IDH3γ functions as a redox switch regulating mitochondrial energy metabolism and contractility in the heart.
Maithily S NanadikarAna M Vergel LeonJia GuoGijsbert J van BelleAline JathoElvina S PhilipAstrid F BrandnerRainer A BöckmannRunzhu ShiAnke ZiesenissCarla M SiemssenKatja DettmerSusanne BrodesserMarlen SchmidtendorfJingyun LeeHanzhi WuCristina M FurduiSören BrandenburgJoseph Robert BurgoyneIvan BogeskiJan RiemerArpita ChowdhuryPeter RehlingTobias BruegmannVsevolod V BelousovDörthe Magdalena KatschinskiPublished in: Nature communications (2023)
Redox signaling and cardiac function are tightly linked. However, it is largely unknown which protein targets are affected by hydrogen peroxide (H 2 O 2 ) in cardiomyocytes that underly impaired inotropic effects during oxidative stress. Here, we combine a chemogenetic mouse model (HyPer-DAO mice) and a redox-proteomics approach to identify redox sensitive proteins. Using the HyPer-DAO mice, we demonstrate that increased endogenous production of H 2 O 2 in cardiomyocytes leads to a reversible impairment of cardiac contractility in vivo. Notably, we identify the γ-subunit of the TCA cycle enzyme isocitrate dehydrogenase (IDH)3 as a redox switch, linking its modification to altered mitochondrial metabolism. Using microsecond molecular dynamics simulations and experiments using cysteine-gene-edited cells reveal that IDH3γ Cys148 and 284 are critically involved in the H 2 O 2 -dependent regulation of IDH3 activity. Our findings provide an unexpected mechanism by which mitochondrial metabolism can be modulated through redox signaling processes.
Keyphrases
- oxidative stress
- molecular dynamics simulations
- hydrogen peroxide
- wild type
- low grade
- induced apoptosis
- mouse model
- electron transfer
- nitric oxide
- crispr cas
- ischemia reperfusion injury
- molecular docking
- metabolic syndrome
- insulin resistance
- adipose tissue
- type diabetes
- skeletal muscle
- cell cycle arrest
- copy number
- heat stress