Project description:We have previously shown in sheep that 10 days of modest chronic increase in maternal cortisol result in fetal heart enlargement and Purkinje cell apoptosis. In subsequent studies in which we extended the duration of cortisol infusion (1mg/kg/d) to term, we found a dramatic incidence of stillbirth in the pregnancies with chronically increased cortisol and associated maternal hyperglycemia. To investigate the effects on the heart, transcriptomic analyses were performed on the septa using ovine microarrays and Webgestalt and Cytoscape programs for pathway inference. Analyses of the effects of 10 days of maternal cortisol infusion (130d-cortisol vs 130d control), ~25 days (term at ~140d-cortisol vs 140d control), normal maturation (140d-control vs 130d control) were performed. In all analyses gene ontology (GO) terms related to immune function and cytokine actions were significantly over-represented. After 10 days of cortisol, growth factor and muscle cell apoptosis pathways were significantly over-represented, consistent with our previous findings. We found significantly differentially regulated genes in the term fetuses (ie after ~25 days of cortisol) in pathways consistent with altered metabolism in the heart, particularly in mitochondria, associated with responses to hypoxia and to nutrient. Analysis of mitochondrial number by quantitative real-time PCR confirmed a significant decrease. These pathways were different from those modeled following the normal increase in cortisol in late gestation which contributes to normal maturation of the heart, and thus may be indicative of the fetal heart pathophysiologies seen in pregnancies complicated by diabetes, CushingM-bM-^@M-^Ys disease and chronic stress. 2 cohorts of singleton sheep fetuses at 129-131d gestation or 139-144d gestation (approximately term) were used. The first cohort received maternal cortisol infusion of 1mg/kg/day or vehicle for 10 days until approximately day 130 of gestation (n=6/group), the second cohort received the same dose of cortisol for approximately 25 days until near term (n=7, cortisol; n=7ewes, n=8 fetuses due to one set of twins, control)

Project description:We have previously shown in sheep that 10 days of modest chronic increase in maternal cortisol result in fetal heart enlargement and Purkinje cell apoptosis. In subsequent studies in which we extended the duration of cortisol infusion (1mg/kg/d) to term, we found a dramatic incidence of stillbirth in the pregnancies with chronically increased cortisol and associated maternal hyperglycemia. In previous studies of the intraventricular septum from these fetuses we found significantly differentially regulated genes in the term fetuses (ie after ~25 days of cortisol) in pathways consistent with altered metabolism in the heart, particularly in mitochondria, associated with responses to hypoxia and to nutrient. Analysis of mitochondrial number by quantitative real-time PCR confirmed a significant decrease. We extended this investigation to the left ventricular free wall of these fetuses.le. Fewer genes were differentially regulated in left ventricle in the near term fetuses. In the LV of this cohort of fetuses, the nonredundant KEGG pathways represented by the DEG were insulin resistance and adipocytokine signaling pathway. GSEA analysis of the DEG in LV identified metabolic pathways as the nonredundant pathway altered. Comparison of the change in gene expression in biceps to that in cardiac intraventricular septum and left ventricle showed few common genes with little overlap in specific metabolic or signaling pathways, despite effects on mitochondria and metabolism in both heart and biceps. Our results suggest that glucocorticoid exposure affects nuclear genes important to mitochondrial activity and reactive oxygen in both cardiac and skeletal muscle tissues in a tissue specific manner.

Project description:We have previously shown in sheep that 10 days of modest chronic increase in maternal cortisol result in fetal heart enlargement and Purkinje cell apoptosis. In subsequent studies in which we extended the duration of cortisol infusion (1mg/kg/d) to term, we found a dramatic incidence of stillbirth in the pregnancies with chronically increased cortisol and associated maternal hyperglycemia. In previous studies of the intraventricular septum from these fetuses we found significantly differentially regulated genes in the term fetuses (ie after ~25 days of cortisol) in pathways consistent with altered metabolism in the heart, particularly in mitochondria, associated with responses to hypoxia and to nutrient. Analysis of mitochondrial number by quantitative real-time PCR confirmed a significant decrease. To investigate the effects on skeletal muscle, we extended the transcriptomic analyses to biceps femoralis. Transcriptomic modelling revealed that pathways related to mitochondrial metabolism were downregulated, whereas pathways suggestive of positive regulation of reactive oxygen species and activation of the apoptotic cascade were upregulated. Mitochondrial DNA (mt-DNA) and the protein levels of cytochrome C was significantly decreased in the biceps. RT- PCR validation of the pathways showed significant decrease in SLC2A4 mRNA levels, and a significant increase in PDK4, TXNIP, ANGPTL4 mRNA levels, consistent with reduced insulin sensitivity of the bicep muscles. Comparison of the change in gene expression in biceps to that in cardiac intraventricular septum and left ventricle showed few common genes with little overlap in specific metabolic or signaling pathways, despite reduction in mitochondria in both heart and biceps. Our results suggest that glucocorticoid exposure affects nuclear genes important to mitochondrial activity and reactive oxygen in both cardiac and skeletal muscle tissues in a tissue specific manner.

