Your search keyword '"Chatton JY"' showing total 4 results

1. The Lactate Receptor HCAR1 Modulates Neuronal Network Activity through the Activation of G α and G βγ Subunits.

Author

de Castro Abrantes H, Briquet M, Schmuziger C, Restivo L, Puyal J, Rosenberg N, Rocher AB, Offermanns S, and Chatton JY

Subjects

Action Potentials, Animals, Calcium Signaling drug effects, Cells, Cultured, Cerebral Cortex cytology, Cyclic AMP physiology, Excitatory Postsynaptic Potentials drug effects, Excitatory Postsynaptic Potentials physiology, Female, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, Miniature Postsynaptic Potentials drug effects, Miniature Postsynaptic Potentials physiology, Nerve Tissue Proteins agonists, Nerve Tissue Proteins deficiency, Nerve Tissue Proteins genetics, Neurons drug effects, Primary Cell Culture, Receptors, G-Protein-Coupled agonists, Receptors, G-Protein-Coupled deficiency, Receptors, G-Protein-Coupled genetics, Second Messenger Systems drug effects, Heterotrimeric GTP-Binding Proteins physiology, Lactates metabolism, Nerve Tissue Proteins physiology, Neurons physiology, Receptors, G-Protein-Coupled physiology

Abstract

The discovery of a G-protein-coupled receptor for lactate named hydroxycarboxylic acid receptor 1 (HCAR1) in neurons has pointed to additional nonmetabolic effects of lactate for regulating neuronal network activity. In this study, we characterized the intracellular pathways engaged by HCAR1 activation, using mouse primary cortical neurons from wild-type (WT) and HCAR1 knock-out (KO) mice from both sexes. Using whole-cell patch clamp, we found that the activation of HCAR1 with 3-chloro-5-hydroxybenzoic acid (3Cl-HBA) decreased miniature EPSC frequency, increased paired-pulse ratio, decreased firing frequency, and modulated membrane intrinsic properties. Using fast calcium imaging, we show that HCAR1 agonists 3,5-dihydroxybenzoic acid, 3Cl-HBA, and lactate decreased by 40% spontaneous calcium spiking activity of primary cortical neurons from WT but not from HCAR1 KO mice. Notably, in neurons lacking HCAR1, the basal activity was increased compared with WT. HCAR1 mediates its effect in neurons through a G iα -protein. We observed that the adenylyl cyclase-cAMP-protein kinase A axis is involved in HCAR1 downmodulation of neuronal activity. We found that HCAR1 interacts with adenosine A1, GABA B , and α 2A -adrenergic receptors, through a mechanism involving both its G iα and G iβγ subunits, resulting in a complex modulation of neuronal network activity. We conclude that HCAR1 activation in neurons causes a downmodulation of neuronal activity through presynaptic mechanisms and by reducing neuronal excitability. HCAR1 activation engages both G iα and G iβγ intracellular pathways to functionally interact with other G i -coupled receptors for the fine tuning of neuronal activity. SIGNIFICANCE STATEMENT Expression of the lactate receptor hydroxycarboxylic acid receptor 1 (HCAR1) was recently described in neurons. Here, we describe the physiological role of this G-protein-coupled receptor (GPCR) and its activation in neurons, providing information on its expression and mechanism of action. We dissected out the intracellular pathway through which HCAR1 activation tunes down neuronal network activity. For the first time, we provide evidence for the functional cross talk of HCAR1 with other GPCRs, such as GABA B , adenosine A1- and α 2A -adrenergic receptors. These results set HCAR1 as a new player for the regulation of neuronal network activity acting in concert with other established receptors. Thus, HCAR1 represents a novel therapeutic target for pathologies characterized by network hyperexcitability dysfunction, such as epilepsy., (Copyright © 2019 the authors.)

Published

2019

2. Sustaining sleep spindles through enhanced SK2-channel activity consolidates sleep and elevates arousal threshold.

Author

Wimmer RD, Astori S, Bond CT, Rovó Z, Chatton JY, Adelman JP, Franken P, and Lüthi A

Subjects

Action Potentials, Animals, Auditory Threshold, Cells, Cultured physiology, Electroencephalography, Female, Inhibitory Postsynaptic Potentials physiology, Male, Mice, Mice, Inbred C57BL, Patch-Clamp Techniques, Polysomnography, Recombinant Fusion Proteins biosynthesis, Recombinant Fusion Proteins physiology, Small-Conductance Calcium-Activated Potassium Channels biosynthesis, Small-Conductance Calcium-Activated Potassium Channels genetics, Specific Pathogen-Free Organisms, Thalamic Nuclei cytology, Up-Regulation, Arousal physiology, Sleep Stages physiology, Small-Conductance Calcium-Activated Potassium Channels physiology, Thalamic Nuclei physiology

