Abstract
We examine the effect of oxidative stress on the stability of mitochondrial respiratory complexes and their association into supercomplexes (SCs) in the neuron-specific Rieske iron sulfur protein (RISP) and COX10 knockout (KO) mice. Previously we reported that these two models display different grades of oxidative stress in distinct brain regions. Using blue native gel electrophoresis, we observed a redistribution of the architecture of SCs in KO mice. Brain regions with moderate levels of oxidative stress (cingulate cortex of both COX10 and RISP KO and hippocampus of the RISP KO) showed a significant increase in the levels of high molecular weight (HMW) SCs. High levels of oxidative stress in the piriform cortex of the RISP KO negatively impacted the stability of CI, CIII and SCs. Treatment of the RISP KO with the mitochondrial targeted antioxidant mitoTEMPO preserved the stability of respiratory complexes and formation of SCs in the piriform cortex and increased the levels of glutathione peroxidase. These results suggest that mild to moderate levels of oxidative stress can modulate SCs into a more favorable architecture of HMW SCs to cope with rising levels of free radicals and cover the energetic needs.
Highlights
The mitochondrial electron transport chain (ETC), located in the inner mitochondrial membrane, is composed of four multimeric enzymes (Complexes I to IV or CI–CIV) and two mobile electron carriers
To understand the regulation of SCs in vivo, we examined the levels of CI and SCs in mitochondria from different brain regions of neuron-specific COX10 and Rieske iron sulfur protein (RISP) KO mice
We previously showed that the COX10 KO had lower levels of oxidative stress markers than the RISP KO
Summary
The mitochondrial electron transport chain (ETC), located in the inner mitochondrial membrane, is composed of four multimeric enzymes (Complexes I to IV or CI–CIV) and two mobile electron carriers (coenzyme Q and cytochrome c). The protons in the IMS are translocated back into the matrix by ATP synthase (complex V or CV) coupling the ETC to ATP production This process is known as oxidative phosphorylation (OXPHOS). What was initially believed to be an artifact quickly gained acceptance in the field and a decade ago the first studies investigating the functionality of mammalian SCs were performed by Enriquez’s group [7]. They convincingly demonstrated that isolated respirasomes “respired” by transferring electrons from NADH to oxygen [7]. Lipids like cardiolipin seem to be essential for stability of SCs [8] and proteins like Rcf in yeast and HIG2A in mammals, COX7a2L and MCJ/DnaJC15 have been described as regulators of SC assembly [9,10,11,12,13,14,15]
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