Journal
JOURNAL OF NUTRITION
Volume 130, Issue 4, Pages 1026S-1031SPublisher
AMER INST NUTRITION
DOI: 10.1093/jn/130.4.1026S
Keywords
glutamate; glutamine; branched-chain amino acids; glucose; transport; metabolism; neuron; glia; brain
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Funding
- NICHD NIH HHS [HD26979] Funding Source: Medline
- NINDS NIH HHS [NS34900, NS37915] Funding Source: Medline
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Intrasynaptic [glutamate] must be kept low in order to maximize the signal-to-noise ratio after the release of transmitter glutamate, This is accomplished by rapid uptake of glutamate into astrocytes, which convert glutamate into glutamine. The latter then is released to neurons, which, via mitochondrial glutaminase, form the glutamate that is used for neurotransmission. This pattern of metabolic compartmentation is the glutamate-glutamine cycle. This model is subject to the following two important qualifications: 1) brain avidly oxidizes glutamate via aspartate aminotransferase; and 2) because almost no glutamate crosses from blood to brain, it must be synthesized in the central nervous system (CNS). The primary source of glutamate carbon is glucose, and a major source of glutamate nitrogen is the branched-chain amino acids, which are transported vapidly into the CNS. This arrangement accomplishes the following: 1) maintenance of low external [glutamate], thereby maximizing signal-to-noise ratio upon depolarization; 2) the replenishing of the neuronal glutamate pool; 3) the trafficking of glutamate through the extracellular fluid In a nonneuroactive form (glutamine); 4) the importation of amino groups from blood, thus maintaining brain nitrogen homeostasis; and 5) the oxidation of glutamate/glutamine, a process that confers an additional level of control in terms of the regulation of brain glutamate, aspartate and gamma-aminobutyric acid.
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