Abstract
We report in this study an intrinsic link between pyrimidine metabolism and liver lipid accumulation utilizing a uridine phosphorylase 1 transgenic mouse model UPase1-TG. Hepatic microvesicular steatosis is induced by disruption of uridine homeostasis through transgenic overexpression of UPase1, an enzyme of the pyrimidine catabolism and salvage pathway. Microvesicular steatosis is also induced by the inhibition of dihydroorotate dehydrogenase (DHODH), an enzyme of the de novo pyrimidine biosynthesis pathway. Interestingly, uridine supplementation completely suppresses microvesicular steatosis in both scenarios. The effective concentration (EC(50)) for uridine to suppress microvesicular steatosis is approximately 20 µM in primary hepatocytes of UPase1-TG mice. We find that uridine does not have any effect on in vitro DHODH enzymatic activity. On the other hand, uridine supplementation alters the liver NAD(+)/NADH and NADP(+)/NADPH ratios and the acetylation profile of metabolic, oxidation-reduction, and antioxidation enzymes. Protein acetylation is emerging as a key regulatory mechanism for cellular metabolism. Therefore, we propose that uridine suppresses fatty liver by modulating the liver protein acetylation profile. Our findings reveal a novel link between uridine homeostasis, pyrimidine metabolism, and liver lipid metabolism.
Highlights
We report in this study an intrinsic link between pyrimidine metabolism and liver lipid accumulation utilizing a uridine phosphorylase 1 transgenic mouse model UPase1-TG
We generated a transgenic mouse model UPase1-TG with genetic knock-in of UPase1 to study the roles of uridine homeostasis in liver function
UPase1-TG mice exhibited hepatic microvesicular steatosis, which could be suppressed with exogenous uridine supplementation at 400 mg/kg/day
Summary
We report in this study an intrinsic link between pyrimidine metabolism and liver lipid accumulation utilizing a uridine phosphorylase 1 transgenic mouse model UPase1-TG. Hepatic microvesicular steatosis is induced by disruption of uridine homeostasis through transgenic overexpression of UPase, an enzyme of the pyrimidine catabolism and salvage pathway. Uridine supplementation completely suppresses microvesicular steatosis in both scenarios. The effective concentration (EC50) for uridine to suppress microvesicular steatosis is approximately 20 μM in primary hepatocytes of UPase1-TG mice. Uridine supplementation alters the liver NAD+/NADH and NADP+/NADPH ratios and the acetylation profile of metabolic, oxidation-reduction, and antioxidation enzymes. Our findings reveal a novel link between uridine homeostasis, pyrimidine metabolism, and liver lipid metabolism.—Le, T. Disruption of uridine homeostasis links liver pyrimidine metabolism to lipid accumulation.
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