1 Department of Obstetrics and Gynaecology and 2 Department of Pathological Biochemistry, University of Glasgow, Glasgow, UK
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Abstract |
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Key words: hormone replacement therapy/insulin resistance/LDL subfractions/menopause/tachyphylaxis
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Introduction |
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Smaller LDL particles (LDL-III) are considered more atherogenic than larger buoyant species, because of their increased susceptibility to oxidation (McNamara et al., 1992) and their increased residence time in the plasma (Dejager, 1993). Indeed, their preponderance in the circulation (even in the presence of normal total LDL concentrations) is strongly associated with an increased incidence of CVD and type 2 diabetes (Crouse et al., 1985
; Austin, 1992
).
Plasma triglyceride concentrations have a determinative influence on the concentration of small, dense LDL in the normal population (McNamara et al., 1992; Rainwater, 2000
). Studies in men demonstrate that when plasma triglyceride concentrations are above 1.31.7 mmol/l, larger LDL particles become triglyceride enriched and thus suitable for conversion to smaller species by the action of the hepatic lipase (HL) enzyme. Increased HL activity, in turn, is associated with insulin resistance (Baynes et al., 1991
), and exhibits strong sexual dimorphism with exogenous androgens up-regulating, and estrogens down-regulating its activity (Hazzard et al., 1984
).
Most studies of ERT in post-menopausal women have examined the effects of oral administration. For example, oral unopposed estradiol (E2) replacement therapy has a favourable effect by reducing total and LDL, and increasing high density lipid (HDL) cholesterol concentrations (Godsland, 2001). The LDL cholesterol-lowering effect following ERT is thought to be directly related to changes in estrogen level, through enhanced LDL receptor activity, which is manifested as an increase in fractional catabolic rate for LDL apolipoprotein B (Karjalainen et al., 2000
). Paradoxically, however, concentrations of plasma triglyceride have been shown to increase (and the LDL particle diameter decrease) following oral estrogen replacement therapy (Campos et al., 1988
; Griffin et al., 1993
; Rajman et al., 1996
). The magnitude of change in triglyceride concentrations appears to be related to the type of estrogen (being more marked with oral conjugated equine estrogen than with 17ß-estradiol), and also appears to be related to the mode of administration.
Few studies have examined the effects of non-oral ERT on lipoprotein parameters, and none have examined the effects of subcutaneous administration on LDL size and density. Transdermally delivered estrogen appears to have minimal effects on lipoprotein profile, and it has a less marked effect on plasma triglyceride concentrations than oral preparations, probably because they avoid the hepatic first pass effect (Seed, 1994; Lahdenpera et al., 1996
). However, it has been suggested that high concentrations of estrogen delivered transdermally may adversely effect the LDL subfraction profile (Lobo, 1991
), however, conclusive data are lacking.
Tachyphylaxis is a recognized complication of implanted estrogen replacement therapy that describes the return of menopausal women to the clinic requesting implant renewal at more frequent intervals than recommended, because of the premature return of symptoms (Garnett et al., 1990). This results in a cumulative effect of increasingly high concentrations of serum E2 (Cardozo et al., 1984
). This provides a good model to study the effects of unopposed, high concentrations of circulating estradiol on lipoprotein profile, HL activity, and LDL subfraction distribution, in the absence of first pass liver interactions.
The aim of this study was to use a cross-sectional population design to examine, for the first time, the effect of supra-normal circulating E2 upon lipid and lipoprotein subfraction concentrations. We hypothesized that despite very high concentrations of systemic estrogen, plasma lipids (in particular triglyceride) would be only minimally altered in women with tachyphylaxis due to avoidance of hepatic first-pass metabolism. Since there is evidence that sex hormones influence insulin metabolism and body fat distribution, we also examined anthropometric parameters and fasting insulin concentrations in this model.
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Materials and methods |
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Study protocol
The study was approved by the local hospital ethics committee, and written informed consent was obtained from all study subjects. All subjects were studied after an overnight fast of 12 h between 0800 and 1030 h.
