-cholesterol and apoB as well as higher plasma homocysteine levels than that of premenopausal women. HRT with either estrogen (17beta-estradiol or conjugated equine estrogen) alone or estrogen combined with progestin for 3.5-4.5 years significantly improved the lipoprotein profile in postmenopausal women by decreasing the levels of total cholesterol (12-20% reduction), LDL-cholesterol (26-29% reduction) and apoB (21-25% reduction). In women treated with 17beta-estradiol or conjugated equine estrogens their plasma levels of apoAl were significantly elevated (18% elevation) as compared to non-users. HRT also reduced plasma concentrations of homocysteine (13-15% reduction). In conclusion, we found that long-term HRT was associated with improvement in plasma lipoprotein profile and a reduction in homocysteine concentration in postmenopausal women. These results support the notion that the improvement of lipoprotein profile and a reduction in homocysteine concentration may contribute to the beneficial effect of HRT on cardiovascular risk.     

The effect of progesterone and synthetic progestins on serum- and estradiol-stimulated proliferation of human breast cancer cells.

The results from the Women's Health Initiative study on enhanced breast cancer risk in postmenopausal women using an estrogen/progestin combination clearly indicate the need for a comparison of different progestins with regard to cancer risk. To shed some light on this issue, we have investigated the influence of progesterone and various synthetic C19- and C21-progestins on cell proliferation of a human breast cancer cell line in vitro. Of special interested was the comparison of two different regimens commonly used in HRT, sequential and continuous combination with estradiol. We used the human breast cancer cell line MCF-7 as a model. Progesterone (P), chlormadinone acetate (CMA), dienogest (DNG), gestodene (GSD), 3-ketodesogestrel (KDG), levonorgestrel (LNG), medroxyprogesterone acetate (MPA), and norethisterone (NET) were investigated in the range of 0.01nm to 10 micro M alone and in combination with 10 nM estradiol. Cell proliferation was measured after 7 days using the ATP chemosensitivity test. Tested alone, CMA, DNG, GSD, KDG, MPA and NET significantly stimulated cell proliferation, but only at high dosages. Sequentially combined with estradiol, only CMA inhibited cell proliferation over the whole concentration range. Slight effects were found for DNG, GSD and KDG, whereas P and MPA only showed an effect at the highest concentration. NET had no significant effect on cell proliferation. Continuously combined, all progestins exhibited an inhibitory effect over the whole concentration range. The most prominent effects were found for P, CMA, GSD, and KDG. Only slight effects were found for DNG, MPA and NET. Our in vitro results indicate that the influence on breast cancer risk using HRT in postmenopausal women might depend on the type of progestin used as well as on the regimen applied. However, the net inhibitory in vitro effect of the progestins at clinically relevant dosages is rather minimal, and whether progestins in general can reduce breast cancer risk in long-term treatment remains uncertain. Further clinical trials are urgently needed to clarify this issue.     

Usefulness of the monkey model to investigate the role soy in postmenopausal women's health

Some of the important health issues for postmenopausal women include cardiovascular disease, osteoporosis, breast cancer, and relief of menopausal symptoms. Ovariectomized cynomolgus monkeys (Macaca fascicularis) have many strengths as models for research in this area including a close phylogenetic relationship to humans, similarities in lipid/lipoprotein metabolism and coronary artery anatomy, similar skeletal anatomical and morphological characteristics, mammary glands with similar pathophysiological characteristics, and a 28-day menstrual cycle with similar hormonal fluctuations. Monkeys (macaques) also experience declining ovarian function and irregular menstrual cycles (natural menopause) when they approach 24 to 29 yr of age. However, because of their very short life span after natural menopause, ovariectomized macaques are used to model postmenopausal women. The cynomolgus monkey model has been useful in defining the potential cardiovascular benefits of soy foods and soy supplements; however, it remains unclear whether the observations are generalizable to all women or only to those who, like cynomolgus monkeys, convert the soy isoflavone daidzein to the metabolite equol. Particularly important has been the use of the cynomolgus monkey model to understand the effects of soy on breast health. There is evidence from a cynomolgus monkey trial to suggest that soy/soy phytoestrogens have no estrogen agonist effects for breast. Finally, soy/soy phytoestrogens do not appear to be an adequate alternative to postmenopausal hormone therapy. Nevertheless, important attributes of soy have been identified, and it may have potential as a complementary component to hormone therapy.     

