Your search keyword '"Jones, Amanda K."' showing total 3 results

1. Tissue-specific responses that constrain glucose oxidation and increase lactate production with the severity of hypoxemia in fetal sheep.

Author

Jones AK, Wang D, Goldstrohm DA, Brown LD, Rozance PJ, Limesand SW, and Wesolowski SR

Subjects

Adipose Tissue embryology, Animals, Disease Models, Animal, Female, Fetal Growth Retardation metabolism, Insulin metabolism, Insulin Secretion, Liver embryology, Male, Muscle, Skeletal embryology, Oxidation-Reduction, Pancreas embryology, Pregnancy, Sheep, Adipose Tissue metabolism, Fetal Hypoxia metabolism, Fetus metabolism, Glucose metabolism, Lactic Acid biosynthesis, Liver metabolism, Muscle, Skeletal metabolism, Pancreas metabolism

Abstract

Fetal hypoxemia decreases insulin and increases cortisol and norepinephrine concentrations and may restrict growth by decreasing glucose utilization and altering substrate oxidation. Specifically, we hypothesized that hypoxemia would decrease fetal glucose oxidation and increase lactate and pyruvate production. We tested this by measuring whole body glucose oxidation and lactate production, and molecular pathways in liver, muscle, adipose, and pancreas tissues of fetuses exposed to maternal hypoxemia for 9 days (HOX) compared with control fetal sheep (CON) in late gestation. Fetuses with more severe hypoxemia had lower whole body glucose oxidation rates, and HOX fetuses had increased lactate production from glucose. In muscle and adipose tissue, expression of the glucose transporter GLUT4 was decreased. In muscle, pyruvate kinase ( PKM ) and lactate dehydrogenase B ( LDHB ) expression was decreased. In adipose tissue, LDHA and lactate transporter ( MCT1 ) expression was increased. In liver, there was decreased gene expression of PKLR and MPC2 and phosphorylation of PDH, and increased LDHA gene and LDH protein abundance. LDH activity, however, was decreased only in HOX skeletal muscle. There were no differences in basal insulin signaling across tissues, nor differences in pancreatic tissue insulin content, β-cell area, or genes regulating β-cell function. Collectively, these results demonstrate coordinated metabolic responses across tissues in the hypoxemic fetus that limit glucose oxidation and increase lactate and pyruvate production. These responses may be mediated by hypoxemia-induced endocrine responses including increased norepinephrine and cortisol, which inhibit pancreatic insulin secretion resulting in lower insulin concentrations and decreased stimulation of glucose utilization. NEW & NOTEWORTHY Hypoxemia lowered fetal glucose oxidation rates, based on severity of hypoxemia, and increased lactate production. This was supported by tissue-specific metabolic responses that may result from increased norepinephrine and cortisol concentrations, which decrease pancreatic insulin secretion and insulin concentrations and decrease glucose utilization. This highlights the vulnerability of metabolic pathways in the fetus and demonstrates that constrained glucose oxidation may represent an early event in response to sustained hypoxemia and fetal growth restriction.

Published

2022

2. Effects of chronic hyperinsulinemia on metabolic pathways and insulin signaling in the fetal liver.

Author

Rozance PJ, Jones AK, Bourque SL, D'Alessandro A, Hay WW Jr, Brown LD, and Wesolowski SR

Subjects

Amino Acids metabolism, Animals, Female, Fetus metabolism, Gene Expression Regulation, Glucose metabolism, Hepatocytes metabolism, Hyperinsulinism physiopathology, Lipid Metabolism, Liver embryology, Mitochondria, Liver metabolism, Oxygen Consumption physiology, Pregnancy, Signal Transduction, Hyperinsulinism metabolism, Insulin metabolism, Liver physiopathology, Sheep physiology

