Project description:Growth restriction, craniofacial dysmorphology and central nervous system defects are the main diagnostic features of fetal alcohol syndrome. Studies in humans and mice have reported that the growth restriction can be prenatal and/or postnatal, but the underlying mechanisms remain unknown. We recently described a mouse model of moderate gestational ethanol exposure that produces measurable phenotypes in line with fetal alcohol syndrome, e.g. craniofacial changes and growth restriction in adolescent mice. Here we further characterize the growth restriction phenotype by measuring body weight at gestational day 16.5, cross-fostering from birth to weaning, and extending our observations into adulthood. Furthermore, in an attempt to unravel the molecular events contributing to the growth phenotype, we have compared gene expression patterns in the liver and kidney of non-fostered ethanol-exposed and control mice at postnatal day 28. We find that the ethanol-induced growth phenotype is not detectable prior to birth, but is present at weaning, even in mice that have been cross-fostered to unexposed dams. This suggests a postnatal growth restriction phenotype that is not due to deficient postpartum care by dams that drank ethanol, but rather a physiological result of ethanol exposure in utero. We also find that, despite some catch-up growth after five weeks of age, the effect extends into adulthood, consistent with longitudinal studies in humans. Genome-wide gene expression analysis revealed interesting ethanol-induced changes in the liver, including genes involved in the metabolism of exogenous and endogenous compounds, iron homeostasis and lipid metabolism. Gene expression changes in the livers of offspring exposed to alcohol in utero compared to controls.

Project description:Growth restriction, craniofacial dysmorphology and central nervous system defects are the main diagnostic features of fetal alcohol syndrome. Studies in humans and mice have reported that the growth restriction can be prenatal and/or postnatal, but the underlying mechanisms remain unknown. We recently described a mouse model of moderate gestational ethanol exposure that produces measurable phenotypes in line with fetal alcohol syndrome, e.g. craniofacial changes and growth restriction in adolescent mice. Here we further characterize the growth restriction phenotype by measuring body weight at gestational day 16.5, cross-fostering from birth to weaning, and extending our observations into adulthood. Furthermore, in an attempt to unravel the molecular events contributing to the growth phenotype, we have compared gene expression patterns in the liver and kidney of non-fostered ethanol-exposed and control mice at postnatal day 28. We find that the ethanol-induced growth phenotype is not detectable prior to birth, but is present at weaning, even in mice that have been cross-fostered to unexposed dams. This suggests a postnatal growth restriction phenotype that is not due to deficient postpartum care by dams that drank ethanol, but rather a physiological result of ethanol exposure in utero. We also find that, despite some catch-up growth after five weeks of age, the effect extends into adulthood, consistent with longitudinal studies in humans. Genome-wide gene expression analysis revealed interesting ethanol-induced changes in the liver, including genes involved in the metabolism of exogenous and endogenous compounds, iron homeostasis and lipid metabolism. Gene expression changes in the kidneys of offspring exposed to alcohol in utero compared to controls.

Project description:Growth restriction, craniofacial dysmorphology and central nervous system defects are the main diagnostic features of fetal alcohol syndrome. Studies in humans and mice have reported that the growth restriction can be prenatal and/or postnatal, but the underlying mechanisms remain unknown. We recently described a mouse model of moderate gestational ethanol exposure that produces measurable phenotypes in line with fetal alcohol syndrome, e.g. craniofacial changes and growth restriction in adolescent mice. Here we further characterize the growth restriction phenotype by measuring body weight at gestational day 16.5, cross-fostering from birth to weaning, and extending our observations into adulthood. Furthermore, in an attempt to unravel the molecular events contributing to the growth phenotype, we have compared gene expression patterns in the liver and kidney of non-fostered ethanol-exposed and control mice at postnatal day 28. We find that the ethanol-induced growth phenotype is not detectable prior to birth, but is present at weaning, even in mice that have been cross-fostered to unexposed dams. This suggests a postnatal growth restriction phenotype that is not due to deficient postpartum care by dams that drank ethanol, but rather a physiological result of ethanol exposure in utero. We also find that, despite some catch-up growth after five weeks of age, the effect extends into adulthood, consistent with longitudinal studies in humans. Genome-wide gene expression analysis revealed interesting ethanol-induced changes in the liver, including genes involved in the metabolism of exogenous and endogenous compounds, iron homeostasis and lipid metabolism.

Project description:We performed single-cell RNA sequencing on murine dorsal telencephalon isolated at gestational day (GD) 14.5, 48 hours after dams are exposed to ethanol or control air in a vapour chamber for 1 hour.

Project description:Microglia activation is a key modulator of brain vulnerability in response to intra-uterine growth restriction (IUGR). However, the consequences of IUGR on microglia development and on microglia proteome are still unknown. We used a model of IUGR induced by a gestational low-protein diet (LPD) in rat. Microglia were isolated from control and LPD animals at P1 and P4. The aim of this work was characterize the consequence of IUGR on microglia development and investigate the consequences of IUGR exposure on microglia proteome during the first postnatal days using a bioinformatics approach associated with functional assays.

