Your search keyword '"Bethany N. Radford"' showing total 8 results

1. Defects in placental syncytiotrophoblast cells are a common cause of developmental heart disease

Author

Bethany N. Radford, Xiang Zhao, Tali Glazer, Malcolm Eaton, Danielle Blackwell, Shuhiba Mohammad, Lucas Daniel Lo Vercio, Jay Devine, Tali Shalom-Barak, Benedikt Hallgrimsson, James C. Cross, Henry M. Sucov, Yaacov Barak, Wendy Dean, and Myriam Hemberger

Subjects

Science

Abstract

Placental dysfunction can affect heart development, but the prevalence of this causality has not been well established. Here, the authors use mouse genetic tools to show that the placenta may constitute a significant source of congenital heart defects.

Published

2023

2. Advanced Maternal Age Differentially Affects Embryonic Tissues with the Most Severe Impact on the Developing Brain

Author

Caroline Kokorudz, Bethany N. Radford, Wendy Dean, and Myriam Hemberger

Subjects

advanced maternal age, embryonic development, transcriptomics, RNA-seq, placenta, brain, Cytology, QH573-671

Abstract

Advanced maternal age (AMA) poses the single greatest risk to a successful pregnancy. Apart from the impact of AMA on oocyte fitness, aged female mice often display defects in normal placentation. Placental defects in turn are tightly correlated with brain and cardiovascular abnormalities. It therefore follows that placenta, brain and heart development may be particularly susceptible to the impact of AMA. In the current study, we compared global transcriptomes of placentas, brains, hearts, and facial prominences from mid-gestation mouse conceptuses developed in young control (7–13 wks) and aging (43–50 wks) females. We find that AMA increases transcriptional heterogeneity in all tissues, but particularly in fetal brain. Importantly, even overtly normally developed embryos from older females display dramatic expression changes in neurodevelopmental genes. These transcriptomic alterations in the brain are likely induced by defects in placental development. Using trophoblast stem cells (TSCs) as a model, we show that exposure to aging uterine stromal cell-conditioned medium interferes with normal TSC proliferation and causes precocious differentiation, recapitulating many of the defects observed in placentas from aged females. These data highlight the increased risk of AMA on reproductive outcome, with neurodevelopment being the most sensitive to such early perturbations and with potential for lifelong impact.

Published

2022

3. Padi2/3 Deficiency Alters the Epigenomic Landscape and Causes Premature Differentiation of Mouse Trophoblast Stem Cells

Author

Noura N. Ballasy, Elizabeth A. Bering, Caroline Kokorudz, Bethany N. Radford, Xiang Zhao, Wendy Dean, and Myriam Hemberger

Subjects

PADI, histone citrullination, DNA methylation, trophoblast stem cells, trophoblast giant cells, epigenetic regulation, Cytology, QH573-671

Abstract

Histone citrullination is a relatively poorly studied epigenetic modification that involves the irreversible conversion of arginine residues into citrulline. It is conferred by a small family of enzymes known as protein arginine deiminases (PADIs). PADI function supports the pluripotent state of embryonic stem cells, but in other contexts, also promotes efficient cellular differentiation. In the current study, we sought to gain deeper insights into the possible roles of PADIs in mouse trophoblast stem cells (TSCs). We show that Padi2 and Padi3 are the most highly expressed PADI family members in TSCs and are rapidly down-regulated upon differentiation. Padi2/3 double knockout (DKO) TSCs express lower levels of stem cell transcription factors CDX2 and SOX2 and are prone to differentiate into extremely large trophoblast giant cells, an effect that may be mediated by centrosome duplication defects. Interestingly, Padi2/3 DKO TSCs display alterations to their epigenomic landscape, with fewer H3K9me3-marked chromocentric foci and globally reduced 5-methylcytosine levels. DNA methylation profiling identifies that this effect is specifically evident at CpG islands of critical trophoblast genes, such as Gata3, Peg3, Socs3 and Hand1. As a consequence of the hypomethylated state, these factors are up-regulated in Padi2/3 DKO TSCs, driving their premature differentiation. Our data uncover a critical epigenetic role for PADI2/3 in safeguarding the stem cell state of TSCs by modulating the DNA methylation landscape to restrict precocious trophoblast differentiation.