Abstract

The effect of chronic of hyperinsulinemia in the fetal liver is poorly understood. Here, we produced hyperinsulinemia with euglycemia for ∼8 days in fetal sheep [hyperinsulinemic (INS)] at 0.9 gestation. INS fetuses had increased insulin and decreased oxygen and amino acid (AA) concentrations compared with saline-infused fetuses [control (CON)]. Glucose (whole body) utilization rates were increased, as expected, in INS fetuses. In the liver, however, there were few differences in genes and metabolites related to glucose and lipid metabolism and no activation of insulin signaling proteins (Akt and mTOR). There was increased p-AMPK activation and decreased mitochondrial mass ( PGC1A expression, mitochondrial DNA content) in INS livers. Using an unbiased multivariate analysis with 162 metabolites, we identified effects on AA and one-carbon metabolism in the INS liver. Expression of the transaminase BCAT2 and glutaminase genes GLS1 and GLS2 was decreased, supporting decreased AA utilization. We further evaluated the roles of hyperinsulinemia and hypoxemia, both present in INS fetuses, on outcomes in the liver. Expression of PGC1A correlated only with hyperinsulinemia, p-AMPK correlated only with hypoxemia, and other genes and metabolites correlated with both hyperinsulinemia and hypoxemia. In fetal hepatocytes, acute treatment with insulin activated p-Akt and decreased PGC1A, whereas hypoxia activated p-AMPK. Overall, chronic hyperinsulinemia produced greater effects on amino acid metabolism compared with glucose and lipid metabolism and a novel effect on one-carbon metabolism in the fetal liver. These hepatic metabolic responses may result from the downregulation of insulin signaling and antagonistic effects of hypoxemia-induced AMPK activation that develop with chronic hyperinsulinemia.

Published

2020

3. Sustained hypoxemia in late gestation potentiates hepatic gluconeogenic gene expression but does not activate glucose production in the ovine fetus.

Author

Jones AK, Rozance PJ, Brown LD, Goldstrohm DA, Hay WW Jr, Limesand SW, and Wesolowski SR

Subjects

Animals, Embryo, Mammalian, Female, Fetal Blood metabolism, Fetal Development genetics, Gene Expression Regulation, Developmental, Gestational Age, Glucose metabolism, Hypoxia veterinary, Liver embryology, Oxygen metabolism, Pregnancy, Fetus metabolism, Gluconeogenesis genetics, Hypoxia genetics, Hypoxia metabolism, Liver metabolism, Pregnancy Complications genetics, Pregnancy Complications metabolism, Pregnancy Complications veterinary, Sheep embryology, Sheep genetics, Sheep metabolism

Abstract

Fetal hypoxemia is associated with pregnancy conditions that cause an early activation of fetal glucose production. However, the independent role of hypoxemia to activate this pathway is not well understood. We hypothesized that fetal hypoxemia would activate fetal glucose production by decreasing umbilical glucose uptake and increasing counter-regulatory hormone concentrations. We induced hypoxemia for 9 days with maternal tracheal N 2 gas insufflation to reduce maternal and fetal arterial Po 2 by ~20% (HOX) compared with fetuses from ewes receiving intratracheal compressed air (CON). At 0.9 of gestation, fetal metabolic studies were performed ( n = 7 CON, 11 HOX). Umbilical blood flow rates, net fetal oxygen and glucose uptake rates, and fetal arterial plasma glucose concentrations were not different between the two groups. Fetal glucose utilization rates were lower in HOX versus CON fetuses but not different from umbilical glucose uptake rates, demonstrating the absence of endogenous glucose production. In liver tissue, mRNA expression of gluconeogenic genes G6PC (P < 0.01) and PCK1 ( P = 0.06) were six- and threefold greater in HOX fetuses versus CON fetuses. Increased fetal norepinephrine and cortisol concentrations and hepatic G6PC and PCK1 expression were inversely related to fetal arterial Po 2 . These findings support a role for fetal hypoxemia to act with counter-regulatory hormones to potentiate fetal hepatic gluconeogenic gene expression. However, in the absence of decreased net fetal glucose uptake rates and plasma glucose concentrations, hypoxemia-induced gluconeogenic gene activation is not sufficient to activate fetal glucose production.

Published

2019