Bridging advanced glycation end product, receptor for advanced glycation end product and nitric oxide with hormonal replacement/estrogen therapy in healthy versus diabetic postmenopausal women: a perspective

Cardiovascular diseases (CVD) are the most significant cause of death in postmenopausal women. The loss of estrogen biosynthesis with advanced age is suggested as one of the major causes of higher CVD in postmenopausal women. While some studies show beneficial effects of estrogen therapy (ET)/hormonal replacement therapy (HRT) in the cardiovascular system of healthy postmenopausal women, similar studies in diabetic counterparts contradict these findings. In particular, ET/HRT in diabetic postmenopausal women results in a seemingly detrimental effect on the cardiovascular system. In this review, the comparative role of estrogens is discussed in the context of CVD in both healthy and diabetic postmenopausal women in regard to the synthesis or expression of proinflammatory molecules like advanced glycation end products (AGEs), receptor for advanced glycation end products (RAGEs), inducible nitric oxide synthases (iNOS) and the anti-inflammatory endothelial nitric oxide synthases (eNOS). The interaction of AGE-RAGE signaling with molecular nitric oxide (NO) may determine the level of reactive oxygen species (ROS) and influence the overall redox status of the vascular microenvironment that may further determine the ultimate outcome of the effects of estrogens on the CVD in healthy versus diabetic women.     

Estrogen is a modulator of vascular inflammation

Vascular inflammation underlies the pathogenesis of atherosclerosis. Atherosclerotic changes in the vasculature lead to conditions such as coronary artery disease and stroke, which are the major causes of morbidity and mortality worldwide. Epidemiological studies in premenopausal women suggest a beneficial role for estrogen in preventing vascular inflammation and consequent atherosclerosis. However, the benefits of estrogen areabsent or even reversed in older postmenopausal subjects. The modulation of inflammation by estrogen under different conditions might explain this discrepancy. Estrogen exerts its antiinflammatory effects on the vasculature through different mechanisms such as direct antioxidant effect, generation of nitric oxide, prevention of apoptosis in vascular cells and suppression of cytokines and the renin-angiotensin system. On the other hand, estrogen also elicits proinflammatory changes under certain conditions, which are less completely understood. Some of the mechanisms underlying a possible proinflammatory role for estrogen include increased expression of the proinflammatory receptor for advanced glycation end products, increased tyrosine nitration of cellular proteins, and generation of reactive oxygen species through an uncoupled eNOS. In this review, we have presented evidence for both antiinflammatory and proinflammatory pathways modulated by estrogen and how interactions among such pathways might determine the effects of estrogen on the vascular system.     

Estrogen and oxidative stress: A novel mechanism that may increase the risk for cardiovascular disease in women

Although early studies demonstrated that exogenous estrogen lowered a woman's risk of cardiovascular disease, recent trials indicate that HRT actually increases the risk of coronary heart disease or stroke. However, there is no clear explanation for this discrepancy. Is estrogen a helpful or a harmful hormone in terms of cardiovascular function? This review discusses some recent findings that propose a novel mechanism which may shed significant light upon this controversy. We propose that nitric oxide synthase (NOS) expressed within the vascular wall is a target of estrogen action. Under normal conditions in younger women, the primary product of estrogen action is NO, which produces a number of beneficial effects on vascular biology. As a woman ages, however, there is evidence for loss of important molecules essential for NO production (e.g., tetrahydrobiopterin, l-arginine). As these molecules are depleted, NOS becomes increasingly “uncoupled” from NO production, and instead produces superoxide, a dangerous reactive oxygen species. We propose that a similar uncoupling and reversal of estrogen response occurs in diabetes. Therefore, we propose that estrogen is neither “good” nor “bad”, but simply stimulates NOS activity. It is the biochemical environment around NOS that will determine whether estrogen produces a beneficial (NO) or deleterious (superoxide) product, and can account for this dual and opposite nature of estrogen pharmacology. Further, this molecular mechanism is consistent with recent analyses revealing that HRT produces salutary effects in younger women, but mainly increases the risk of cardiovascular dysfunction in older postmenopausal women.     

