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SUN-077 In Utero Growth Restriction Induces an Early Metabolic Shift in Fetal Rat Heart
Adverse uterine environment may expose newborns to develop metabolic diseases later in their life. The in-utero growth restriction (IUGR) is an immediate outcome of a sub-optimal womb environment, where the fetus cannot reach its full growth potential. We have developed an animal model of IUGR based...
Autores principales: | , , , |
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Formato: | Online Artículo Texto |
Lenguaje: | English |
Publicado: |
Endocrine Society
2019
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Materias: | |
Acceso en línea: | https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6553205/ http://dx.doi.org/10.1210/js.2019-SUN-077 |
Sumario: | Adverse uterine environment may expose newborns to develop metabolic diseases later in their life. The in-utero growth restriction (IUGR) is an immediate outcome of a sub-optimal womb environment, where the fetus cannot reach its full growth potential. We have developed an animal model of IUGR based on a low-sodium diet given to dams during the last week of gestation. We showed that the isocaloric low-sodium diet reduces maternal blood volume expansion, causing poor placental perfusion, low placental weight and subsequent IUGR in offspring. Redistribution of blood flow in the fetus was observed, causing a preferential perfusion to major organs, such as the heart. Consistent with this, adult offspring showed an increase in blood pressure and remodeling of cardiomyocytes occurs in adult female, suggesting metabolic changes in cardiac function. In this study, we address whether the IUGR induced-stress leads to metabolic changes in fetal cardiomyocytes to adapt their energy-production process and lipid utilization. At 22 days of gestation, hearts were collected from IUGR and control fetuses, and homogenized. Gene expression profile as well as protein levels were analyzed. We observed an increased expression of critical genes involved in lipid metabolism, such as long chain fatty acid receptor CD36, carnitine palmitoyltransferase CPT1a, and also key enzymes of long chain fatty acid beta-oxidation in IUGR heart. In addition, our results indicate an increase in mitochondrial biogenesis. To address whether changes in lipid metabolite profile might prevail, we performed lipidomic MS analysis in heart homogenates. Lipidomics showed significant accumulation of very long and long-chain fatty acids in the context of IUGR and when comparing males and females. These changes could be reminiscent of an adaptation in the use of fatty acids for energy production. Altogether, these findings suggest that fetal IUGR cardiac cells may rely more on the use of lipids as an energy source, compared to same age control cells. Such alterations in energy metabolism in fetal IUGR cardiomyocytes are consistent with an early metabolic shift to favor lipids as the main energy source. This shift normally occurs in the neonatal life to adapt to an extra-uterine environment. Therefore, our findings suggest that adaptation to an altered placental perfusion results in an early cardiac metabolic remodeling that might predispose individuals to metabolic disorders later in their life. Sources of Research Support: Fond de Recherche Québécois en Santé (FRQS) and Canadian Institutes of Health Research (CIHR). |
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