Abstract
This study was the first comprehensive investigation of the dependence of mitochondrial enzyme response (catalytic subunits of mitochondrial complexes (MC) I-V, including NDUFV2, SDHA, Cyt b, COX1 and ATP5A) and mitochondrial ultrastructure in the rat cerebral cortex (CC) on the severity and duration of in vivo hypoxic exposures. The role of individual animal’s resistance to hypoxia was also studied. The respiratory chain (RC) was shown to respond to changes in environmental [O2] as follows: (a) differential reaction of mitochondrial enzymes, which depends on the severity of the hypoxic exposure and which indicates changes in the content and catalytic properties of mitochondrial enzymes, both during acute and multiple exposures; and (b) ultrastructural changes in mitochondria, which reflect various degrees of mitochondrial energization. Within a specific range of reduced O2 concentrations, activation of the MC II is a compensatory response supporting the RC electron transport function. In this process, MC I develops new kinetic properties, and its function recovers in hypoxia by reprograming the RC substrate site. Therefore, the mitochondrial RC performs as an in vivo molecular oxygen sensor. Substantial differences between responses of rats with high and low resistance to hypoxia were determined.
Highlights
Hypoxia is an extremely widespread phenomenon, which causes various pathologies, including myocardium infarction, stroke, ischemia, hemorrhage, etc
In normoxic conditions (21% O2 in exhaled air), concentrations of Mitochondrial Enzyme Complex (MC) I-V subunits differed in rats with different tolerance to hypoxia (Table 1), which was consistent with our previous data [25,26]
The same was true for the content of SDHA subunit, an iron-sulfur cluster component of Succinate Dehydrogenase Activity (SDH) (MC II)
Summary
Hypoxia is an extremely widespread phenomenon, which causes various pathologies, including myocardium infarction, stroke, ischemia, hemorrhage, etc. It has been convincingly proven that during adaptation to hypoxia, the cellular energy demand is met by modification of oxidative phosphorylation (OXPHOS), and by kinetic regulation and changes in properties and contents of mitochondrial enzymes [12,13,14,15]. In this process, the respiratory chain (RC) substrate site (mitochondrial complexes, MC I-II) plays a special role [5,11,16].
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