Objective: Leptin is the hormonal product of the ob gene. It is expressed in adipocytes and participates in the regulation of food intake and metabolism. Since leptin also seems to signal metabolic information to the reproductive system, we studied the association between reproductive hormones and plasma leptin in normal-weight young women. Design: Eight young women with normal menstrual cycles (body mass index (BMI) 21.2 Ϯ 1.6 kg/m 2 ) and eight young women using hormonal contraception (BMI 21.4 Ϯ 1.1 kg/m 2 ) were studied. Furthermore, six women with normal menstrual cycles and no hormonal therapy (BMI 20.7 Ϯ 1.2 kg/m 2 ) were studied around the time of the anticipated ovulation. Methods: Serum leptin, estradiol, progesterone and luteinizing hormone (LH) concentrations were measured with radioimmunoassays. Results: Serum leptin concentrations were similar at the beginning of the cycle, at the time of the anticipated ovulation and at the end of the menstrual cycle (10.2 Ϯ 7.1, 10.7 Ϯ 7.0 and 11.8 Ϯ 6.9 mg/l respectively). There was an association between leptin and LH concentrations (r ¼ 0.37, P< 0 .01) when values recorded during different time points during the cycle were plotted with each other. There was no change in serum leptin in samples taken at different times of the cyclic treatment with an oral contraceptive. There was no significant difference in mean serum leptin concentrations between women using oral contraceptives and women with no hormonal therapy. Conclusions: There is a link between serum leptin and LH concentrations during the menstrual cycle. Variations in circulating estrogen and/or progesterone concentrations have no major influence on circulating leptin in young female subjects.
Among other actions, leptin has been suggested to increase energy expenditure and to modulate the menstrual cycle. In fact, the main effect of leptin seems to be modulating the sympathetic nervous system and gonadotropin-releasing hormone pulsatility. We investigated whether changes in the plasma steroid concentrations during the estrous cycle and after ovariectomy and steroid replacement can modulate plasma leptin levels, adipose tissue leptin mRNA expression, and some of the candidates for mediating energy expenditure (uncoupling proteins (UCP) 1, 2, and 3 mRNA) in white and brown adipose tissue. Rats in estrous cycle or ovariectomized rats with or without estradiol or progesterone replacement therapy for 18 days were studied. Plasma leptin, insulin, estradiol and progesterone were measured with radioimmunoassays. Leptin mRNA expression was measured in subcutaneous, periovarian and mesenteric white adipose tissue and in interscapular brown adipose tissue. Expression of UCP 1, 2, and 3 mRNA in periovarian white and brown adipose tissue was analyzed. Plasma leptin levels were significantly decreased in the estrous (1.1 +/- 0.4 ng/ml) compared with the pro-estrous (1.7 +/- 0.4 ng/ml, F = 3.0, p = 0.046) phase of cycle. UCP1 mRNA levels in brown adipose tissue were more elevated during pro-estrus than during metestrus (F = 3.17, p = 0.039). Gene expressions of leptin, UCP2 or UCP3 mRNA did not change significantly during the cycle. In ovariectomized rats, estradiol and/or progesterone treatment had no effect on plasma leptin levels. Gene expression analysis of leptin and UCP1, 2 and 3 in adipose tissue was not affected by steroid replacement. In conclusion, the estrous cycle appears to have a minor effect on modulation of leptin and uncoupling proteins. Only plasma leptin levels and expression of UCP1 mRNA are modestly elevated during the estrous cycle in the rat. Since estrogen and/or progesterone substitution in ovariectomized rats does not affect circulating leptin concentration or expression of leptin and UCPs in adipose tissue, it is unlikely that steroids play a major role in their regulation.
