The effect of folate deficiency on placental function

Baker, Bernadette

January 2016

Insufficient maternal folate during pregnancy increases the risk of the baby being small for gestational age (SGA). Studies in teenagers, a population vulnerable to folate deficiency and SGA birth, have shown that low maternal folate status is associated with impaired placental cell turnover and reduced transport suggesting placental dysfunction underlies SGA in maternal folate deficiency. Mechanisms through which folate-depletion compromises placental function are currently unknown. In non-placental cells, folate modulates microRNAs (miRs), post-transcriptional regulators of cellular functions. Expression of miRs is altered in placentas of SGA compared to normally grown babies but there are no data on differential miR expression or regulation in placentas from folate deficient women. This PhD investigated the hypothesis that placental dysfunction observed in folate deficient women is mediated by altered miR expression. Three placental preparations were compared (villous tissue in explant culture, BeWo choriocarcinoma cells and isolated cytotrophoblast cells) to determine the optimum in vitro system to study the direct effects of folate deficiency. In cytotrophoblast cells, folate deficiency significantly elevated apoptosis and reduced the activity of the system A amino acid transporter, consistent with observations in the placentas of folate-deficient teenagers. The reduction in system A activity by low folate was not associated with altered mRNA expression for the isoforms of system A, implicating an effect of low folate on post-translational regulation of the nutrient transporter. Targeted examination of villous tissue from teenagers with low folate status identified up-regulation of miR-222-3p a folate-sensitive miR. An unbiased miR array identified up-regulation of a further 16 miRs suggesting that maternal folate deficiency in vivo results in aberrant placental miR expression. Bioinformatic analysis of the folate sensitive miRs predicted gene targets known to be altered in placentas from SGA pregnancy that were likely to alter placental function. Two miRs altered in placentas from women with low folate status, miR-30e-3p and miR-34b-5p, were also significantly altered in folate deficient cytotrophoblasts confirming a direct effect of folate on trophoblast miR expression. Inhibition of these miRs in vitro had no effects on placental functions that are altered in vivo in folate-deficient women. Gene array and in silico analysis identified functional endpoints affected by these folate sensitive miRs, including cell signalling for proliferation and survival and oxidative stress, which might contribute to placental dysfunction in folate deplete women. Overall, this study has demonstrated for the first time that folate deficient conditions can directly alter trophoblast system A transport and cell survival and thus could contribute to the increased susceptibility to SGA births in folate deficient women. It has also contributed to the knowledge that miR expression is differentially altered in placentas exposed to folate-deficient versus sufficient conditions in vivo and that miRs are directly altered by folate depletion in vitro. These studies provide the foundation for future research to define the functional consequences of altered expression of folate-sensitive miRs and their target genes to explain how altered miRs could be affecting placental function resulting in development of SGA.

618.3

Effects of glucocorticoids on placental development and function : implications for fetal growth restriction

Nugent, Justine Lucy

January 2012

Fetal growth restriction (FGR) signifies that the fetus has not achieved its growth potential and is associated with increased perinatal mortality and morbidity. The exact aetiology of FGR, in the absence of any identifiable fetal and maternal factors, remains unclear and is attributed to placental insufficiency. The FGR placenta has a characteristic phenotype including: increased resistance in the fetoplacental circulation, an alteration in trophoblast cell turnover and reduced activity of placental nutrient transport systems, the best characterised being the amino acid transporter, system A. The placenta strongly expresses the cortisol inactivating enzyme, 11β-hydroxysteroid dehydrogenase type 2 (11β-HSD2). 11β-HSD2 activity was reduced in placentas from pregnancies complicated by FGR, suggesting increased exposure of the fetoplacental unit to maternal cortisol. In animal models, excessive exposure to glucocorticoids (GCs) is associated with a reduction in both fetal and placental weight. This reduction in placental weight was associated with abnormalities in placental function, consistent with those observed in the FGR placenta. This PhD investigated whether excess GC exposure during pregnancy is responsible placental insufficiency in human pregnancies and tested the hypotheses that excess GC exposure adversely affects placental vascular tone, trophoblast cell turnover and activity of the amino acid transporter, system A. Term placentas were collected from uncomplicated pregnancies and first trimester placental samples were obtained following elective surgical termination of pregnancy. Wire myography was used to explore the acute and chronic effects of GCs on term chorionic plate artery (CPA) function. The impact of GC treatment on trophoblast cell turnover in both first trimester and term placenta was investigated using the placental explant system. The effect of GCs on the activity of the system A transporter was also investigated in term explants and in isolated cytotrophoblasts where the expression of 11β-HSD2 was reduced using siRNA. Gene microarray studies on first trimester placental explants treated with GCs were utilised to identify genes regulated by GCs. Blunted constriction to thromboxane A2 was observed following acute GC treatment, whilst chronic exposure resulted in enhanced vasoconstriction, mimicking the altered reactivity of CPAs from pregnancies complicated by FGR. GC excess in first trimester placental explants increased apoptosis and decreased proliferation, thereby replicating the disordered turnover of the trophoblast observed in FGR placentas. No demonstrable effect was observed in cell turnover or system A activity in term placental explants treated with GCs, however, these experiments were hindered by the in-vitro regeneration of the syncytiotrophoblast in the model employed. The attenuation of 11β-HSD2 activity observed in FGR placentas was replicated in term primary cytotrophoblasts utilising siRNA to knock-down expression of 11β-HSD2. Preliminary results suggested an increase in system A activity in response to cortisol. Gene microarray studies identified a significant number of genes (~500) that were regulated by dexamethasone, confirming that GCs have an impact on many aspects of placental function. Potential mediators for the characteristic features of the FGR placenta replicated here in response to GC treatment were identified and validated at the mRNA level. The studies described in this thesis support the hypotheses that GC excess within the placenta contributes to the development of raised vascular resistance in the fetoplacental circulation and the disordered trophoblast turnover in placentas from pregnancies complicated by FGR. However, with the preliminary studies performed, the hypothesis that elevated levels of GCs contribute to the reduced placental amino acid transfer by the system A transporter in the FGR placenta can not be confidently disproven.

