Defective NADPH production in mitochondrial disease complex I causes inflammation and cell death

Balsa, Eduardo; Perry, Elizabeth A.; Bennett, Christopher F.; Jedrychowski, Mark; Gygi, Steven P.; Doench, John G.; Puigserver, Pere

Defective NADPH production in mitochondrial disease complex I causes inflammation and cell death

Eduardo Balsa, Elizabeth A. Perry, Christopher F. Bennett, Mark Jedrychowski, Steven P. Gygi, John G. Doench and Pere Puigserver ()
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Eduardo Balsa: Dana-Farber Cancer Institute
Elizabeth A. Perry: Dana-Farber Cancer Institute
Christopher F. Bennett: Dana-Farber Cancer Institute
Mark Jedrychowski: Harvard Medical School
Steven P. Gygi: Harvard Medical School
John G. Doench: Broad Institute of MIT and Harvard
Pere Puigserver: Dana-Farber Cancer Institute

Nature Communications, 2020, vol. 11, issue 1, 1-12

Abstract: Abstract Electron transport chain (ETC) defects occurring from mitochondrial disease mutations compromise ATP synthesis and render cells vulnerable to nutrient and oxidative stress conditions. This bioenergetic failure is thought to underlie pathologies associated with mitochondrial diseases. However, the precise metabolic processes resulting from a defective mitochondrial ETC that compromise cell viability under stress conditions are not entirely understood. We design a whole genome gain-of-function CRISPR activation screen using human mitochondrial disease complex I (CI) mutant cells to identify genes whose increased function rescue glucose restriction-induced cell death. The top hit of the screen is the cytosolic Malic Enzyme (ME1), that is sufficient to enable survival and proliferation of CI mutant cells under nutrient stress conditions. Unexpectedly, this metabolic rescue is independent of increased ATP synthesis through glycolysis or oxidative phosphorylation, but dependent on ME1-produced NADPH and glutathione (GSH). Survival upon nutrient stress or pentose phosphate pathway (PPP) inhibition depends on compensatory NADPH production through the mitochondrial one-carbon metabolism that is severely compromised in CI mutant cells. Importantly, this defective CI-dependent decrease in mitochondrial NADPH production pathway or genetic ablation of SHMT2 causes strong increases in inflammatory cytokine signatures associated with redox dependent induction of ASK1 and activation of stress kinases p38 and JNK. These studies find that a major defect of CI deficiencies is decreased mitochondrial one-carbon NADPH production that is associated with increased inflammation and cell death.

Date: 2020
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DOI: 10.1038/s41467-020-16423-1

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