Current technical approaches to brain energy metabolism

Barros, L. Felipe; Bolaños, Juan P.; Bonvento, Gilles; Bouzier‐Sore, Anne‐Karine; Brown, Angus M.; Hirrlinger, Johannes; Kasparov, Sergey; Kirchhoff, Frank; Murphy, Anne N.; Pellerin, Luc; Robinson, Michael B.; Weber, Bruno

doi:10.1002/glia.23248

Cited by 46 publications

(31 citation statements)

References 192 publications

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“…A new approach to mitochondrial function Mitochondria are the chief ATP producers of eukaryotic cells and also a principal site for the generation of building blocks for macromolecular synthesis. The speeds of these catabolic and anabolic pathways are assessed by diverse techniques 30 of complementary strengths and weaknesses. For catabolism, respirometry is the standard technique since the days of Otto Warburg.…”

Section: Discussionmentioning

confidence: 99%

“…A protocol to approach flux was devised based on the idea that acute inhibition of mitochondrial pyruvate entry at the MPC should cause a progressive fall in mitochondrial pyruvate as it is consumed by PDH and PC. Analogous methods have been applied successfully to the measurement of whole cell glucose, lactate and pyruvate consumptions in various cell types 9,29,30 .…”

Section: Quantification Of Mitochondrial Pyruvate Fluxmentioning

confidence: 99%

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A highly responsive pyruvate sensor reveals pathway-regulatory role of the mitochondrial pyruvate carrier MPC

Arce-Molina

Cortés-Molina

Sandoval

et al. 2019

Preprint

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Mitochondria generate ATP and building blocks for cell growth and regeneration, using pyruvate as the main substrate. Here we introduce PyronicSF, a user-friendly GFP-based sensor of improved dynamic range that enables real-time subcellular quantitation of mitochondrial pyruvate transport, concentration and flux. We report that cultured mouse astrocytes maintain mitochondrial pyruvate in the low micromolar range, below cytosolic pyruvate, which means that the mitochondrial pyruvate carrier MPC controls the decision between respiration and anaplerosis/gluconeogenesis in an ultrasensitive fashion. The functionality of the sensor in living tissue is demonstrated in the brain of Drosophila melanogaster larvae. Mitochondrial subpopulations are known to coexist within a given cell, which differ in their morphology, mobility, membrane potential, and vicinity to other organelles. The present tool can be used to investigate how mitochondrial diversity relates to metabolism, to study the role of MPC in disease, and to screen for small-molecule MPC modulators.

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Section: Discussionmentioning

confidence: 99%

Section: Quantification Of Mitochondrial Pyruvate Fluxmentioning

confidence: 99%

A highly responsive pyruvate sensor reveals pathway-regulatory role of the mitochondrial pyruvate carrier MPC

Arce-Molina

Cortés-Molina

Sandoval

et al. 2019

Preprint

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“…A drawback of our study is that it is mainly based on data from transcriptomic studies, and hence it may not precisely reflect metabolic fluxes (Chubukov et al, ). Nevertheless transcriptomic studies have previously led to the identification of metabolic pathways (Corominas et al, ; Hu, Gu, Sun, Bai, & Wang, ) and they are a sound approach to address brain metabolism in humans (Barros et al, ). Moreover, genomic‐based models have been extensively used to study metabolic networks (Duarte et al, ) and to simulate metabolic‐based phenotypes of cancer cells (Gruetter, Seaquist, & Ugurbil, ; Lewis & Abdel‐Haleem, ; Lewis et al, ).…”

Section: Discussionmentioning

confidence: 99%

GSEA of mouse and human mitochondriomes reveals fatty acid oxidation in astrocytes

Eraso-Pichot

Brasó-Vives

Golbano

et al. 2018

Glia

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The prevalent view in neuroenergetics is that glucose is the main brain fuel, with neurons being mostly oxidative and astrocytes glycolytic. Evidence supporting that astrocyte mitochondria are functional has been overlooked. Here we sought to determine what is unique about astrocyte mitochondria by performing unbiased statistical comparisons of the mitochondriome in astrocytes and neurons. Using MitoCarta, a compendium of mitochondrial proteins, together with transcriptomes of mouse neurons and astrocytes, we generated cell-specific databases of nuclear genes encoding for mitochondrion proteins, ranked according to relative expression. Standard and in-house Gene Set Enrichment Analyses (GSEA) of five mouse transcriptomes revealed that genes encoding for enzymes involved in fatty acid oxidation (FAO) and amino acid catabolism are consistently more expressed in astrocytes than in neurons. FAO and oxidative-metabolism-related genes are also up-regulated in human cortical astrocytes versus the whole cortex, and in adult astrocytes versus fetal astrocytes. We thus present the first evidence of FAO in human astrocytes. Further, as shown in vitro, FAO coexists with glycolysis in astrocytes and is inhibited by glutamate. Altogether, these analyses provide arguments against the glucose-centered view of energy metabolism in astrocytes and reveal mitochondria as specialized organelles in these cells.