618.34

Development of placental ultrasound markers to screen for the term, small for gestational age (SGA) baby

Collins, Sally

January 2012

No description available.

Antenatal sildenafil citrate treatment in a mouse model of fetal growth restriction : effects on fetus and offspring

Renshall, Lewis

January 2015

Fetal growth restriction (FGR), when a fetus fails to reach its genetic growth potential, affects up to 10 % of pregnancies and is a major risk factor for both neonatal and adulthood morbidity and mortality. There are currently no treatments for FGR except for delivery of the fetus; resulting in premature delivery which, in itself, is linked to poor outcome. Therefore, the focus of current research is to examine whether therapies successfully used to treat diseases with similar aetiologies to FGR can also be used to treat FGR. Sildenafil citrate (SC), a selective phosphodiesterase-5 inhibitor, is one such candidate. With the recent announcement of the STRIDER international clinical trial for the treatment of severe FGR with SC, it is imperative to determine the efficacy and safety of SC treatment on both fetus in utero and long-term adult health. Mouse models that mimic characteristics of human FGR represent an attractive model to perform pre-clinical studies. Recent studies in mice have demonstrated that SC increased fetal and placental weight and normalised umbilical artery blood flow velocity in FGR but no studies have assessed effects of antenatal SC on offspring health. The aims of this study were to assess the effect of antenatal SC treatment on a) fetal weight b) fetal vascular reactivity b) pup viability and d) long-term effects on postnatal development/physiology in a mouse model of FGR.All experiments were performed in the placental-specific insulin-like growth factor 2 knockout mouse (Igf2 P0+/- mice) which have mixed litters of wild-type (WT) and growth restricted (P0) mice. It has been reported that SC administered in the drinking water was able to increase P0 fetal weight and thus this mouse model was chosen to assess the effects of SC on the fetus and offspring. SC was administered to pregnant dams in two regimens; orally (120 – 160 mg.kg-1) and subcutaneously (10 mg.kg-1) between E12.5 and E18.5. WT and P0 fetal abdominal aortas were isolated at E18.5 and ex vivo vascular function was assessed using wire myography. Fetal abdominal aortas demonstrated reliable and reproducible vasocontraction and vasorelaxation; there were some sex- and genotype-specific differences. SC demonstrated dose-dependent effects on fetal aortic function. Offspring from dams treated with a subcutaneous injection of SC or saline were assessed for postnatal growth (week 5 – week 12), systolic blood pressure (week 8 and week 13), glucose tolerance (week 12) and mesenteric / aortic vascular function (week 14 – week 16). These experiments demonstrated that;• A supratherapeutic concentration of antenatal SC (120 – 160 mg.kg-1) did not increase fetal weight but significantly blunted relaxation responses of fetal abdominal aortas at E18.5. • A subcutaneous injection of antenatal SC (10 mg.kg-1) did not increase fetal weight or alter fetal abdominal aortic function in mice but led to increased systolic blood pressure in both WT and P0 offspring. Additionally, glucose sensitivity was significantly reduced in female offspring from SC treated dams. In conclusion, the studies outlined in this thesis have demonstrated that antenatal SC treatment can cause alterations in fetal blood vessel function and also lead to changes in metabolic and cardiovascular function in mouse offspring. Using ex vivo wire myography, mouse fetal abdominal aortas were able to be assessed at E18.5. This methodological advance will be beneficial as it can be applied to assessing putative treatments in mice that show characteristics of human FGR. In addition, this technique will allow for investigation of the underlying mechanisms of in utero programming of adulthood cardiovascular diseases such as hypertension. Future work must focus on the mechanisms leading to increased systolic blood pressure in offspring from SC treated dams and whether such effects are noted in other animal models of FGR using a variety of SC dosing regimens. These studies will provide information with which to increase efficacy, and ensure the safety, of SC treatment in pregnancy complications.