Abstract

Sleep spindles are synchronized 11-15 Hz electroencephalographic (EEG) oscillations predominant during nonrapid-eye-movement sleep (NREMS). Rhythmic bursting in the reticular thalamic nucleus (nRt), arising from interplay between Ca(v)3.3-type Ca(2+) channels and Ca(2+)-dependent small-conductance-type 2 (SK2) K(+) channels, underlies spindle generation. Correlative evidence indicates that spindles contribute to memory consolidation and protection against environmental noise in human NREMS. Here, we describe a molecular mechanism through which spindle power is selectively extended and we probed the actions of intensified spindling in the naturally sleeping mouse. Using electrophysiological recordings in acute brain slices from SK2 channel-overexpressing (SK2-OE) mice, we found that nRt bursting was potentiated and thalamic circuit oscillations were prolonged. Moreover, nRt cells showed greater resilience to transit from burst to tonic discharge in response to gradual depolarization, mimicking transitions out of NREMS. Compared with wild-type littermates, chronic EEG recordings of SK2-OE mice contained less fragmented NREMS, while the NREMS EEG power spectrum was conserved. Furthermore, EEG spindle activity was prolonged at NREMS exit. Finally, when exposed to white noise, SK2-OE mice needed stronger stimuli to arouse. Increased nRt bursting thus strengthens spindles and improves sleep quality through mechanisms independent of EEG slow waves (<4 Hz), suggesting SK2 signaling as a new potential therapeutic target for sleep disorders and for neuropsychiatric diseases accompanied by weakened sleep spindles.

Published

2012

3. Glutamate transport decreases mitochondrial pH and modulates oxidative metabolism in astrocytes.

Author

Azarias G, Perreten H, Lengacher S, Poburko D, Demaurex N, Magistretti PJ, and Chatton JY

Subjects

Analysis of Variance, Animals, Biological Transport, Cells, Cultured, Cerebral Cortex metabolism, Energy Metabolism, Hydrogen-Ion Concentration, Mice, Neurons metabolism, Amino Acid Transport System X-AG metabolism, Astrocytes metabolism, Glutamic Acid metabolism, Mitochondria metabolism, Oxygen metabolism

Abstract

During synaptic activity, the clearance of neuronally released glutamate leads to an intracellular sodium concentration increase in astrocytes that is associated with significant metabolic cost. The proximity of mitochondria at glutamate uptake sites in astrocytes raises the question of the ability of mitochondria to respond to these energy demands. We used dynamic fluorescence imaging to investigate the impact of glutamatergic transmission on mitochondria in intact astrocytes. Neuronal release of glutamate induced an intracellular acidification in astrocytes, via glutamate transporters, that spread over the mitochondrial matrix. The glutamate-induced mitochondrial matrix acidification exceeded cytosolic acidification and abrogated cytosol-to-mitochondrial matrix pH gradient. By decoupling glutamate uptake from cellular acidification, we found that glutamate induced a pH-mediated decrease in mitochondrial metabolism that surpasses the Ca(2+)-mediated stimulatory effects. These findings suggest a model in which excitatory neurotransmission dynamically regulates astrocyte energy metabolism by limiting the contribution of mitochondria to the metabolic response, thereby increasing the local oxygen availability and preventing excessive mitochondrial reactive oxygen species production.

Published

2011

4. Brain-derived neurotrophic factor stimulates energy metabolism in developing cortical neurons.

Author

Burkhalter J, Fiumelli H, Allaman I, Chatton JY, and Martin JL

Subjects

Amino Acids metabolism, Amino Acids pharmacokinetics, Animals, Biological Transport drug effects, Cells, Cultured, Cerebral Cortex cytology, Cerebral Cortex embryology, Deoxyglucose pharmacokinetics, Glucose metabolism, Glucose pharmacokinetics, Glucose Transporter Type 3, Kinetics, Mice, Monosaccharide Transport Proteins genetics, Monosaccharide Transport Proteins metabolism, Neurons cytology, Neuropeptide Y biosynthesis, Protein Biosynthesis, RNA, Messenger metabolism, Sodium metabolism, Sodium-Potassium-Exchanging ATPase metabolism, Brain-Derived Neurotrophic Factor pharmacology, Cerebral Cortex metabolism, Energy Metabolism drug effects, Nerve Tissue Proteins, Neurons drug effects, Neurons metabolism

Abstract

Brain-derived neurotrophic factor (BDNF) promotes the biochemical and morphological differentiation of selective populations of neurons during development. In this study we examined the energy requirements associated with the effects of BDNF on neuronal differentiation. Because glucose is the preferred energy substrate in the brain, the effect of BDNF on glucose utilization was investigated in developing cortical neurons via biochemical and imaging studies. Results revealed that BDNF increases glucose utilization and the expression of the neuronal glucose transporter GLUT3. Stimulation of glucose utilization by BDNF was shown to result from the activation of Na+/K+-ATPase via an increase in Na+ influx that is mediated, at least in part, by the stimulation of Na+-dependent amino acid transport. The increased Na+-dependent amino acid uptake by BDNF is followed by an enhancement of overall protein synthesis associated with the differentiation of cortical neurons. Together, these data demonstrate the ability of BDNF to stimulate glucose utilization in response to an enhanced energy demand resulting from increases in amino acid uptake and protein synthesis associated with the promotion of neuronal differentiation by BDNF.

Published

2003