Linking epigenetic dysregulation, mitochondrial impairment, and metabolic dysfunction in SBMA motor neurons
Naemeh Pourshafie, … , Christopher Grunseich, Kenneth H. Fischbeck
Naemeh Pourshafie, … , Christopher Grunseich, Kenneth H. Fischbeck
Published July 9, 2020
Citation Information: JCI Insight. 2020;5(13):e136539. https://doi.org/10.1172/jci.insight.136539.
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Research Article Genetics Neuroscience

Linking epigenetic dysregulation, mitochondrial impairment, and metabolic dysfunction in SBMA motor neurons

Abstract

Spinal and bulbar muscular atrophy (SBMA) is a neuromuscular disorder caused by a polyglutamine expansion in the androgen receptor (AR). Using gene expression analysis and ChIP sequencing, we mapped transcriptional changes in genetically engineered patient stem cell–derived motor neurons. We found that transcriptional dysregulation in SBMA can occur through AR-mediated histone modification. We detected reduced histone acetylation, along with decreased expression of genes encoding compensatory metabolic proteins and reduced substrate availability for mitochondrial function. Furthermore, we found that pyruvate supplementation corrected this deficiency and improved mitochondrial function and SBMA motor neuron viability. We propose that epigenetic dysregulation of metabolic genes contributes to reduced mitochondrial ATP production. Our results show a molecular link between altered epigenetic regulation and mitochondrial metabolism that contributes to neurodegeneration.

Authors

Naemeh Pourshafie, Ester Masati, Eric Bunker, Alec R. Nickolls, Parisorn Thepmankorn, Kory Johnson, Xia Feng, Tyler Ekins, Christopher Grunseich, Kenneth H. Fischbeck

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Figure 6

The interrelationship between mitochondrial dysfunction and transcriptional dysregulation.

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The interrelationship between mitochondrial dysfunction and transcriptio...
Flow diagram depicting low acetyl-CoA levels as a central metabolic change that connects reduced expression of metabolic genes to mitochondrial ATP production impairment. From left, altered p300/CBP activity, which may be due to sequestration and depletion by the mutant AR (40), leads to reduced H3K27ac. This in turn contributes to repression of ETC and metabolic genes. Repression of these genes perturbs compensatory metabolic pathways, which results in insufficient production of acetyl-CoA. Acetyl-CoA is a common substrate for both the ETC function and p300/CBP HAT activity. Low acetyl-CoA (substrate) contributes to low ATP production and mitochondrial dysfunction. In parallel, when the energy demands of the cell increase, mitochondria respond by consuming more acetyl-CoA (substrate). The reduction of acetyl-CoA contributes to repression of ETC and metabolic genes through impaired p300/CBP acetylation.