612.6

Reproductive Ecology of White-Tailed Deer: Fetal Development and Mate Choice

Morina, Daniel L

10 August 2018

Aspects of white-tailed deer (Odocoileus virginianus) reproductive ecology remain understudied. The accuracy of the fetal age estimation equation in current use is unknown. Knowledge is also limited for female choice of secondary sexual traits like antlers and body size. To address previous fetal estimation equations, I developed a model that included litter characteristics using 110 fetuses with known ages of 54 to 175 days. To address female choice, I manipulated antler size and paired large and small males while controlling allometrically related traits. I then allowed estrus females to choose between pairs of segregated males with either large and small antlers or large and small bodies. My predictive fetal aging model generated more accurate fetal ages under a range of sample timing and composition variation. Using various behavioral indications of choice, I demonstrated that females prefer males with larger antlers and lack a preference for body size or age.

antlers

sexual selection

mate choice

fetal growth

Prolactine placentaire et anomalies de croissance au cours du diabète maternel / Placental prolactin and growth disorders during maternal diabetes

Perimenis, Pierrette

20 September 2014

Malgré l’amélioration des prises en charge diabétologiques et obstétricales, la grossesse chez la patiente ayant un diabète pré-gestationnel ou gestationnel reste à ce jour à haut risque pour la mère et pour l’enfant. Chez l’enfant, les anomalies de croissance, macrosomie, mais parfois Retard de Croissance Intra-Utérin (RCIU) restent à ce jour très fréquentes avec des conséquences à court et à long terme. La croissance fœtale est un processus complexe mettant en jeu la susceptibilité génétique fœtale mais surtout le milieu intra-utérin à savoir l’environnement métabolique maternel et placentaire. Les mécanismes physiopathologiques en lien avec ces anomalies de croissance dans ce contexte de diabète restent encore incompris et mal expliqués par l’hyperglycémie maternelle seule. A l’interface entre la mère et le fœtus, le placenta exerce plusieurs fonctions influençant le métabolisme maternel et fœto-placentaire donc le développement de l’unité fœto-placentaire. Le placenta, acteur crucial de la programmation fœtale, va s’adapter à son environnement afin de permettre la survie fœtale.L’objectif de ce travail de thèse était d’étudier le compartiment placentaire en analysant l’expression des gènes impliqués dans la croissance fœto-placentaire afin de déterminer des facteurs prédictifs des anomalies de croissance au cours du diabète maternel. Pour répondre à cet objectif, nous avons d'abord utilisé un modèle de rate gestante rendue diabétique par la streptozotocine seule ou associée avec la nicotinamide et validé certains de nos résultats dans des placentas issus de patientes diabétiques de type 1. L’analyse du transcriptome placentaire a mis en évidence l’implication prépondérante de certains gènes appartenant à la famille prolactine (PRL), au système rénine-angiotensine et aux métalloprotéases. La caractéristique phénotypique de ces ratons était de présenter un RCIU à la naissance avec sur le plan histologique une hypovascularisation placentaire associée.Nous nous sommes surtout intéressés aux gènes placentaires appartenant à la famille PRL, non décrits auparavant dans la littérature dans le diabète, comme prl8a2, connu aussi sous le nom de Dprp (Decidual Prolactin Related-Protein). La PRL dans sa forme native de 23-kDa a des propriétés pro-angiogéniques alors que clivée en vasoinhibines par la Bone morphogenetic protein1 (BMP1), la cathepsine D, a des propriétés anti-angiogéniques. Chez nos 2 modèles de rates, nous confirmons une surexpression par qPCR de Dprp, et de Bmp1 et une augmentation du rapport du clivage de la PRL et donc des vasoinhibines par rapport aux contrôles.Nous avons pu valider ces résultats dans des placentas de patientes diabétiques de type 1 dont la caractéristique chez les nouveaux nés était un petit poids de naissance. Enfin, nous nous sommes intéressés à la cinétique de ces anomalies concernant la famille PRL dans nos modèles animaux. Nous avons pu montrer chez la rate gestante diabétique que le RCIU était présent dès le 14ème jour de gestation et que la quantité en vasoinhibines et l’expression des gènes Bmp1 et Dprp n'étaient modifiées qu'à partir du 17ème jour de gestation.Ces travaux sont en faveur d’une implication de la PRL placentaire et de ses vasoinhibines dans le diabète maternel laissant leur supposer un rôle dans l’hypovascularisation