Project description:We have identified effects of elevated maternal cortisol on fetal cardiac maturation and function in an ovine model. Whereas short term exposure, produced by maternal infusion (1 mg/kg/d) from 115-130d gestation increased fetal heart wall thickness and weight, myocyte proliferation and Purkinje fiber apoptosis, when cortisol exposure continued until term (~145 days of gestation), there was a profound increase in perinatal stillbirth. Further study indicated increases in P-R and R-R interval of the ECG and increased incidence of arrhythmias at birth, suggesting that these changes in the fetal heart contribute to the stillbirth. We have used systems biology to statistically model the transcriptomic changes in hearts at 130 days and near term. In the current study, we used this approach to test for effects on pathways related to metabolism and cardiac structure in the left ventricle and septum from newborn lambs. Cortisol altered genes in pathways involved in cardiac architecture in the left ventricle, including SMAD and BMP; cortisol also increased collagen deposition. Genes in pathways involved in metabolism and actin filament assembly were affected within the septum. Comparison of the effects of cortisol to the effects of normal maturation from day 140 to birth revealed that only 1% of the genes changed by cortisol in the LV and 18% in the septum were consistent with the normal maturational changes in gene expression. These results indicate that chronic in utero exposure to elevated cortisol concentrations alters the normal maturation of the fetal myocardium, adversely impacting perinatal cardiac function.

Project description:Cortisol administration during late gestation in ewes, modeling maternal stress, resulted in transcriptomic changes suggesting altered maturation and metabolic changes to the offspring heart. This study investigates the effects of cortisol on epicardial adipose tissue (EAT), a visceral fat pad associated with adverse cardiovascular conditions in adults. Pregnant ewes were treated with either 1 or 0.5 mg/kg/day cortisol from 115 days gestation to term and EAT collected from term fetuses (control: n=8, maternal cortisol 1 mg/kg/day: n=6) or two-week-old lambs (control: n=7, maternal cortisol 0.5mg/kg/day: n=9). Transcriptomic modeling was used to identify pathways altered by maternal cortisol over-exposure. Transcriptomic modeling confirmed the brown fat phenotype of EAT at term and a transition towards white fat at two weeks of age in EAT of control fetuses/lambs, and highlighted a role of immune responses, including complement-coagulation, and serotonin in this transition. Maternal cortisol (1mg/kg/day) increased the lipid peroxidation product 4-hydroxynonenal in EAT of term fetuses, but did not affect the number of activated macrophages or size of the lipid droplets in the depot; transcriptomics suggested an earlier metabolic maturation of EAT via, in part, increased immune responses. Conversely the transcriptomics in EAT of two-week-old lambs of ewes treated with a lower dose of cortisol (0.5mg/kg/day) suggested decreased metabolism of several substrates through both mitochondrial and cytosolic actions, and delayed maturation of EAT associated with a longer period of adipogenesis and angiogenesis.

Project description:Purpose: Offspring from females that experience stressful conditions during reproduction often exhibit altered phenotypes and many of these effects are thought to arise due to increased exposure to maternal glucocorticoids. Here we used RNAseq to test whether the embryonic transcriptional response to increased levels of cortisol was similar to the transcriptional response to maternal stress in sticklebacks Methods: Eggs were treated by immersing eggs for 30 mins in water that contained 0, 5, or 10 ug/L, which represented baseline, predator induced, and super physiological levels of maternally derived cortisol. To isolated enough RNA for RNAseq, 10 embyros from each clutch/treatment were pooled prior to RNA extraction for a total of 18 pools (6 clutches x 3 treatments). Results: Analysis of genome-wide transcriptional profiles suggests that 17251 (genes which survived a cut-off of having cpm more than 1 in at least two samples; and had a significant likelihood ratio calculated in edgeR) genes out of the possible 22,456 genes in the stickleback genome were expressed in 72-hour embryos. However, we did not detect any differences in gene expression between embryos that were treated with cortisol compared to the control group. mRNA profiles of egg clutches treated with 0, 5, or 10 ug/L are compared, which represented baseline, predator induced, and super physiological levels of maternally derived cortisol.