Anthropometric measurements were made by the same-trained observer using standard techniques (World Health Organization, 1989). Body weight was measured using digital scales (Seca®, Hamburg, Germany) to within 100 g in light clothes; height was measured barefoot using stadiometer to within 0.5 cm. Body mass index (BMI) was calculated as: weight (kg)/height (m)2. Circumferences were measured to within 1 mm using flexible tape in the standing position. For calculation of waisthip ratio (WHR), waist circumference was measured mid-way between the lowest rib margin and the iliac crest at the end of gentle expiration, and hip circumference at the widest level of the greater trochanters.
The antecubital vein was cannulated with a butterfly needle (21 gauge) and 50 ml blood was withdrawn for hormone, lipoprotein and LDL subfraction estimations. Post-heparin plasma samples were obtained for hepatic lipase estimation 10 min following an i.v. injection of heparin at 70 IU/kg body weight. Samples for endocrine assays were harvested at 4°C by low speed centrifugation and aliquots of serum and plasma for hormonal analyses were stored at 20°C until analyses. Samples for lipid, and lipoprotein, and lipoprotein subfractions were placed on ice and were centrifuged within 2 h of venesection at 1000 g for 10 min. Aliquots of separated serum or plasma were either frozen immediately at 70°C for estimation of hepatic lipase activity, or stored temporarily at 4°C.
E2 (SI: pg/mlx3.67 = pmol/l) and progesterone (SI: ng/mlx 3.18 = nmol/l) were measured using a competitive fluoroimmunoassay (Wallac Ltd, Turku, Finland). Testosterone (SI: ng/mlx3.46 = nmol/l) was measured using competitive radioimmunoassay (Coat-A-Count® T; DPC, Los Angeles, CA, USA). LH, FSH and sex hormone binding globulin were assayed using specific non-competitive sandwich fluoroimmunoassay (Delfia hLH, Delfia hFSH, Delfia SHBG; Wallac Ltd, Turku, Finland). The free androgen index (FAI) was calculated as testosterone concentration (nmol/l) x100, divided by SHBG concentration (nmol/l). Plasma glucose was measured using the glucose oxidase method (Glucose Reagent Kit, Olympus AU5200®; Olympus Optical Co Ltd), while insulin was measured using a competitive radioimmunoassay (Coat-A-Count® I; DPC).
Plasma total cholesterol, triglyceride, HDL-C, very low density lipoprotein cholesterol (VLDL-C) and LDL-C measurements were performed by a modification of the standard Lipid Research Clinics protocol (1975).
The LDL subfractions were isolated by upward elution though six-step density gradient ultracentrifugation. The method was developed in our laboratory (Griffin et al., 1990). Briefly, major LDL subfractions were identified by peak maxima that occurred between hydrated density intervals of 1.0251.034 g/ml (LDL I), 1.0341.044 g/ml (LDL II) or 1.0441.060 g/ml (LDL III). The individual subfraction areas beneath the LDL profile were quantified using Beckman data graphics software (Beckman, High Wycombe, Bucks, UK). The detection system measured LDL concentration as absorbance at 280 nm and this was corrected to lipoprotein mass equivalence by applying previously calculated extinction coefficients. LDL-I 1 optical density unit (OD) = 2.63 mg lipoprotein/ml, LDL-II 1OD = 2.94 mg lipoprotein/ml and LDL-III 1 OD = 1.92 mg lipoprotein/ml. The integrated areas were corrected for differences in extinction coefficient and expressed as percentage of total LDL concentrations in mg of lipoprotein/dl plasma. The concentrations of the individual lipoprotein subfractions were determined by proportioning the mass (i.e. the sum of protein, cholesterol, cholesterol ester, triglyceride and phospholipid content) of total LDL (density 1.0191.063) prepared by sequential centrifugation according to the areas under the density gradient absorbance profile.
Hepatic lipase activity was estimated by the method described (Belfrage and Vaughan, 1969). It was assayed in post-heparin plasma (PHP). Briefly, PHP was incubated with 14C-labelled triglyceride/gum arabic emulsion; the free fatty acid (FFA) released by lipase activity was captured by albumin and extracted into a solvent. The ratio of radioactivity in the extracted fraction to the total present in blank incubations provided the basis of calculating the activity of the enzyme. Enzyme activities were expressed in mmol of fatty acids released per hour per ml of plasma (mmolFFA/ml/h).