placentaire, mise en évidence à la fois chez l'homme et l'animal. En perspective, nous envisageons de poursuivre ces travaux avec une approche plus fonctionnelle. Il convient de préciser l’implication de la BMP1 en confirmant sa responsabilité dans le clivage de la PRL, en analysant plus finement la relation entre vasoinhibines et hyperglycémie en tenant compte du degré et de la durée d’exposition de l'hyperglycémie. Enfin, il serait intéressant de regarder l’implication de la PRL placentaire non plus au cours du RCIU mais plutôt au cours de la macrosomie fœtale, qui reste l’anomalie de croissance la plus fréquente au cours du diabète maternel. / Despite the improvement of obstetrical and diabetological care, the pregnancy of the patient presenting a gestational or pregestational diabetes remains ourdays at a high risk for the mother and for its child. For the child, fetal growth disorders such as macrosomia but also intra-uterine growth restriction (IUGR) are still very frequent with short and long-term consequences. Fetal growth is a complex process involving the fetal genetic susceptibility but also the intra-uterine environment especially in its maternal and placental metabolic aspects. The link between the physiopathological mechanisms of these disorders and fetal growth in this context of maternal diabetes remains unclear and partially explained by maternal hyperglycemia only. At an interface between the mother and the fetus, the placenta employes multiples functions that influence maternal, fetal and placental metabolisms and consequently the fetoplacental unit development. The placenta, as crucial actor of fetal programming, must adapt to its environnment for the survival of the fetus.The objectives of this thesis were to study the placental compartment with an analysis of expression of genes involved in feto-placental growth to determine the predictive factors of these growth disorders during maternal diabetes. To bring a response to these objectives, we used initially a model of gestant rat diabetes induced by streptozotocin alone or in combination with nicotinamide and we validated some of our results in the placenta from type 1 diabetic mothers.The placental transcriptomic analysis pointed out the involvment of some genes of the prolactin (PRL) family, of the renine-angiotensin-aldosterone system and of metalloproteinase family. The principal phenotypical characteristic of the pups at birth was an IUGR with an histological aspect of a placental hypovascularization associated.We focused especially to the placental genes of the PRL familly, non described before in the litterature in diabetes, such as prl8a2 also known as Dprp (decidual prolactin related-protein). PRL in its native form of 23 kDa is proangiogenic but when processed by Bone morphogenetic protein 1 (BMP-1) or cathepsin D (CTSD) to vasoinhibins has antiangiogenic properties. In our 2 rat models, we demonstrated by qPCR an upregulation of Bmp-1 and Dprp with an increase amount of vasoinhibins when compared to controls.We could validate some of our results in the placenta from diabetic type 1 women with a characteristic of small birth weight of the newborns.Finally, we interested in the course of these disorders concerning PRL family in our animal models during their pregnancy. We could demonstrate that IUGR was present by 14th day of gestation. Bmp-1 or Dprp gene expression and the vasoinhibin amount were not different between groups at the 14th day of gestation but modified by 17th day of gestation.These studies highlighted a placental involvment of PRL and its vasoinhibins during maternal diabetes suggesting a role in placental hypovascularisation in animal and women.The perspectives will be in continuing these studies with a more functional approach. We have to bring more details about the involvment of BMP-1 in this PRL process with an in-depth analysis of the link between hyperglycemia and vasoinhibins among the degree and the time of exposition to hyperglycemia. Finally, it would be interesting to study the involvment of placental PRL not only in the cases of IUGR but also in that of macrosomia, that remains the most frequent fetal growth disorder during maternal diabetes.

Prolactine

Diabète gestationnel

Placenta

Développement foetal

Croissance foetale

Fetal growth disorders

Gestational diabetes

Fetal growth

A pilot study on potential involvement of epigenetic regulations secondary to perturbed intrauterine environment

Lam, Shih-en., 林詩恩.

January 2008

published_or_final_version / Paediatrics and Adolescent Medicine / Master / Master of Philosophy

Epigenetics.

Genetic regulation.