Published

2022

4. Evidence of increased hypoxia signaling in fetal liver from maternal nutrient restriction in mice

Author

Bethany N. Radford and Victor K. M. Han

Subjects

Male, Offspring, Physiological, Intrauterine growth restriction, Nutritional Status, Gestational Age, Biology, Fetal Hypoxia, Pediatrics, Andrology, 03 medical and health sciences, Mice, 0302 clinical medicine, Pregnancy, 030225 pediatrics, medicine, Animals, Developmental, Adaptation, skin and connective tissue diseases, Fetus, BTG2, Fetal Growth Retardation, Animal, Gestational age, Gene Expression Regulation, Developmental, Maternal Nutritional Physiological Phenomena, Hypoxia (medical), medicine.disease, Newborn, Adaptation, Physiological, Disease Models, Animal, Gene Expression Regulation, Liver, Animals, Newborn, Prenatal Exposure Delayed Effects, Pediatrics, Perinatology and Child Health, Disease Models, Animal Nutritional Physiological Phenomena, Female, FKBP5, sense organs, medicine.symptom, 030217 neurology & neurosurgery, Signal Transduction

Abstract

BACKGROUND: Intrauterine growth restriction (IUGR) is a pregnancy condition where fetal growth is reduced, and offspring from IUGR pregnancies are at increased risk for type II diabetes as adults. The liver is susceptible to fetal undernutrition experienced by IUGR infants and animal models of growth restriction. This study aimed to examine hepatic expression changes in a maternal nutrient restriction (MNR) mouse model of IUGR to understand fetal adaptations that influence adult metabolism. METHODS: Liver samples of male offspring from MNR (70% of ad libitum starting at E6.5) or control pregnancies were obtained at E18.5 and differential expression was assessed by RNAseq and western blots. RESULTS: Forty-nine differentially expressed (FDR

Published

2020

5. Fetal and Placental Growth Physiology and Pathophysiology

Author

Victor K. M. Han, Zain Awamleh, and Bethany N. Radford

Subjects

Fetus, Noninvasive imaging, business.industry, Medicine, Stem cell, business, Bioinformatics, Embryonic stem cell, Developmental biology, Pathophysiology, Epigenomics, Diagnostic modalities

Abstract

Normal growth of an embryo/fetus is a highly complex event orchestrated by the embryonic/fetal genome and influenced by the microenvironment within the mother’s uterine cavity. The latter, in turn, is influenced by the mother’s environment, including nutrition/diet, lifestyle, activity, and stress. It is indeed a miracle that 50% of all conceptions result in a successful pregnancy, of which ~ 90% survive to full term. Recent advances in genomic and epigenomic knowledge and technologies have increased our understanding of the physiological and pathophysiological processes in development: stem cells provide optimism for cellular regenerative therapies; next-generation genomic and epigenomic technologies hold promise for improving the ability to predict pathophysiology prior to expression as diseases/disorders; and noninvasive imaging technologies will provide higher resolution diagnostic modalities. We are on the cusp of a medical revolution in developmental biology that will benefit humans in the precise prediction of human developmental disorders, allowing us healthier lives through prevention.

Published

2020

6. Insights image for 'Evidence of increased hypoxia signalling in fetal liver from maternal nutrient restriction in mice'

Author

Bethany N. Radford and Victor K. M. Han

Subjects

Fetus, Maternal Nutritional Physiological Phenomena, Physiology, Nutrients, Biology, Hypoxia (medical), Pediatrics, Mice, Nutrient, Signalling, Liver, Pediatrics, Perinatology and Child Health, medicine, Animals, Humans, Female, medicine.symptom, Hypoxia