Besides its role in the regulation of energy balance, leptin seems to be involved in linking energy stores to the reproductive system. A gender-dependent difference exists in plasma leptin concentration and leptin messenger ribonucleic acid expression in rodents and humans. This difference does not seem to be explained simply by differences in the amount of body fat between genders. To elucidate the relationship of endogenous testosterone and leptin, we studied the serum leptin concentrations in 269 elderly nondiabetic men. In addition, to assess whether exogenously administered testosterone could influence leptin production, we followed the serum levels of leptin in 10 healthy men during a 12-month treatment with 200 mg testosterone enanthate, i.m., weekly for contraceptive purposes. We found that the serum leptin concentration correlated inversely (r = -0.39; P < 0.001) with that of testosterone in elderly men. This inverse correlation was still present when body mass index and plasma insulin were included in the analysis. The administration of testosterone to young men suppressed serum leptin from the pretreatment level of 3.4 +/- 1.4 to 1.9 +/- 0.6 micrograms/L during the therapy. After cessation of testosterone injections, serum leptin concentration returned back to the pretreatment level. It is concluded that testosterone has a suppressive effect on leptin production, as reflected by circulating levels of this hormone.
Among other actions, leptin has been suggested to increase energy expenditure and to modulate the menstrual cycle. In fact, the main effect of leptin seems to be modulating the sympathetic nervous system and gonadotropin-releasing hormone pulsatility. We investigated whether changes in the plasma steroid concentrations during the estrous cycle and after ovariectomy and steroid replacement can modulate plasma leptin levels, adipose tissue leptin mRNA expression, and some of the candidates for mediating energy expenditure (uncoupling proteins (UCP) 1, 2, and 3 mRNA) in white and brown adipose tissue. Rats in estrous cycle or ovariectomized rats with or without estradiol or progesterone replacement therapy for 18 days were studied. Plasma leptin, insulin, estradiol and progesterone were measured with radioimmunoassays. Leptin mRNA expression was measured in subcutaneous, periovarian and mesenteric white adipose tissue and in interscapular brown adipose tissue. Expression of UCP 1, 2, and 3 mRNA in periovarian white and brown adipose tissue was analyzed. Plasma leptin levels were significantly decreased in the estrous (1.1 +/- 0.4 ng/ml) compared with the pro-estrous (1.7 +/- 0.4 ng/ml, F = 3.0, p = 0.046) phase of cycle. UCP1 mRNA levels in brown adipose tissue were more elevated during pro-estrus than during metestrus (F = 3.17, p = 0.039). Gene expressions of leptin, UCP2 or UCP3 mRNA did not change significantly during the cycle. In ovariectomized rats, estradiol and/or progesterone treatment had no effect on plasma leptin levels. Gene expression analysis of leptin and UCP1, 2 and 3 in adipose tissue was not affected by steroid replacement. In conclusion, the estrous cycle appears to have a minor effect on modulation of leptin and uncoupling proteins. Only plasma leptin levels and expression of UCP1 mRNA are modestly elevated during the estrous cycle in the rat. Since estrogen and/or progesterone substitution in ovariectomized rats does not affect circulating leptin concentration or expression of leptin and UCPs in adipose tissue, it is unlikely that steroids play a major role in their regulation.
Objective: Leptin plays an important role in the regulation of reproduction. To explore the contribution of oestradiol to serum leptin levels in men, we measured the concentrations of serum leptin and insulin after inhibition of oestrogen biosynthesis by selective blockade of the aromatase enzyme. Design: The study had a double-blind parallel group design. Methods: The aromatase inhibitor, MPV 2213ad, was given to eight healthy male volunteers as a single dose of 100 mg. Eight men received placebo. Serum leptin and insulin were determined from blood samples collected at 0800 h, 1600 h and 2000 h both on the actual test day (day 0) and on the previous day (day ¹1), and from single blood samples taken in the morning of days 1, 2, 4 and 7. Changes in serum leptin were correlated with those seen in serum oestradiol, testosterone, LH, FSH, cortisol and aldosterone, which were determined earlier.Results: After the aromatase inhibitor administration, mean serum oestradiol concentration was reduced by 74% from the baseline compared with a 19% reduction in the placebo group (P for difference < 0.001), and returned to pre-treatment levels within four days. Despite marked changes in serum oestradiol and sustained elevations in serum testosterone, LH and FSH concentrations, serum leptin concentrations were similar in the group receiving the aromatase inhibitor and in the placebo group. We found a weak correlation between serum oestradiol and leptin, which could not be reproduced when the percentage changes in these variables were analysed. Conclusion: Marked short-term reduction in serum oestradiol concentration has no effect on serum leptin levels in young men.
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