Lactate promotes plasticity gene expression by potentiating NMDA signaling in neurons

Yang, Jiang-Yan; Ruchti, Evelyne; Petit, Jean Marie; Jourdain, Pascal; Grenningloh, Gabriele; Allaman, Igor; Magistretti, Pierre J.

doi:10.1073/pnas.1322912111

Cited by 404 publications

(406 citation statements)

References 37 publications

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“…It is, however, consistent with a more nuanced view of lactate dynamics where extracellular lactate originates from, and is metabolized by, multiple cell types, where lactate is scattered from the activated brain area via the astrocytic syncytium [34], and where lactate plays roles other than that of an energy substrate, e.g. redox signaling to switch on neuronal plasticity genes [35]. It still seem appropriate to challenge the conservative and somewhat static view on lactate shuttling between neurons and astrocytes that almost seem to predetermine conclusions from new studies regarding metabolite fluxes, as exemplified by a recent study on the interaction between oligodendrocytes and the axonal compartment of neurons [36,37].…”

Section: Malate Aspartate Shuttle In Isolated Brain Mitochondria and supporting

confidence: 75%

Fluctuations in Cytosolic Calcium Regulate the Neuronal Malate–Aspartate NADH Shuttle: Implications for Neuronal Energy Metabolism

Satrústegui

Bak

2015

Neurochem Res

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The malate-aspartate NADH shuttle (MAS) operates in neurons and other cells to translocate reducing equivalents from the cytosol to the mitochondrial matrix, thus allowing a continued flux through the glycolytic pathway and metabolism of extracellular lactate. Recent discoveries have taught us that MAS is regulated by fluctuations in cytosolic Ca 2? levels, and that this regulation is required to maintain a tight coupling between neuronal activity and mitochondrial respiration and oxidative phosphorylation. At cytosolic Ca 2? fluctuations below the threshold of the mitochondrial calcium uniporter, there is a positive correlation between Ca 2? and MAS activity; however, if cytosolic Ca 2? increases above the threshold, MAS activity is thought to be reduced by an intricate mechanism. The latter forces the neurons to partly rely on anaerobic glycolysis producing lactate that may be metabolized subsequently, by neurons or other cells. In this review, we will discuss the evidence for Ca 2? -mediated regulation of MAS that have been uncovered over the last decade or so, together with the need for further verification, and examine the metabolic ramifications for neurons.

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Section: Malate Aspartate Shuttle In Isolated Brain Mitochondria and supporting

confidence: 75%

Fluctuations in Cytosolic Calcium Regulate the Neuronal Malate–Aspartate NADH Shuttle: Implications for Neuronal Energy Metabolism

Satrústegui

Bak

2015

Neurochem Res

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“…38 However, upon neuronal activity, astrocytes can supply metabolic substrates, such as lactate, which neurons can use for energy provision 39,40 as well as for modulating neurotransmission. 41 Here we now decipher a molecular mechanism that explains the link between neuronal synaptic activity with astrocyte provision of antioxidant precursors to sustain neuronal survival. Whether this NMDAR-p35/Cdk5 pathway would also account for lactate provision from astrocytes to neurons 39,40 remains a tempting possibility yet to be explored.…”

Section: Discussionmentioning

confidence: 99%

Astrocyte NMDA receptors' activity sustains neuronal survival through a Cdk5–Nrf2 pathway

et al. 2015

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Neurotransmission unavoidably increases mitochondrial reactive oxygen species. However, the intrinsic antioxidant defense of neurons is weak and hence the mechanism whereby these cells are physiologically protected against oxidative damage is unknown. Here we found that the antioxidant defense of neurons is repressed owing to the continuous protein destabilization of the master antioxidant transcriptional activator, nuclear factor-erythroid 2-related factor-2 (Nrf2). By contrast, Nrf2 is highly stable in neighbor astrocytes explaining their robust antioxidant defense and resistance against oxidative stress. We also show that subtle and persistent stimulation of N-methyl-D-aspartate receptors (NMDAR) in astrocytes, through a mechanism not requiring extracellular Ca 2+ influx, upregulates a signal transduction pathway involving phospholipase C-mediated endoplasmic reticulum release of Ca 2+ and protein kinase Cδ activation. Active protein kinase Cδ promotes, by phosphorylation, the stabilization of p35, a cyclin-dependent kinase-5 (Cdk5) cofactor. Active p35/Cdk5 complex in the cytosol phosphorylates Nrf2 at Thr 395 , Ser 433 and Thr 439 that is sufficient to promote Nrf2 translocation to the nucleus and induce the expression of antioxidant genes. Furthermore, this Cdk5-Nrf2 transduction pathway boosts glutathione metabolism in astrocytes efficiently protecting closely spaced neurons against oxidative damage. Thus, intercellular communication through NMDAR couples neurotransmission with neuronal survival.

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“…100 Interestingly, redox modulation of the NMDA receptor has recently been shown to mediate several of the effects of lactate on brain function. 101 …”

Section: Lactate-a Volume Transmittermentioning

confidence: 99%

Lactate Transport and Signaling in the Brain: Potential Therapeutic Targets and Roles in Body—Brain Interaction

Bergersen

2014

J Cereb Blood Flow Metab

199

166

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Lactate acts as a 'buffer' between glycolysis and oxidative metabolism. In addition to being exchanged as a fuel by the monocarboxylate transporters (MCTs) between cells and tissues with different glycolytic and oxidative rates, lactate may be a 'volume transmitter' of brain signals. According to some, lactate is a preferred fuel for brain metabolism. Immediately after brain activation, the rate of glycolysis exceeds oxidation, leading to net production of lactate. At physical rest, there is a net efflux of lactate from the brain into the blood stream. But when blood lactate levels rise, such as in physical exercise, there is net influx of lactate from blood to brain, where the lactate is used for energy production and myelin formation. Lactate binds to the lactate receptor GPR81 aka hydroxycarboxylic acid receptor (HCAR1) on brain cells and cerebral blood vessels, and regulates the levels of cAMP. The localization and function of HCAR1 and the three MCTs (MCT1, MCT2, and MCT4) expressed in brain constitute the focus of this review. They are possible targets for new therapeutic drugs and interventions. The author proposes that lactate actions in the brain through MCTs and the lactate receptor underlie part of the favorable effects on the brain resulting from physical exercise.

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Lactate promotes plasticity gene expression by potentiating NMDA signaling in neurons

Cited by 404 publications

References 37 publications

Fluctuations in Cytosolic Calcium Regulate the Neuronal Malate–Aspartate NADH Shuttle: Implications for Neuronal Energy Metabolism

Fluctuations in Cytosolic Calcium Regulate the Neuronal Malate–Aspartate NADH Shuttle: Implications for Neuronal Energy Metabolism

Astrocyte NMDA receptors' activity sustains neuronal survival through a Cdk5–Nrf2 pathway

Lactate Transport and Signaling in the Brain: Potential Therapeutic Targets and Roles in Body—Brain Interaction

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