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BACKGROUND: The prevalence of maternal obesity is rising rapidly worldwide and constitutes a major obstetric problem, increasing mortality and morbidity in both mother and offspring. Obese women are predisposed to pregnancy complications such as gestational diabetes mellitus (GDM), and children of obese mothers are more likely to develop cardiovascular and metabolic disease in later life. Maternal obesity and GDM may be associated with a state of chronic, low-grade inflammation termed "metainflammation", as opposed to an acute inflammatory response. This inflammatory environment may be one mechanism by which offspring of obese women are programmed to develop adult disorders. METHODS: Herein we review the evidence that maternal obesity and GDM are associated with changes in the maternal, fetal and placental inflammatory profile. RESULTS: Maternal inflammation in obesity and GDM may not always be associated with fetal inflammation. CONCLUSION: We propose that the placenta 'senses' and adapts to the maternal inflammatory environment, and plays a central role as both a target and producer of inflammatory mediators. In this manner, maternal obesity and GDM may indirectly program the fetus for later disease by influencing placental function.

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INTRODUCTION: Labor induces a myriad of changes in placental gene expression. These changes may represent a physiological adaptation inhibiting placental cellular processes associated with a high demand for oxygen and energy (e.g., protein synthesis and active transport) thereby promoting oxygen and glucose transfer to the fetus. We hypothesized that mechanistic target of rapamycin complex 1 (mTORC1) signaling, a positive regulator of trophoblast protein synthesis and amino acid transport, is inhibited by labor. METHODS: Placental tissue was collected from healthy, term pregnancies (n = 15 no-labor; n = 12 labor). Activation of Caspase-1, IRS1/Akt, STAT, mTOR, and inflammatory signaling pathways was determined by Western blot. NFĸB p65 and PPARγ DNA binding activity was measured in isolated nuclei. RESULTS: Labor increased Caspase-1 activation and mTOR complex 2 signaling, as measured by phosphorylation of Akt (S473). However, mTORC1 signaling was inhibited in response to labor as evidenced by decreased phosphorylation of mTOR (S2448) and 4EBP1 (T37/46 and T70). Labor also decreased NFĸB and PPARγ DNA binding activity, while having no effect on IRS1 or STAT signaling pathway. DISCUSSION AND CONCLUSION: Several placental signaling pathways are affected by labor, which has implications for experimental design in studies of placental signaling. Inhibition of placental mTORC1 signaling in response to labor may serve to down-regulate protein synthesis and amino acid transport, processes that account for a large share of placental oxygen and glucose consumption. We speculate that this response preserves glucose and oxygen for transfer to the fetus during the stressful events of labor.

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Workshops are an important part of the IFPA annual meeting as they allow for discussion of specialized topics. At IFPA meeting 2013 there were twelve themed workshops, four of which are summarized in this report. These workshops related to various aspects of placental biology but collectively covered areas of pregnancy pathologies and placental metabolism: 1) diabetes in pregnancy; 2) lipids, fatty acids and the placenta; 3) oxygen in placental development and pathologies; 4) stem cells and pathologies.

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Adiponectin has well-established insulin-sensitizing effects in non-pregnant individuals. Pregnant women who are obese or have gestational diabetes typically have low circulating levels of adiponectin, which is associated with increased fetal growth. Lean women, on the other hand, have high circulating levels of adiponectin. As a result, maternal serum adiponectin is inversely correlated to fetal growth across the full range of birth weights, suggesting that maternal adiponectin may limit fetal growth. In the mother, adiponectin is predicted to promote insulin sensitivity and stimulate glucose uptake in maternal skeletal muscle thereby reducing nutrient availability for placental transfer. Adiponectin prevents insulin-stimulated amino acid uptake in cultured primary human trophoblast cells by modulating insulin receptor substrate phosphorylation. Furthermore, chronic administration of adiponectin to pregnant mice inhibits placental insulin and mammalian target of rapamycin complex 1 (mTORC1) signaling, down-regulates the activity and expression of key placental nutrient transporters and decreases fetal growth. Preliminary findings indicate that adiponectin binds to the adiponectin receptor-2 on the trophoblast cell and activates p38 MAPK and PPAR-α, which inhibits the insulin/IGF-1 signaling pathway. In contrast to maternal adiponectin, recent reports suggest that fetal adiponectin may promote expansion of adipose tissue and stimulate fetal growth. Regulation of placental function by adiponectin constitutes a novel physiological mechanism by which the endocrine functions of maternal adipose tissue influence fetal growth. These findings may help us better understand the factors determining birth weight in normal pregnancies and in pregnancy complications associated with altered maternal adiponectin levels such as obesity and gestational diabetes.

