MitoPediaAlert2020 Archive: Difference between revisions
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| '''Non-mitochondrial respiration or [[residual oxygen consumption]] (''Rox'')? — Concept-driven constructive terminology frames our perception.''' | |||
After inhibition of electron-transfer (ET) pathways or in the absence of fuel substrates, both ''mitochondrial'' non-ET reactions and ''non-mitochondrial'' reactions contribute to ''residual oxygen consumption'' in mt-preparations and living cells. <br> | |||
- »'''[https://www.bioenergetics-communications.org/index.php/BEC_2020.1_doi10.26124bec2020-0001.v1 BEC: Mitochondrial physiology]'''« — Table 1: ''Rox'' induced by non-ET pathway oxidation reactions | |||
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Revision as of 08:42, 24 August 2020
- Currently Answered Questions from the »Oroboros Ecosystem Agenda«
Aug 2020
- Aug-26 We
Non-mitochondrial respiration or residual oxygen consumption (Rox)? — Concept-driven constructive terminology frames our perception. After inhibition of electron-transfer (ET) pathways or in the absence of fuel substrates, both mitochondrial non-ET reactions and non-mitochondrial reactions contribute to residual oxygen consumption in mt-preparations and living cells.
- »BEC: Mitochondrial physiology« — Table 1: Rox induced by non-ET pathway oxidation reactions
- Aug-20 Th
Would you like to simultaneously monitor O2 flux and the redox state of the Q-junction in isolated mitochondria? Soon you will be able to with the new Q-Module being developed as a part of the H2020 SME NextGen-O2k project:
- »Q-Module«
- Aug-13 Th
Photosynthesis efficiency is reduced by 25% in plants and algae due the metabolic process called photorespiration.
- »Photorespiration«
- Aug-06 Th
OXPHOS-coupling efficiency (1-L/P) describes the coupling of the mitochondrial electron transfer system. This coupling control factor ranges from 1.0 for a fully coupled system to 0.0 for a system with zero respiratory phosphorylation capacity (L=P). It is suggested to use OXPHOS-coupling efficiency instead of the respiratory acceptor control ratio (RCR) to evaluate mitochondrial coupling.