Clinical experience with trimegestone as a new progestin in HRT

Trimegestone (TMG) is a novel, 19-norpregnane progestin, which demonstrates endometrial selectivity with a reduced progestin-related side effect profile when compared to several other currently marketed progestins. TMG has been studied in combination with 17beta-estradiol (17beta-E2) and conjugated equine estrogens (CEE). TMG-containing HRT agents were effective in relieving vasomotor symptoms and providing protection from endometrial hyperplasia with < or =1% hyperplasia. In clinical trials with sequential regimens, TMG provided predictable withdrawal bleeding associated with a low incidence of irregular and prolonged bleeding. Clinical studies of continuous combined regimens of estrogen/TMG combinations demonstrated high levels of amenorrhea. Both 17beta-E2 and CEE/TMG combinations have shown improved bone mineral density and quality-of-life assessments. Both continuous combined and sequential regimens of 17beta-E2/TMG and CEE/TMG have a favorable clinical profile. TMG provides an important new option for the treatment of postmenopausal symptoms and the prevention of osteoporosis.     

Biological effects of hormone replacement therapy in relation to serum estradiol levels

OBJECTIVE: Tissues in various parts of the body have different sensitivities to estradiol. However, it is very difficult to measure the serum estradiol levels precisely in women receiving oral conjugated equine estrogen, which is a mixture of estrogens. In the present study, we precisely measured the serum levels of estradiol in postmenopausal women undergoing hormone replacement therapy (HRT), and we clarified the relationships between serum estradiol levels and the effects of HRT on the Kupperman index, bone mineral density (BMD), serum gonadotropin, lipid metabolism and unscheduled bleeding as the clinical endpoints. METHODS: Sixty-eight postmenopausal or bilaterally ovariectomized women, aged 30-64 years, who had been suffering from vasomotor symptoms such as hot flush or atrophy of the vagina were randomly assigned to two groups: one group of 34 patients who received oral administration of 0.625 mg conjugated equine estrogen (CEE, Premarin, Wyeth) and 2.5 mg medroxyprogesterone acetate (MPA, Provera, Upjohn) every other day, and another group of 34 patients who received oral administration of 0.625 mg CEE and 2.5 mg MPA every day. All subjects were re-classified into three groups according to the serum estradiol level after 12 months of treatment: (1) low estradiol group (<15 pg/ml, n = 25); (2) middle estradiol group (> or =15 and <25 pg/ml, n = 27), and (3) high estradiol group (> or =25 pg/ml, n = 16). We examined the relationships between serum estradiol level and the effects of estradiol on the Kupperman index, BMD, serum gonadotropin levels, lipid profile and unscheduled bleeding in these three groups. Results: Results obtained by using our newly developed high-performance liquid chromatography (HPLC)-radioimmunoassay (RIA) system clearly showed that the effects on each tissue in postmenopausal women receiving oral CEE and MPA is closely related to estradiol level. The effects of HRT on BMD, serum gonadotropin levels and lipid profile were shown to be clearly dependent on the serum estradiol levels, while the effect of HRT on the Kupperman index was independent of the serum estradiol level. Furthermore, it was also found that a very low concentration of estradiol (<15 pg/ml) was sufficient to suppress the serum LH and FSH levels and to relieve vasomotor symptoms, and that the minimum concentration of estradiol required to increase BMD was 15 pg/ml. On the other hand, the level of estradiol required to reduce total cholesterol, low density lipoprotein-cholesterol (LDL-C) and apolipoprotein B (Apo B) was found to be more than 25 pg/ml, while the level required to increase high density lipoprotein-cholesterol (HDL-C) and apolipoprotein A1 (Apo A1) was at least 15 pg/ml. The incidence of unscheduled bleeding was also lower in the low estradiol group than in the other estradiol level groups. CONCLUSION: These results suggest that the different clinical endpoints have different response thresholds and thus reflect tissue sensitivity to estradiol levels achieved by HRT.