Project description:Selective serotonin reuptake inhibitors (SSRIs) are commonly prescribed drugs to pregnant women experiencing depression. While such drugs might be beneficial in combating depression by competitively binding to serotonin transporter (SERT), they can adversely affect the placenta and fetal brain development. Parietal trophoblast giant cells (pTGCs) in the mouse placenta are postulated to internalize maternal serotonin (5-HT) via transport through SERT, encoded by Slc6a4. The placenta provides the initial source of 5-HT to the emerging brain via the placental-brain axis. Disruption of 5-HT acquisition by pTGCs due to genetic deletion of Slc6a4 is hypothesized to impact placental and fetal brain development. A transgenic mouse line with the SERT transporter selectively deleted was created by pairing mice with Cre-recombinase linked to proliferin (Prl2c2) with LoxP sites flanking the Slc6a4 gene. Proliferin is solely expressed by pTGCs and other giant cells of the placenta. To compare placental and fetal brain development in selective Sl6a4 KO and WT mice, 5-HT content in the placenta and fetal brains of the mice was measured. No significant differences in 5-HT content were evident between knockout (KO) and wild-type (WT) placenta and fetal brain. However, there was significantly lower average number of pTGCs in KO placentas compared to WT (p ≤ 0.05). Sexually dimorphic differences in gene expression were evident in the placenta and fetal brain between KO and WT counterparts with female conceptuses showing the most dramatic responses. Findings suggest that ablation of SERT in pTGC disrupts the placenta-brain axis in a sex-dependent manner. These results might have important clinical ramifications for pregnant women being treated with SSRIs.

Project description:Obese women who develop gestational diabetes show lower adiponectin levels across pregnancy than obese euglycemic women suggesting that obese women with low adiponectin levels have an impaired capacity to handle the metabolic changes during pregnancy. Adiponectin acts on the placenta during pregnancy; this fact allows for the interesting possibility that adiponectin can exert endocrine effects on the developing fetus. The aim was to investigate how adiponectin affects fetal growth, placenta function and metabolic functions during pregnancy. Wild-type (wt) and adiponectin transgenic (APNtg) mice were fed normal chow or a high fat/high sucrose (HF/HS) diet for 8 weeks before mating. Dams and fetuses were dissected at gestational day 18.5. Maternal adiponectin overexpression decreased fetal body weight in dams on normal chow, and even more in dams on HF/HS diet. Pools of two placentas or two livers from one male and one female fetus with the same genotype (wt or APNtg) from the same dam on HF/HS diet were used in proteomic analysis, and a total of five pools per group (wt-wt, wt-APNtg, APNtg-wt, APNtg-APNtg) were included in the liquid chromatography-tandem mass spectrometry (LS-MS/MS) analysis. In total, 7290 proteins were identified in placenta, and 7301 proteins in fetal liver. Next, we analyzed phosphosites, in total,19264 sites were identified in placenta proteins and 15334 sites were identified in fetal liver proteins. We then applied pathway analysis to the total protein and phosphopeptide data using PRISM and Enrichr.

Project description:Background: Maternal iron deficiency (ID) is associated with poor pregnancy and fetal outcomes. The effect is thought to be mediated by the placenta but there is no comprehensive assessment of placental response to maternal ID. Additionally, whether the influence of maternal ID on the placenta differs by fetal sex is unknown. Objectives: Our primary aim was to identify gene and protein signatures of ID mouse placentas at mid-gestation. A secondary objective was to profile the expression of iron genes in mouse placentas across gestation. Methods: We used a real-time PCR based array to determine the mRNA expression of all known iron genes in mouse placentas at embryonic day (E) 12.5, E14.5, E16.5, and E19.5 (n=3 placentas/time point). To determine the effect of maternal ID, we performed RNA sequencing and proteomics in male and female placentas from ID and iron adequate mice at E12.5 (n=8 dams/diet). Results: In female placentas, six genes including transferrin receptor (Tfrc) and solute carrier family 11 member 2 were significantly changed by maternal ID. An additional 154 genes were altered in male ID placentas. Proteomic analysis quantified 7662 proteins in the placenta. Proteins translated from iron responsive element (IRE) containing mRNAs were altered in abundance; ferritin and ferroportin 1 decreased while TFRC increased in ID placenta. Less than 4% of the significantly altered genes in ID placentas occurred both at the transcriptional and translational levels. Conclusions: Our data demonstrate that the impact of maternal ID on placental gene expression in mice is limited in scope and magnitude at mid-gestation. We provide strong evidence for IRE-based transcriptional and translational coordination of iron gene expression in the mouse placenta. Finally, we discover sexually dimorphic effects of maternal ID on placental gene expression, with more genes and pathways altered in male compared with female mouse placentas.

Project description:Gut microbiota play an important role in regulating individual health. It is also increasingly apparent that changes in maternal gut microbiota result can render her offspring more susceptible to diseases later in life. Such bacterial induced changes likely originate in the womb. As the placenta is the primary communication organ between mother and conceptus, it is vulnerable to in utero environmental changes, including those associated with maternal gut microbiota. The placenta also relays nutritional and other factors, including serotonin, to the developing fetal brain that help guide development of this organ. Thus, placental disruptions can influence the placenta-brain axis and subsequently neurobehavioral programming with potential long-term consequences. One mechanism by which changes in maternal gut microbiota might effect the placenta are through alterations in bacterial short chained fatty acids (SCFA). The hypothesis, thus, tested in the current studies is that absence of a maternal gut microbiota, as occurs in germ-free (GF) mice, would impact bacterial SCFA in her fecal samples and in the fetal placenta and brain. Secondarily, we tested whether transcriptomic changes would be evident in the placenta and fetal brain from conceptuses derived from GF relative to multi-pathogen free (MPF) pregnant females.

