Various clinical and epidemiological evidence strongly suggests a major role for sex steroid hormones in the determination of anatomical specificities of fat distribution in human. To date, no studies have examined the possible presence of androgen receptors (AR) in human adipocytes and preadipocytes. We have studied AR in preadipocytes from various anatomical locations (intra-abdominal and subcutaneous) in middle-aged men and women during the proliferation and differentiation processes (adipogenesis). Androgen binding sites quantified by [3H]R-1881-specific binding in whole cell extracts were twofold higher in intra-abdominal than in subcutaneous preadipocytes but identical for the same fat depots in men and women. Western blot analysis revealed 1) the presence of AR in the nuclear and cytosolic fractions of human preadipocytes, 2) a decrease of AR expression during adipogenesis, and 3) an upregulation of AR by androgens in vitro. RT-PCR experiments showed the presence of AR mRNA in human preadipocytes and adipocytes and also the regional specificity of AR distribution. However, AR mRNA expression was found to increase during adipogenesis. The same results were observed in rat preadipocytes. In conclusion, this study clearly demonstrates the presence of AR in human preadipocytes and adipocytes and suggests that androgens may contribute, through regulation of their own receptors, to the control of adipose tissue development.
Adipocytes are estrogen-responsive cells, but the quantitative expression and transcriptional regulation of the estrogen receptors (ER-alpha and ER-beta) in human adipocytes and their precursor cells are unclear. Using real-time quantitative PCR, we have demonstrated that both ER-alpha and ER-beta mRNA are expressed in human mature adipocytes with a large predominance of ER-alpha mRNA. Moreover, ER-alpha mRNA is identically expressed whatever the anatomic origin (intraabdominal and subcutaneous) of the adipocytes and the gender. ER-beta mRNA levels are higher in women compared with men, without regional differences. 17beta-Estradiol in vitro upregulates expression of both ER-alpha and ER-beta mRNA in subcutaneous adipocytes from women but only the ER-alpha mRNA in subcutaneous and intra-abdominal adipocytes from men. In preadipocytes, only the ER-alpha subtype was present. In the latter cells, estrogens in vitro had no influence on ER-alpha expression (mRNA and protein). The present study also shows that estrogens in vitro increase the AP-1, SP-1, and estrogen response element DNA binding activities in differentiated but not in confluent preadipocytes, suggesting that ER become functional during the course of adipogenesis. On the whole, these data are consistent with a predominant role of the ER-alpha subtype in mediating the effects of estrogens on human adipose tissue development and metabolism.
Because leptin has recently been shown to induce proliferation and/or differentiation of different cell types through different pathways, the aim of the present study was to investigate, in vitro, the influence of leptin on adipogenesis in rat preadipocytes. A prerequisite to this study was to identify leptin receptors (Ob-Ra and Ob-Rb) in preadipocytes from femoral subcutaneous fat. We observed that expressions of Ob-Ra and Ob-Rb increase during adipogenesis. Furthermore, leptin induces an increase of p42/p44 mitogen-activated protein kinase phosphorylated isoforms in both confluent and differentiated preadipocytes and of STAT3 phosphorylation only in confluent preadipocytes. Moreover, exposure to leptin promoted activator protein-1 complex DNA binding activity in confluent preadipocytes. Finally, exposure of primary cultured preadipocytes from the subcutaneous area to leptin (10 nM) resulted in an increased proliferation ([3H]thymidine incorporation and cell counting) and differentiation (glycerol-3-phosphate dehydrogenase activity and mRNA levels of lipoprotein lipase, peroxisome proliferator-activated receptor-γ2, and c-fos). Altogether, these results indicate that, in vitro at least, leptin through its functional receptors exerts a proadipogenic action in subcutaneous preadipocytes.
As a sexual dimorphism appears in plasma leptin levels, the aim of the present study was to investigate, in vivo and in vitro, the influence of sex steroid hormones on ob messenger RNA (mRNA) and leptin expressions in rat fat cells from various anatomical localizations. In male rats, castration resulted in a modulation of ob gene mRNA expression which was increased by 2-fold in perirenal and half-reduced in sc adipocytes. Moreover, in isolated fat cells from both perirenal and s.c. fat depots, ob gene mRNA expression was reduced by 20% after a 24-h in vitro exposure to dihydrotestosterone (10(-8) M). This effect of dihydrotestosterone on ob mRNA was prevented by exposure to the antiandrogen cyproterone acetate and also by actinomycin D. In contrast, leptin secretion from both perirenal and sc adipocytes was unchanged after 24 h exposure to dihydrotestosterone. In female rats, ovariectomy induced a 25% decrease in ob gene mRNA expression in perirenal fat cells. In vitro studies revealed that a 24-h exposure to 17-beta estradiol (10(-8) M) induced a 1.4-, 1.2-, and 1.75-fold increase in ob mRNA expression and a 3.8-, 1.65- and 2-fold increase in leptin secretion in sc, perirenal and parametrial adipocytes, respectively. Moreover, these effects were prevented by the antiestrogen ICI182780 and also by actinomycin D. Altogether, these results demonstrate that in rat adipocytes, estrogens, and androgens modulate ob gene expression at the mRNA level through sex steroid receptor-dependent transcriptional mechanisms.
In the present study, we have explored, in vitro, the possibility that short exposure to androgens and estrogens for 24 h may directly influence leptin expression (ARNm and secretion) in sc adipose tissue from men and women. In men, only dihydrotestosterone at high concentration (100 nM) induced a reduction in leptin secretion and ob mRNA level. In women, 17beta-estradiol (10-100 nM) increased ob mRNA expression (+180 to +500%) and leptin release (+75%). Moreover, in adipose tissue of women, the estrogen precursors testosterone (100 nM) and dehydroepiandrosterone (1 microM) also induced an increase in leptin secretion (+84 and +96%, respectively), an effect that was prevented by the aromatase inhibitor letrozole. Finally, the stimulatory effect of 17beta-estradiol observed in women was antagonized by the antiestrogen ICI182780. Altogether, these results suggest that the sexual dimorphism of leptinemia in humans is mainly owing to the estrogen receptor-dependent stimulation of leptin expression in adipose tissue by estrogens and estrogen precursors in women.
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