Paradoxical neuronal hyperexcitability in a mouse model of mitochondrial pyruvate import deficiency.

Andres De La Rossa,Marine H Laporte,Simone Astori,Jean-Claude Martinou,José Manuel Nunes,Carmen Sandi,Preethi Sheshadri,Eric B Taylor,Michael R Duchen,Eva Ramos-Fernández,Jared Rutter,Alan Carleton,Thomas Marissal,Charles Quairiaux,Pablo Mendez,Sylvie Montessuit,Abbas Khani

doi:10.7554/elife.72595

Abstract

Neuronal excitation imposes a high demand of ATP in neurons. Most of the ATP derives primarily from pyruvate-mediated oxidative phosphorylation, a process that relies on import of pyruvate into mitochondria occuring exclusively via the mitochondrial pyruvate carrier (MPC). To investigate whether deficient oxidative phosphorylation impacts neuron excitability, we generated a mouse strain carrying a conditional deletion of MPC1, an essential subunit of the MPC, specifically in adult glutamatergic neurons. We found that, despite decreased levels of oxidative phosphorylation and decreased mitochondrial membrane potential in these excitatory neurons, mice were normal at rest. Surprisingly, in response to mild inhibition of GABA mediated synaptic activity, they rapidly developed severe seizures and died, whereas under similar conditions the behavior of control mice remained unchanged. We report that neurons with a deficient MPC were intrinsically hyperexcitable as a consequence of impaired calcium homeostasis, which reduced M-type potassium channel activity. Provision of ketone bodies restored energy status, calcium homeostasis and M-channel activity and attenuated seizures in animals fed a ketogenic diet. Our results provide an explanation for the seizures that frequently accompany a large number of neuropathologies, including cerebral ischemia and diverse mitochondriopathies, in which neurons experience an energy deficit.

Highlights

The brain is by far the main consumer of glucose and oxygen in the body, with pre- and postsynaptic mechanisms being the primary sites of ATP consumption[1,2,3]
To assess the role of the mitochondrial pyruvate carrier (MPC) in neuronal oxidative phosphorylation (OXPHOS), we first used primary cultures of cortical neurons largely depleted of astrocytes
Expression of either of the two shRNAs produced a significant reduction in MPC1 and MPC2 protein levels (Supplementary figure 1b, c)

Summary

Introduction

The brain is by far the main consumer of glucose and oxygen in the body, with pre- and postsynaptic mechanisms being the primary sites of ATP consumption[1,2,3]. Most of the ATP in neurons is produced in mitochondria through pyruvate-mediated oxidative phosphorylation (OXPHOS), even though aerobic glycolysis, or the so-called Warburg effect, can generate sufficient ATP to sustain several neuronal functions, including neuronal firing[3,4,5,6,7]. Pyruvate is produced either by glycolysis or through the action of lactate dehydrogenase, which mainly uses lactate derived from astrocytes[8]. Pyruvate transport into mitochondria provides fuel for the tricarboxylic acid (TCA) cycle and boosts ATP production by OXPHOS. Deletion of MPC1 or MPC2 is sufficient to inactivate the carrier activity, and in the mouse causes embryonic lethality at E12(11, 12). Providing ketone bodies, which directly feed the TCA cycle with acetyl-CoA and boost

Methods

Results

Conclusion