Ralphiel S. Payne scite author profile

Aerobic energy metabolism uses glucose and oxygen to produce all the energy needs of the brain. Several studies published over the last 13 years challenged the assumption that the activated brain increases its oxidative glucose metabolism to meet the increased energy demands. Neuronal function in rat hippocampal slices supplied with 4 mM glucose could tolerate a 15 min activation by a 5 mM concentration of the excitatory neurotransmitter glutamate (Glu), whereas slices supplied with 10 mM glucose could tolerate a 15 min activation by 20 mM Glu. However, in slices in which neuronal lactate use was inhibited by the lactate transporter inhibitor a-cyano-4-hydroxycinnamate (4-CIN), activation by Glu elicited a permanent loss of neuronal function, with a twofold to threefold increase in tissue lactate content. Inhibition of glycolysis with the glucose analog 2-deoxy-D-glucose (2DG) during the period of exposure to Glu diminished normal neuronal function in the majority of slices and significantly reduced the number of slices that exhibited neuronal function after activation. However, when lactate was added with 2DG, the majority of the slices were neuronally functional after activation by Glu. NMDA, a nontransportable Glu analog by the glial glutamate transporter, could not induce a significant increase in slice lactate level when administered in the presence of 4-CIN. It is suggested that the heightened energy demands of activated neurons are met through increased glial glycolytic flux. The lactate thus formed is a crucial aerobic energy substrate that enables neurons to endure activation.

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Brain lactate, not glucose, fuels the recovery of synaptic function from hypoxia upon reoxygenation: an in vitro study

Schurr

et al. 1997

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Brain Lactate Is an Obligatory Aerobic Energy Substrate for Functional Recovery After Hypoxia: Further In Vitro Validation

Schurr¹,

Payne²,

Miller

et al. 1997

Journal of Neurochemistry

239

138

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This study used the rat hippocampal slice preparation and the monocarboxylate transporter inhibitor, α‐cyano‐4‐hydroxycinnamate (4‐CIN), to assess the obligatory role that lactate plays in fueling the recovery of synaptic function after hypoxia upon reoxygenation. At a concentration of 500 µM, 4‐CIN blocked lactate‐supported synaptic function in hippocampal slices under normoxic conditions in 15 min. The inhibitor had no effect on glucose‐supported synaptic function. Of control hippocampal slices exposed to 10‐min hypoxia, 77.8 ± 6.8% recovered synaptic function after 30‐min reoxygenation. Of slices supplemented with 500 µM 4‐CIN, only 15 ± 10.9% recovered synaptic function despite the large amount of lactate formed during the hypoxic period and the abundance of glucose present before, during, and after hypoxia. These results indicate that 4‐CIN, when present during hypoxia and reoxygenation, blocks lactate transport from astrocytes, where the bulk of anaerobic lactate is formed, to neurons, where lactate is being utilized aerobically to support recovery of function after hypoxia. These results unequivocally validate that brain lactate is an obligatory aerobic energy substrate for posthypoxia recovery of function.

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Lactate, not pyruvate, is neuronal aerobic glycolysis end product: An in vitro electrophysiological study

2007

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Blockade of lactate transport exacerbates delayed neuronal damage in a rat model of cerebral ischemia

et al. 2001

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Ralphiel S. Payne

An Increase in Lactate Output by Brain Tissue Serves to Meet the Energy Needs of Glutamate-Activated Neurons

Brain lactate, not glucose, fuels the recovery of synaptic function from hypoxia upon reoxygenation: an in vitro study

Brain Lactate Is an Obligatory Aerobic Energy Substrate for Functional Recovery After Hypoxia: Further In Vitro Validation

Lactate, not pyruvate, is neuronal aerobic glycolysis end product: An in vitro electrophysiological study

Blockade of lactate transport exacerbates delayed neuronal damage in a rat model of cerebral ischemia

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