Project description:Zinc deficiency during pregnancy and postnatal life can adversely affect the health and predispose to an increased risk of developing human diseases at adulthood. The present study was designed to evaluate whether dietary zinc deficiency or supplementation during the pregnancy, lactation and juvenile stages interferes with the development of mammary tumors induced by 7,12-dimethylbenzanthracene (DMBA) in female Sprague-Dawley (SD) rats. Pregnant females SD were allocated into three groups: dams received diets containing adequate (35 mg/Kg chow), deficient (3 mg/Kg chow) or supplemented (180 mg/Kg chow) zinc levels during gestational day 10 (GD 10) until the litters weaning. Female offspring were allocated into three groups and received the same diets as their dams until postnatal day (PND) 51. At PND 51, females SD (n=16 each group) received a single dose of DMBA (50 mg/kg, ig) for initiation of mammary carcinogenesis, adequate zinc diets and were euthanized at PND 180. Tumors samples were collected and processed for histological evaluation and microarray analysis. Dietary zinc deficiency induced a significant reduction in female offspring body weight evolution at parturition, weaning and pubertal phases. At late in life, the early in life dietary zinc deficiency or supplementation did not alter the latency, incidence, multiplicity and volume or histological types of mammary tumors in relation to the adequate zinc group, and changed the expression of a small amount of genes. The present findings indicate that early-in life dietary zinc deficiency or supplementation did not significantly modify the susceptibility to development of mammary tumors induced by DMBA.

Project description:Initiation of a vitamin A deficient diet in mid-gestation, maintained in the post-weaning diet is sufficient to cause liver and serum retinoid depletion. Wild type C57Bl/6J timed mated pregnant dams were administered either a defined vitamin A sufficient low fat (12 percent kcal from fat) diet or matched vitamin A deficient diet from embryonic day 10.5. Vitamin A sufficient offspring were weaned onto either a high fat diet (60 percent kcal from fat) or maintained on the low fat 12 percent kcal from fat diet for 11 weeks (14 weeks of age). Gestational vitamin A deficient offspring were maintained on the same vitamin A deficient diet until 14 weeks of age. The impact of the maternal diet on a post-weaning high fat diet was compared to a standard maternal breeder diet followed by the post-weaning high fat diet.

Project description:Fetal alcohol spectrum disorders (FASD) are a group of neurodevelopmental disorders caused by ethanol exposure in utero, which can result in neurocognitive and behavioral impairments, growth defects, and craniofacial anomalies. FASD affects up to 1-5% of school-aged children in the United States, and there is currently no cure. The underlying mechanisms involved in ethanol teratogenesis remain elusive and need greater understanding to develop and implement effective therapies. Using a third trimester human equivalent postnatal mouse model of FASD, we evaluate the transcriptomic changes induced by ethanol exposure in the cerebellum on P5 and P6, after only 1 or 2 days of ethanol exposure, with the goal of shedding light on the transcriptomic changes induced early during the onset and development of FASD. We have highlighted key pathways and cellular functions altered by ethanol exposure, which include pathways related to immune function and cytokine signaling as well as the cell cycle.  Additionally, we found that ethanol exposure resulted in an increase in transcripts associated with a neurodegenerative microglia phenotype, and acute- and pan-injury reactive astrocyte phenotypes. Mixed effects on oligodendrocyte lineage cell associated transcripts and cell cycle associated transcripts were observed. These studies help to elucidate the underlying mechanisms that may be involved with the onset of FASD and provide further insights that may aid in identifying novel targets for interventions and therapeutics.

Project description:Taurine is known to be important for fetal well being and to be able to prevent effects of a low birthweight phenotype when supplemented to pregnant dams. We hypothesized that gestational taurine supplementation would affect gene expression level in 4w offspring liver and skeletal muscle.

Project description:Alcohol (ethanol, EtOH) consumption during pregnancy can result in fetal alcohol spectrum disorders (FASDs), which are characterized by prenatal and postnatal growth restriction and craniofacial dysmorphology. The specific mechanisms by which alcohol mediates these injuries have yet to be determined. Cell-derived extracellular vesicles, including exosomes and microvesicles containing several species of RNAs (exRNAs), have recently emerged as a mechanism of cell-to-cell communication. However, EtOH’s effects on the biogenesis and function of non-coding exRNAs during fetal development have not been explored. Therefore, we studied the effects of maternal EtOH exposure on the composition of exRNAs in the amniotic fluid (AF) using a rat fetal alcohol exposure (FAE) model. Timed pregnant Sprague Dawley rats received 0 or 2.5 g/kg of 20% EtOH by oral gavage on embryonic days 5, 8, 10, 12 and 15. Through RNA-Seq analysis we identified and verified AF exosomal miRNAs with differential expression levels specifically associated with maternal EtOH exposure.