Barron, Catherine Mary2020-08-072020-08-072020-08-06vt_gsexam:27081http://hdl.handle.net/10919/99602Trimethylamine N-oxide (TMAO) is a metabolite derived from dietary choline, betaine, and carnitine via intestinal microbiota metabolism. In several recent studies, TMAO has been shown to directly induce inflammation and reactive oxygen species (ROS) generation in numerous cell types, resulting in cell dysfunction. However, whether TMAO will impact stem cell properties remains unknown. This project aims to explore the potential impact of TMAO on mouse embryonic stem cells (mESCs), which serve as an in vitro model of the early embryo and of other potent stem cell types. Briefly, mESCs were cultured in the absence (0mM) or presence of TMAO under two different sets of treatment conditions: long-term (21 days), low-dose (20µM, 200µM, and 1000µM) treatment or short-term (5 days), high-dose (5mM, 10mM, 15mM) treatment. Under these treatment conditions, mESC viability, proliferation, and stemness were analyzed. mESC properties were not negatively impacted under long-term, low-dose TMAO treatment; however, short-term, high-dose treatment resulted in significant reduction of mESC viability and proliferation. Additionally, mESC stemness was significantly reduced when high-dose treatment was extended to 21 days. To investigate an underlying cause for TMAO-induced loss in mESC stemness, metabolic activity of the mESCs under short-term, high-dose TMAO treatment was measured with a Seahorse XFe96 Analyzer. TMAO treatment significantly decreased the rate of glycolysis, and it increased the rate of compensatory glycolysis upon inhibition of oxidative phosphorylation (OxPHOS). It also significantly increased the rate of OxPHOS, maximal respiratory capacity, and respiratory reserve. These findings indicate that TMAO induced a metabolic switch of mESCs from high glycolytic activity to greater OxPHOS activity to promote mESC differentiation. Additionally, TMAO resulted in increased proton leak, indicating increased oxidative stress, and elucidating a potential underlying mechanism for TMAO-induced loss in mESC stemness. Altogether, these findings indicate that TMAO decreases stem cell potency potentially via modulation of metabolic activity.ETDIn CopyrightTrimethylamine N-oxidemouse embryonic stem cellspluripotencymetabolismmitochondriareactive oxygen speciesproton leakEffects of Trimethylamine N-Oxide on Mouse Embryonic Stem Cell PropertiesThesis