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“…In the last years, a large toolbox of genetically‐encoded nanosensors for metabolite imaging were developed, among them different sensors for ATP (Barros et al, ; Nakano, Imamura, Nagai, & Noji, ; Rajendran et al, ; Tantama et al, ; Yaginuma et al, ). Ateam, the sensor employed in the present study, exists in several variants, which exhibit different binding affinities to ATP ranging from several µM to 3.3 mM (Imamura et al, ).…”

Section: Discussionmentioning

confidence: 99%

“…While there is a wealth of experimental evidence supporting this so‐called astrocyte‐neuron lactate shuttle, there is an ongoing debate about its relevance (Bak & Walls, ; Barros & Weber, ), indicating that many aspects of neuron‐glia interaction and metabolic relationships between astrocytes and neurons are still not understood in detail. This is partly due to the lack of appropriate tools in the past, circumventing a dynamic determination of activity‐related changes in energy metabolites in brain tissue with (sub‐) cellular resolution (Barros et al, ). The recent development of suitable genetically encoded fluorescence sensors for metabolites such as ATP, glucose, lactate, or pyruvate (San Martin et al, ; Tantama, Hung, & Yellen, ) has provided first exciting new insights into cellular metabolism in cells in primary culture (Bittner et al, ; Tantama, Martinez‐Francois, Mongeon, & Yellen, ; Winkler et al, ), in isolated white matter tracts (Trevisiol et al ), brain tissue slices (Fernandez‐Moncada et al, ; Köhler et al, ), as well as in vivo (Mächler et al, ).…”

Section: Introductionmentioning

confidence: 99%

FRET‐based imaging of intracellular ATP in organotypic brain slices

Lerchundi

Kafitz

Winkler

et al. 2018

J of Neuroscience Research

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Active neurons require a substantial amount of adenosine triphosphate (ATP) to re‐establish ion gradients degraded by ion flux across their plasma membranes. Despite this fact, neurons, in contrast to astrocytes, do not contain any significant stores of energy substrates. Recent work has provided evidence for a neuro‐metabolic coupling between both cell types, in which increased glycolysis and lactate production in astrocytes support neuronal metabolism. Here, we established the cell type‐specific expression of the Förster resonance energy transfer (FRET) based nanosensor ATeam1.03YEMK (“Ateam”) for dynamic measurement of changes in intracellular ATP levels in organotypic brain tissue slices. To this end, adeno‐associated viral vectors coding for Ateam, driven by either the synapsin‐ or glial fibrillary acidic protein (GFAP) promoter were employed for specific transduction of neurons or astrocytes, respectively. Chemical ischemia, induced by perfusion of tissue slices with metabolic inhibitors of cellular glycolysis and mitochondrial respiration, resulted in a rapid decrease in the cellular Ateam signal to a new, low level, indicating nominal depletion of intracellular ATP. Increasing the extracellular potassium concentration to 8 mM, thereby mimicking the release of potassium from active neurons, did not alter ATP levels in neurons. It, however, caused in an increase in ATP levels in astrocytes, a result which was confirmed in acutely isolated tissue slices. In summary, our results demonstrate that organotypic cultured slices are a reliable tool for FRET‐based dynamic imaging of ATP in neurons and astrocytes. They moreover provide evidence for an increased ATP synthesis in astrocytes, but not neurons, during periods of elevated extracellular potassium concentrations.

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Current technical approaches to brain energy metabolism

Cited by 46 publications

References 192 publications

A highly responsive pyruvate sensor reveals pathway-regulatory role of the mitochondrial pyruvate carrier MPC

A highly responsive pyruvate sensor reveals pathway-regulatory role of the mitochondrial pyruvate carrier MPC

GSEA of mouse and human mitochondriomes reveals fatty acid oxidation in astrocytes

FRET‐based imaging of intracellular ATP in organotypic brain slices

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