Project description:Serotonin in the mammary gland is known to regulate processes such as calcium homeostasis, tight junction permeability, and milk protein gene expression. The objective of this study was to discover novel genes, pathways and functions which serotonin modulates during lactation. The rate-limiting enzyme in the synthesis of non-neuronal serotonin is tryptophan-hydroxylase (TPH1). Therefore, we used TPH1 knock-out mice dams (serotonin deficient) and compared them to wild-type dams and also Tph1 deficient dams injected daily with 5-HTP. Mammary gland tissues were collected on day 10 of lactation and then analyzed by RNA sequencing. Genome-wide gene expression profiles of 12 mouse mammary gland samples were evaluated using RNA sequencing; these 12 samples belong to wild-type dams (WT; n = 4), Tryptophan hydroxylase (Tph1) knock-out dams (KO; Tph1 deficient; n = 4), and Tph1 deficient dams injected daily with 5-HTP (RC; n = 4). Mammary tissues were collected on day 10 of lactation and then underwent RNA extraction, library generation, and subsequent sequencing.

Project description:Advanced maternal age is a risk factor for neurodevelopmental disorders in offspring. The present study aimed to investigate differences in placental and fetal head gene expression between old and young C57BL6/J female mice. Conceptuses were collected at E12.5 and processed for transcriptomic mRNA gene expression microarray analyses. The most significant differences between old and young females were found in gene expression of the fetal heads (398 differentially expressed genes, DEG) as compared with the placenta (51 DEG).

Project description:Immune tolerance at the maternal-fetal interface is required for fetal development. Excessive maternal interferon gamma (IFNγ) and interleukin-17 (IL-17) is linked to pregnancy complications, but the regulation of maternal IFNγ and IL-17 at the maternal-fetal interface (MFI) is poorly understood. Here we demonstrate a gut-placenta immune axis in pregnant mice in which the absence or perturbation of gut microbiota dysregulates maternal IFNγ and IL-17 responses at the MFI, resulting in fetal resorption. Microbiota-dependent tryptophan derivatives suppress IFNγ+ and IL-17+ T cells at the MFI by priming myeloid-derived suppressor cells (MDSCs) and gut-derived RORγt+ Tregs, respectively. The tryptophan derivative indole-3-carbinol, or tryptophan-metabolizing Lactobacillus murinus, rebalances the T cell response at the MFI and reduces fetal resorption in germ-free mice. Furthermore, MDSCs, RORγt+ Tregs, and microbiota-dependent tryptophan derivatives are dysregulated at the MFI in human recurrent miscarriage cases. Together, our findings identify microbiota-dependent immune tolerance mechanisms that promote fetal development.

Project description:Serotonin in the mammary gland is known to regulate processes such as calcium homeostasis, tight junction permeability, and milk protein gene expression. The objective of this study was to discover novel genes, pathways and functions which serotonin modulates during lactation. The rate-limiting enzyme in the synthesis of non-neuronal serotonin is tryptophan-hydroxylase (TPH1). Therefore, we used TPH1 knock-out mice dams (serotonin deficient) and compared them to wild-type dams and also Tph1 deficient dams injected daily with 5-HTP. Mammary gland tissues were collected on day 10 of lactation and then analyzed by RNA sequencing.

Project description:The effects of maternal microbiota on the fetal development was investigated by comparing tissues of fetuses from germ-free (GF) and normal (SPF) murine dams using RNA-seq and non-targeted metabolomics (for metabolomics data, see: https://bmcmicrobiol.biomedcentral.com/articles/10.1186/s12866-022-02457-6). For RNA-seq, two E18.5 fetuses were collected from 6 GF dams and 6 SPF dams, and transcriptomes analyzed by QuantSeq in whole intestine, brain and placenta.

Project description:During pregnancy, the energy requirements of the fetus impose changes in maternal metabolism. Increasing insulin resistance in the mother maintains nutrient flow to the growing fetus, while prolactin and placental lactogen counterbalance this resistance and prevent maternal hyperglycemia by driving expansion of the maternal population of insulin-producing beta-cells. However, the exact mechanisms by which the lactogenic hormones drive beta-cell expansion remain uncertain. Here we show that serotonin acts downstream of lactogen signaling to drive beta-cell proliferation. Serotonin synthetic enzyme Tph1 and serotonin production increased sharply in beta-cells during pregnancy or after treatment with lactogens in vitro. Inhibition of serotonin synthesis by dietary tryptophan restriction or Tph inhibition blocked beta-cell expansion and induced glucose intolerance in pregnant mice without affecting insulin sensitivity. Expression of the Gq-linked serotonin receptor Htr2b in maternal islets increased during pregnancy and normalized just prior to parturition, while expression of the Gi-linked receptor Htr1d increased at the end of pregnancy and postpartum. Blocking Htr2b signaling in pregnant mice also blocked beta-cell expansion and caused glucose intolerance. These studies reveal an integrated signaling pathway linking beta-cell mass to anticipated insulin need during pregnancy. Modulators of this pathway, including medications and diet, may affect the risk of gestational diabetes. Analysis of poly(A)+ RNA from 3 biological replicates of pancreatic islets isolated from normal female and pregnant female mice