Regulation of leptin and leptin receptor in baboon pregnancy: effects of advancing gestation and fetectomy.

Leptin, a product of both adipose tissue and the placental syncytiotrophoblast and a potential regulator of primate conceptus development, increases in the maternal circulation with advancing gestation. This increase may be potentiated by estrogens, which also increase as pregnancy progresses. In the present study adipose tissue was collected from nonpregnant (n = 5) baboons (Papio sp) and in baboons during early (days 58-62; n = 5), mid (days 98--102; n = 5), and late (days 158-162; n = 5) pregnancy (term, approximately 184 days). Additionally, placental estrogen production was inhibited in pregnant baboons by the removal of fetal androgen precursors via fetectomy at midgestation, with tissues collected from fetectomized (n = 5) baboons approximately 60 days later. Leptin, estrogens, and androgens were quantitated in maternal serum by RIA. Leptin (LEP) and leptin receptor (LEP-R(L) and LEP-R(S) isoforms) messenger ribonucleic acids (mRNAs) were quantitated by competitive RT-PCR, and leptin concentrations were determined by RIA in maternal adipose and placental villous tissues. Although LEP transcript abundance in adipose tissues was unchanged as a result of pregnancy or with advancing gestation, the leptin protein level was higher (P < 0.02) in pregnant baboons in early gestation than in nonpregnant baboons and increased with gestational age (P < 0.04). Maternal serum estrogens (estradiol and estrone) and androgens (androstenedione and testosterone) were lower (P < 0.0001) in fetectomized baboons than in intact controls. Serum leptin concentrations were unchanged by fetectomy, but the abundance of LEP mRNA transcripts was lower (P < 0.003) in sc adipose tissue and 3-fold higher (P < 0.05) in placenta. Similarly, the leptin protein level declined (P < 0.05) in sc adipose tissue and increased (P < 0.05) in placenta in fetectomized baboons. Although LEP-R(L) mRNA levels were unchanged after fetectomy, placental LEP-R(S) transcript abundance was lower (P < 0.04) than in pregnancy-intact baboons matched for gestational age. Results suggest that both adipose tissue and the placenta may contribute to maternal hyperleptinemia during normal primate pregnancy. Furthermore, the withdrawal of placental steroids results in the enhanced placental leptin production that is commensurate with a decline in production by sc adipose tissue.

Effects of estrogen on leptin gene promoter activation in MCF-7 breast cancer and JEG-3 choriocarcinoma cells: selective regulation via estrogen receptors alpha and beta.

Leptin is a potential regulator of conceptus development. We have previously suggested that in primate pregnancy, leptin biosynthesis is regulated by estrogen in a tissue-specific manner. Therefore, the objective of the current study was to determine the mechanism of estrogen action on LEP promoter activation in divergent cell types. The effects of estrogen were investigated in estrogen receptor (ER)-positive MCF-7 breast cancer cells and in ER-negative JEG-3 choriocarcinoma cells. Cells were transfected with a leptin-luciferase or an estrogen responsive element (ERE)-luciferase reporter construct, in conjunction with ERalpha, ERbeta, or empty vector expression plasmids. Cells were treated with estradiol and/or the specific estrogen antagonists, ICI-182,780 or 4-hydroxytamoxifen. In MCF-7 cells, estradiol stimulated (P<0.05) ERE-luciferase activity and was inhibited by ICI-182,780, but did not stimulate leptin-luciferase activity. However, leptin-luciferase was stimulated by estradiol (P<0.05) and inhibited by antiestrogens in JEG-3 cells that were co-transfected with ERalpha. Both antiestrogens stimulated leptin-luciferase activity (P<0.05) in JEG-3 cells co-transfected with ERbeta. Results suggested that LEP promoter activation may depend upon co-activators present in leptin-producing cells and may be inhibited by repressors present in non-leptin producing cells. Divergent effects of estrogen may be owed to differences in the type of ER (alpha or beta) expressed in target tissues.