Statistics
Data distributions were examined by drawing normality plots of all variables, and by performing ShapiroWilks test. A P value of < 0.05 was considered significant deviation from normality. Variables (E2, LH, FSH, testosterone, androstenedione, SHBG, triglyceride, HDL cholesterol, VLDL cholesterol, HL, and LDL subfractions mass and percentage) not normally distributed were log (loge) transformed. Results for normally distributed variables are shown as mean [95% confidence interval (CI)], while geometric mean (95% CI) is quoted for log-transformed variables.
Results in the two groups were compared using independent sample t-tests on normal and log normal variables. 2-tests were used to determine the difference in proportions in the study groups. Pearson's product moment correlation coefficients were calculated in the study subjects and controls (pooled data).
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Results |
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Discussion |
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Reduction in LDL cholesterol observed in this study could be due to an estrogen-mediated increased LDL catabolism secondary to enhanced LDL receptor expression (Griffin et al., 1993). These receptors have greater affinity for larger LDL particles resulting in selective clearance of LDL subfractions. Consistent with this, we noted that LDL-I concentrations were 30% lower in the SE group (56 versus 80 mg/dl; P < 0.05). By contrast, LDL-III was similar in the two groups.
Triglyceride concentrations were not higher in the SE group relative to controls. These data support the concept that the dose dependent increase in triglyceride concentration following oral estrogen therapy is likely a first pass pharmacological effect, since transdermal estrogen administration has little effect on plasma triglyceride concentrations (Walsh et al., 1991; Lahdenpera et al., 1996
). Given the absence of an effect of SE on triglyceride concentrations, and the established influence of triglyceride on LDL III concentrations (McNamara et al., 1992
; Coresh et al., 1993
; Rainwater, 2000
), it is not surprising that the concentration of small, dense LDL-III was not different in the SE group. This observation indicates that the perturbations in LDL subfraction distribution following oral, conjugated estrogen replacement therapy are explained by the increased plasma triglyceride concentrations that result from this form of therapy (Campos et al., 1993
; Griffin et al., 1993
; Rajman et al., 1996
). Absolute LDL-III concentrations only increase once plasma triglyceride reaches concentrations above 1.51.7 mmol/l (Tan et al., 1995
; Sattar et al., 1997
; Pirwany et al., 2001
).
HL plays a key role in the remodelling of LDL, and is thus a key determinant of LDL-III concentration (Griffin et al., 1993). HL activity was 40% lower in the SE group, which is in keeping with the proposed effects of estrogen on this enzyme (Tikkanen and Nikkila, 1987
).
Although we cannot exclude the effects of selection bias (e.g. differences in diet) in our study, it is noteworthy that mean WHR and fasting insulin were significantly lower in the SE group than in the controls, suggesting a difference in insulin sensitivity in the two groups. Our results appear to contrast with those observed in oral contraceptive users in whom the estrogen component (ethinyl estradiol) is associated with a reduction in insulin sensitivity (Godsland et al., 1992); however, such effects were not observed with transdermally administered 17ß-estradiol (Spencer et al., 2000
). These combined data indicate that the effects of estrogen on insulin sensitivity are dependent both on the type of estrogen used, balance of estradiol and estrone in the circulation, and the mode of administration.
In our population, there was a significant proportion of smokers in the two groups (37% and 42% in the SE and control groups respectively). Although we did not detect any differences in the pattern of results when smoking was examined, larger prospective studies are needed to establish if smoking influences the metabolic benefits of estrogen treatment.
In conclusion, our results show that women with SE had similar circulating triglyceride and HDL cholesterol concentrations but lower LDL cholesterol concentrations compared to age, smoking and BMI matched post-menopausal women not taking ERT. The data concerning correlates of insulin sensitivity (fasting insulin, and WHR) suggest that supra-normal circulating concentrations of E2, delivered subcutaneously, may beneficially influence insulin metabolism. Future prospective studies are needed to confirm these cross-sectional observations.
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Notes |
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Submitted on April 10, 2001; resubmitted on September 3, 2001
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References |
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accepted on November 6, 2001.