Published

2019

7. Evidence of increased hypoxia signaling in fetal liver from maternal nutrient restriction in mice

Author

Bethany N, Radford and Victor K M, Han

Subjects

Male, Fetal Growth Retardation, Gene Expression Regulation, Developmental, Nutritional Status, Gestational Age, Maternal Nutritional Physiological Phenomena, Fetal Hypoxia, Adaptation, Physiological, Disease Models, Animal, Mice, Animals, Newborn, Liver, Pregnancy, Prenatal Exposure Delayed Effects, Animals, Animal Nutritional Physiological Phenomena, Female, Signal Transduction

Abstract

Intrauterine growth restriction (IUGR) is a pregnancy condition where fetal growth is reduced, and offspring from IUGR pregnancies are at increased risk for type II diabetes as adults. The liver is susceptible to fetal undernutrition experienced by IUGR infants and animal models of growth restriction. This study aimed to examine hepatic expression changes in a maternal nutrient restriction (MNR) mouse model of IUGR to understand fetal adaptations that influence adult metabolism.Liver samples of male offspring from MNR (70% of ad libitum starting at E6.5) or control pregnancies were obtained at E18.5 and differential expression was assessed by RNAseq and western blots.Forty-nine differentially expressed (FDR 0.1) transcripts were enriched in hypoxia-inducible pathways including Fkbp5 (1.6-fold change), Ccng2 (1.5-fold change), Pfkfb3 (1.5-fold change), Kdm3a (1.2-fold change), Btg2 (1.6-fold change), Vhl (1.3-fold change), and Hif-3a (1.3-fold change) (FDR 0.1). Fkbp5, Pfkfb3, Kdm3a, and Hif-3a were confirmed by qPCR, but only HIF-2a (2.2-fold change, p = 0.002) and HIF-3a (1.3 p = 0.03) protein were significantly increased.Although a moderate impact, these data support evidence of fetal adaptation to reduced nutrients by increased hypoxia signaling in the liver.

Published

2018

8. Offspring from maternal nutrient restriction in mice show variations in adult glucose metabolism similar to human fetal growth restriction

Author

V K M Han and Bethany N. Radford

Subjects

Adult, Male, medicine.medical_specialty, Offspring, medicine.medical_treatment, Population, Medicine (miscellaneous), 030209 endocrinology & metabolism, Placental insufficiency, Type 2 diabetes, Biology, Carbohydrate metabolism, Pediatrics, 03 medical and health sciences, Mice, 0302 clinical medicine, Pregnancy, Internal medicine, Glucose Intolerance, medicine, Animals, Humans, education, Maternal-Fetal Exchange, Caloric Restriction, education.field_of_study, Fetus, 030219 obstetrics & reproductive medicine, Fetal Growth Retardation, Insulin, Malnutrition, medicine.disease, Disease Models, Animal, Endocrinology, Animals, Newborn, fetal growth restriction, glucose metabolism, insulin sensitivity, liver, Female

Abstract

Fetal growth restriction (FGR) is a pregnancy condition in which fetal growth is suboptimal for gestation, and this population is at increased risk for type 2 diabetes as adults. In humans, maternal malnutrition and placental insufficiency are the most common causes of FGR, and both result in fetal undernutrition. We hypothesized that maternal nutrient restriction (MNR) in mice will cause FGR and alter glucose metabolism in adult offspring. Pregnant CD-1 mice were subjected to MNR (70% of average ad libitum) or control (ad libitum) from E6.5 to birth. Following birth, mice were fostered by mothers on ad libitum feeds. Weight, blood glucose, glucose tolerance and tissue-specific insulin sensitivity were assessed in male offspring. MNR resulted in reduced fetal sizes but caught up to controls by 3 days postnatal age. As adults, glucose intolerance was detected in 19% of male MNR offspring. At 6 months, liver size was reduced (P = 0.01), but pAkt-to-Akt ratios in response to insulin were increased 2.5-fold relative to controls (P = 0.004). These data suggest that MNR causes FGR and long-term glucose intolerance in a population of male offspring similar to human populations. This mouse model can be used to investigate the impacts of FGR on tissues of importance in glucose metabolism.

Published

2018