Project description:Control vs. AngII Infusion: Heart

Project description:Cortisol administration during late gestation in ewes, modeling maternal stress, resulted in transcriptomic changes suggesting altered maturation and metabolic changes to the offspring heart. Pregnant ewes were treated with 0.5 mg/kg/day cortisol from 115 days gestation to term lambs were studied over the next 2 weeks. Left ventricular free wall (LV) and intraventricular septum (IVS) were collected at 2 weeks of age (lambs of control, untreated ewes: n=8, lambs of ewes treated with 0.5 mg/kg/day: n=8). In this model we found that neonatal plasma glucose was increased and plasma insulin was decreased compared to those in the control group. LV free wall thickness was increased in the 2 week old lamb. In this study, we have used transcriptomic modeling to better understand the programming effect of this maternal cortisolemia in the 2 week old hearts. This is a time when both terminal differentiation and a shift in the metabolism of the heart from carbohydrates to lipid oxidation are thought to be complete. The transcriptomics indicates downregulation of RNA related pathways, but upregulation of ubiquitin-mediated proteolysis and protein targeting to the mitochondria in in the intraventricular septum (IVS) and left ventricle (LV) in lambs of cortisol-infused ewes compared to untreated control ewes. In IVS pathways the AMPK pathway and adipocytokine signaling pathways were also modeled as downregulated in lambs of cortisl-treated ewes Genes for peroxisomal activity are modeled as decreased in LV and IVS; our previous metabolomic study of the newborn hearts from the 1 mg/kg/d study indicated changes in the plasmogens and phospholipids that are peroxisomal products. Our results suggest that pathways for lipid metabolismas well as cell proliferation and cardiac remodeling have altered activity postnatally after the in utero cortisol exposure. Together, this model is consistent with the observed increase in cardiac wall thickness at necropys and altered glucose metabolism observed in vivo, and predicts that in utero exposure to excess maternal cortisol causes postnatal cardiac hypertrophy and altered responses to oxidative stress.

Project description:Purpose: Offspring from females that experience stressful conditions during reproduction often exhibit altered phenotypes and many of these effects are thought to arise due to increased exposure to maternal glucocorticoids. Here we used RNAseq to test whether the embryonic transcriptional response to increased levels of cortisol was similar to the transcriptional response to maternal stress in sticklebacks Methods: Eggs were treated by immersing eggs for 30 mins in water that contained 0, 5, or 10 ug/L, which represented baseline, predator induced, and super physiological levels of maternally derived cortisol. To isolated enough RNA for RNAseq, 10 embyros from each clutch/treatment were pooled prior to RNA extraction for a total of 18 pools (6 clutches x 3 treatments). Results: Analysis of genome-wide transcriptional profiles suggests that 17251 (genes which survived a cut-off of having cpm more than 1 in at least two samples; and had a significant likelihood ratio calculated in edgeR) genes out of the possible 22,456 genes in the stickleback genome were expressed in 72-hour embryos. However, we did not detect any differences in gene expression between embryos that were treated with cortisol compared to the control group.

Project description:Fourteen human subjects (18-40 years of age) were studied. The control group (saline + LPS [n = 7]) received a 12 hour infusion of saline and the experimental group (cortisol + LPS [n = 7]) received a 12 hour infusion of cortisol (3 ug/kg/min). After 6 hours of saline or cortisol infusion, intravenous lipopolysaccharide (2 ng/kg) was administered to all subjects. Blood samples were collected at -24 hours, 0 hours, 6 hours and 24 hours relative to LPS administration at 0 hours. Leukocytes and monocytes were isolated from these blood samples, total RNA extracted, and microarray analyses performed using Affymetrix Focus GeneChips. Blood samples were collected at (-24)hr, 0hr, 6hr, and 24hr in relation to the LPS infusion. For both saline and cortisol treated subjects, infusion was started at (-6) hr and continued to (+6) hr.