Leptin receptor transcripts are constitutively expressed in placenta and adipose tissue with advancing baboon pregnancy.

The baboon (Papio sp.) is an accepted nonhuman primate model for the study of the endocrinology of human pregnancy. To further characterize this model with regard to leptin function, messenger RNA transcripts for both long (Ob-RL) and short (Ob-RS) leptin receptor isoforms were identified in maternal tissues at various stages of gestation. Thus, placental villous, subcutaneous and omental adipose tissues were collected upon cesarean delivery at early (Days 60-62), mid (Days 98-102) and late (Days 159-164) pregnancy (term approximately 184 days). Additionally, amniochorion, decidua, and corpus luteum were collected in late gestation. Expression of Ob-RL and Ob-RS transcripts was determined in relation to constitutively expressed glyceraldehyde-3-phosphate dehydrogenase via reverse transcriptase-polymerase chain reaction, and transcripts were localized within specific placental cell types by in situ hybridization. Ob-RL and Ob-RS transcripts were present in amniochorion, decidua, and corpus luteum at term and appeared constitutively expressed throughout gestation in placenta and adipose tissues. Ob-RS was expressed in greater (P < 0.02) abundance than Ob-RL in all tissues. Within the placenta, receptor isoforms were localized predominantly to the syncytiotrophoblast. The expression of leptin receptor transcripts in maternal adipose tissues, as well as in the syncytiotrophoblast, amniochorion, decidua, and corpus luteum, suggests the potential for autocrine/paracrine roles for the polypeptide in the endocrinology of primate pregnancy. These are the first such observations in a nonhuman primate and support the use of the baboon as a model for the study of leptin in human pregnancy.

Regulation of pathways determining cholesterol availability in the baboon placenta with advancing gestation.

Low density lipoprotein (LDL) is accepted as the primary source of cholesterol for progesterone biosynthesis in the primate placental syncytiotrophoblast. We hypothesized that the syncytiotrophoblast may, however, derive significant amounts of cholesterol from sources in addition to the LDL pathway, especially during early pregnancy or when faced with a paucity of lipoprotein-cholesterol. To test this, alternate cholesterol-providing pathways were assessed in placentae at early (Days 60-61), mid (Days 98-102), and late (Days 160-167) gestation in the baboon (Papio sp., term approximately 184 days). Expression of LDL receptor mRNA transcripts in an enriched fraction of syncytiotrophoblast cells was approximately 13-fold greater (P < 0.05) in mid and late gestation than in early pregnancy, although no differences were observed in whole villous tissue. The abundance of transcripts for 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase, the enzyme responsible for de novo cholesterol synthesis, remained unchanged in syncytiotrophoblast cells; however, HMG-CoA reductase activity declined approximately 2-fold from early to late pregnancy (P < 0.01), with a commensurate decline in immunoreactive HMG-CoA reductase protein. Activities for acyl-coenzyme A:cholesterol acyl transferase (ACAT), a rate-limiting enzyme for cholesterol esterification, were greater (P < 0.05) at early and mid pregnancy in placental homogenates than in those from late pregnancy, while ACAT-1 mRNA concentrations and cholesterol ester hydrolase activity remained unchanged. These results, taken together, suggest that although de novo synthesis has the potential to provide a measure of the cholesterol used for placental progesterone production during early baboon pregnancy, its contribution declines with advancing gestational age as LDL receptor-derived cholesterol becomes the major source of substrate. Changes in LDL receptor mRNA abundance suggest differences in mechanisms regulating cholesterol homeostasis in steroidogenically active syncytiotrophoblasts vs. proliferative nonendocrine cell types in the placenta.

Serum leptin concentrations and expression of leptin transcripts in placental trophoblast with advancing baboon pregnancy.