DNA - Methylation.

Fetus - Growth.

Fetal growth retardation.

Placental restriction and endocrine control of postnatal growth

De Blasio, Miles Jonathon.

January 2004

Includes list of papers arising from this thesis. "July 2004" Includes bibliographical references (leaves 253-297)

Fetus Growth

Fetal growth retardation

Pregnancy Complications

Prenatal diagnosis

Epigenetic rRgulation in the Placenta and its Role in Fetal Growth

Pinto Barreto Ferreira, Jose Carlos

11 January 2012

Fetal growth potential reflects a complex regulatory system delivered by genetic and environmental factors acting directly on the fetus or through the placenta. Compromise of this potential, as seen in intrauterine growth restriction (IUGR), is associated with increased perinatal mortality and short and long term morbidity. The expression of several genes has been shown to be disturbed in placentas of fetuses with growth restriction. However, the primary causes for these changes have not yet been elucidated. I proposed that epigenetic mechanisms, specifically DNA methylation, may be involved in placental development leading to modulation of the expression of specific genes, and that their altered regulation will impact fetal development and growth. My primary objective was to identify DNA methylation variation in placenta, in association with variation of gene expression and with poor fetal growth. I used a global genomic screening approach, with 24 selected placental samples, from newborns considered IUGR or normal controls, to identify candidate target genomic regions carrying epigenetic alterations. Candidate regions were followed up, by expression analysis of corresponding regulated genes, for associations with altered expression and by targeted methylation analysis in an expanded cohort of 170 samples, for associations with birthweight percentile. I analyzed methylation variation at imprinting centers (IC), gene promoters and CpG islands. In two genome-wide case control screening studies using distinct commercial microarray platforms I identified approximately 68 differentially methylated autosomal candidate genomic regions overlapping gene promoters. Hypomethylated CpGs mapping to gene promoters were found to be more abundant in placentas of growth restricted newborns than in controls. One of the most interesting candidates, WNT2, was analyzed in an extended sample cohort and showed an association of high promoter methylation to low expression as well as low birthweight percentile. This gene is involved in a pathway that diverts cells from programmed apoptosis. It is highly expressed in placenta, and in mice, targeted biallelic inactivation of Wnt2 has been shown to cause poor growth and perinatal death in 50% of the affected pups. These findings support the hypothesis that dysregulation of epigenetic mechanisms are involved in abnormal placental development and can impact fetal growth.

Epigenetics

DNA methylation

Placenta

Fetal growth

0758

0307

0369

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Epigenetic rRgulation in the Placenta and its Role in Fetal Growth

Pinto Barreto Ferreira, Jose Carlos

11 January 2012

Fetal growth potential reflects a complex regulatory system delivered by genetic and environmental factors acting directly on the fetus or through the placenta. Compromise of this potential, as seen in intrauterine growth restriction (IUGR), is associated with increased perinatal mortality and short and long term morbidity. The expression of several genes has been shown to be disturbed in placentas of fetuses with growth restriction. However, the primary causes for these changes have not yet been elucidated. I proposed that epigenetic mechanisms, specifically DNA methylation, may be involved in placental development leading to modulation of the expression of specific genes, and that their altered regulation will impact fetal development and growth. My primary objective was to identify DNA methylation variation in placenta, in association with variation of gene expression and with poor fetal growth. I used a global genomic screening approach, with 24 selected placental samples, from newborns considered IUGR or normal controls, to identify candidate target genomic regions carrying epigenetic alterations. Candidate regions were followed up, by expression analysis of corresponding regulated genes, for associations with altered expression and by targeted methylation analysis in an expanded cohort of 170 samples, for associations with birthweight percentile. I analyzed methylation variation at imprinting centers (IC), gene promoters and CpG islands. In two genome-wide case control screening studies using distinct commercial microarray platforms I identified approximately 68 differentially methylated autosomal candidate genomic regions overlapping gene promoters. Hypomethylated CpGs mapping to gene promoters were found to be more abundant in placentas of growth restricted newborns than in controls. One of the most interesting candidates, WNT2, was analyzed in an extended sample cohort and showed an association of high promoter methylation to low expression as well as low birthweight percentile. This gene is involved in a pathway that diverts cells from programmed apoptosis. It is highly expressed in placenta, and in mice, targeted biallelic inactivation of Wnt2 has been shown to cause poor growth and perinatal death in 50% of the affected pups. These findings support the hypothesis that dysregulation of epigenetic mechanisms are involved in abnormal placental development and can impact fetal growth.

Epigenetics

DNA methylation

Placenta

Fetal growth

0758

0307

0369

0380