Glucose as a carbon source to synthesize palmitate de novo in the adult rodent brain: Adding to the carbon recycling story in the brain

While brain glucose metabolism is known to contribute the carbons to support brain saturated and monounsaturated fatty biosynthesis de novo in the developing brains of young rodents, such a contribution to fatty acid biosynthesis in the adult brain is poorly understood. Recent work from the Bazinet laboratory illuminates the role of brain glucose metabolism in providing a carbon source from which palmitic acid is synthesized. In “The Majority of Brain Palmitic Acid is Maintained by Lipogenesis from Dietary Sugars and is Augmented in Offspring fed low Palmitic Acid Levels from Birth”, the Bazinet lab demonstrates the importance of glucose as a key contributing source of carbon for brain palmitic synthesis and that a low palmitate diet exacerbates its utilization for brain palmitate synthesis de novo. Further, this impact is found in male mice rather than female mice, which adds an additional layer of importance. Mammals are known to conserve carbon and the brain has the ability to convert a variety of carbon sources to needed molecules, depending on the physiological needs of the brain. Overall, this paper contributes an important missing piece of the puzzle regarding carbon recycling in the brain and is a key piece of evidence that indeed the adult mammalian brain can convert glucose to carbons for use in saturated fatty acid synthesis. While brain glucose metabolism is known to contribute the carbons to support brain saturated and monounsaturated fatty biosynthesis de novo in the developing brains of young rodents, such a contribution to fatty acid biosynthesis in the adult brain is poorly understood. This Editorial highlights a study from the Bazinet laboratory (in the current issue of JNeurochem) illuminating the role of brain glucose metabolism in providing a carbon source from which palmitic acid is synthesized. The authors demonstrate the importance of glucose as a key contributing source of carbon for brain palmitic synthesis and that a low palmitate diet exacerbates the utilization of glucose in the brain. Overall, this paper contributes an important missing piece of the puzzle regarding carbon recycling in the brain and is a key piece of evidence that indeed the adult mammalian brain can convert glucose to carbons for use in saturated fatty acid synthesis.