Leptin is a polypeptide hormone originally thought to be produced exclusively by adipocytes. Recently, however, both leptin messenger ribonucleic acid (mRNA) and leptin protein were identified in human placental trophoblast cells, suggesting a potential role in primate pregnancy. In the present study, venous blood samples were collected at 5-day intervals during gestation from baboons (Papio sp), an established model for the study of human pregnancy, as well as from nonpregnant baboons, and leptin concentrations were determined by RIA. Additionally, placental villous tissue was collected upon cesarean delivery at early (days 60-62; n = 5), mid (days 98-102; n = 5), and late (days 159-167; n = 5) gestation (term = approximately 184 days), and leptin mRNA was quantitated by competitive RT-PCR. Finally, in situ hybridization was employed to localize transcripts to specific placental cell types. Results determined that maternal leptin levels (mean +/- SEM), which were dramatically greater (P<0.01) than those in nonpregnant cycling baboons (1.4+/-0.1 ng/mL), increased (P<0.005) with gestational age from 63.6+/-10.4 ng/mL on day 60 of gestation to 157.8+/-16.1 near term. Levels declined to those found in cycling baboons by 15 days postdelivery. In contrast to maternal leptin concentrations, placental leptin mRNA decreased (P<0.02) with advancing pregnancy, as transcript abundance declined approximately 8-fold from early to late gestation. Maternal peripheral leptin concentrations were positively correlated (r = 0.66; P<0.001) whereas placental leptin mRNA levels were negatively correlated (r = -0.64; P<0.01) with gestational age. Expression of leptin mRNA transcripts, as evidenced by RT-PCR in villous tissue, was localized principally within syncytiotrophoblast by in situ hybridization. In summary, changes in maternal peripheral leptin concentrations and placental leptin mRNA abundance that occur commensurate with advancing gestational age may imply evolving roles for the polypeptide with advancing primate pregnancy. In this capacity, localization of leptin transcripts within the baboon syncytiotrophoblast suggests the potential for autocrine or paracrine interactions within this endocrinologically active tissue. Finally, both the similarities in leptin ontogeny in baboon and human pregnancy and the singular enhancement of maternal leptin levels inherent throughout baboon gestation emphasize the potential of this nonhuman primate model for the study of leptin action in the maternal-fetoplacental unit.

Expression of placental leptin and leptin receptor transcripts in early pregnancy and at term.

OBJECTIVE: To demonstrate the expression of messenger RNA (mRNA) transcripts for placental leptin and leptin receptor in early gestation and at term, to quantitate transcriptional changes relative to stage of gestation, to localize transcripts within specific placental cell types, and to determine if transcripts also are expressed in cultured cells. METHODS: Expression of leptin and leptin receptor was assessed by reverse transcriptase-polymerase chain reaction, and leptin quantitated against a leptin mRNA competitor (MIMIC), in human placental villous tissue collected at term cesarean deliveries and earlier during gestation (7-14 weeks) upon elective terminations. In situ hybridization was used to identify cell types exhibiting transcripts for genes of interest. Additionally, tissue was dispersed enzymatically, cytotrophoblast cells progressed to syncytiotrophoblastic maturity in culture, and transcripts were assessed. RESULTS: Placental leptin and leptin receptor transcripts were identified in early (n = 6) and late (n = 5) gestation. Although no changes (P > .05) were apparent for receptor, leptin mRNA declined (P < .005) from (mean+/-standard error) 1.815+/-.491 attomoles/microg total RNA early in gestation to .013+/-.003 attomoles/microg total RNA at term. Leptin and leptin receptor transcripts were localized in trophoblast by in situ hybridization and were expressed in culture. CONCLUSION: Results suggest an ontogenetic decline in leptin mRNA with advancing gestation. Localization of leptin and leptin receptor transcripts in syncytiotrophoblasts, cells also responsible for the production of hormones vital to pregnancy maintenance, suggest a potential for autocrine or paracrine interactions within this tissue. Finally, transcript expression in cultured cells suggests the suitability of in vitro paradigms for future studies of leptin in pregnancy.