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Nutrient-sensing signaling pathways regulate cell metabolism and growth in response to altered nutrient levels and growth factor signaling. Because trophoblast cell metabolism and associated signaling influence fetal nutrient availability, trophoblast nutrient sensors may have a unique role in regulating fetal growth. We review data in support of a role for mammalian target of rapamycin complex 1 (mTORC1) in placental nutrient-sensing. Placental insulin/IGF-I signaling and fetal levels of oxygen, glucose and amino acids (AAs) are altered in pregnancy complications such as intrauterine growth restriction, and all these factors are well-established upstream regulators of mTORC1. Furthermore, mTORC1 is a positive regulator of placental AA transporters, suggesting that trophoblast mTORC1 modulates AA transfer across the placenta. In addition, placental mTORC1 signaling is also known to be modulated in pregnancy complications associated with altered fetal growth and in animal models in which maternal nutrient availability has been altered experimentally. Recently, significant progress has been made in identifying the molecular mechanisms by which mTORC1 senses AAs, a process requiring shuttling of mTOR to late endosomal and lysosomal compartments (LELs). We recently identified members of the proton-assisted amino acid transporter (PAT/SLC36) family as critical components of the AA-sensing system or 'nutrisome' that regulates mTORC1 on LEL membranes, placing AA transporters and their subcellular regulation both upstream and downstream of mTORC1-driven processes. We propose a model in which placental mTORC1 signaling constitutes a critical link between maternal nutrient availability and fetal growth, thereby influencing the long-term health of the fetus.

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Oxygenated cholesterol metabolites known as oxysterols display potent biological activities ranging from regulation of lipid homeostasis to cytotoxicity. Oxysterols have previously been shown to inhibit the invasion of first trimester trophoblasts, an effect which involves activation of the nuclear liver X receptors (LXRs). In the present study, we investigated the effects of several oxysterols on syncytialisation (differentiation and fusion) in term placental trophoblasts. Treatment of cultured term primary trophoblast cells with oxysterols [25-hydroxycholesterol, 7-ketocholesterol, 22(R)-hydroxycholesterol] and the synthetic LXR agonist T0901317 at non-toxic doses decreased expression of GCM-1 and HERV-W mRNA and reduced hCG secretion and placental alkaline phosphatase activity, indicative of diminished trophoblast differentiation. Furthermore, treatment with these compounds also decreased cell fusion measured by E-cadherin immunostaining and quantification of syncytialised nuclei. Treatment with an LXR antagonist (geranylgeranyl diphosphate) abrogated the inhibitory effects of oxysterols and T0901317 on trophoblast syncytialisation indicating that these effects are mediated by LXR. These findings suggest that oxysterols impair differentiation and fusion of term trophoblast cells via an LXR-dependent mechanism.

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Placental ATP-binding cassette (ABC) transporters limit fetal exposure to xenobiotics by regulating transplacental passage into the fetal circulation; their expression and function in fetal membranes, however, has not been studied. In the present study the expression, localisation and function of ABC transporters in human amnion was examined to explore their potential role in modulating amniotic fluid drug disposition in pregnancy. Single-assay oligo-microarrays were used to profile amnion gene expression, and drug transporters expressed at significant levels were identified and selected for further studies. The expression of ABCG2/breast cancer resistance protein (BCRP) and multidrug resistance-associated proteins (MRP) 1 (ABCC1), 2 (ABCC2) and 5 (ABCC5) was detected on the arrays, and verified by RT-PCR and immunoblotting. On confocal microscopy of fetal membrane cryosections, MRP1 and MRP5 were immunolocalised to both apical and basolateral surfaces of the amniotic epithelium, while MRP2 was expressed at low levels only in the apical membrane. BCRP in contrast showed cytoplasmic staining throughout the amniotic epithelium. In addition to the amnion, MRP1 and BCRP immunostaining was observed in the chorion and the decidua. Cell accumulation studies using selective MRP and BCRP inhibitors showed the transporters to be functionally active in amnion epithelial monolayer cultures. In contrast, transwell transport studies using intact amnion membranes did not show significant vectorial transport. These findings identify the amnion as a novel site of ABC drug transporter expression. Functional studies indicate that they may act primarily to prevent cellular xenobiotic accumulation, rather than to confer fetal protection through reduced accumulation in amniotic fluid.

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