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W3030092835 startingPage "1865" @default.
W3030092835 abstract "The antagonism between thiol oxidation and reduction enables efficient control of protein function and is used as central mechanism in cellular regulation. The best-studied mechanism is the dithiol-disulfide transition in the Calvin Benson Cycle in photosynthesis, including mixed disulfide formation by glutathionylation. The adjustment of the proper thiol redox state is a fundamental property of all cellular compartments. The glutathione redox potential of the cytosol, stroma, matrix and nucleoplasm usually ranges between −300 and −320 mV. Thiol reduction proceeds by short electron transfer cascades consisting of redox input elements and redox transmitters such as thioredoxins. Thiol oxidation ultimately is linked to reactive oxygen species (ROS) and reactive nitrogen species (RNS). Enhanced ROS production under stress shifts the redox network to more positive redox potentials. ROS do not react randomly but primarily with few specific redox sensors in the cell. The most commonly encountered reaction within the redox regulatory network however is the disulfide swapping. The thiol oxidation dynamics also involves transnitrosylation. This review compiles present knowledge on this network and its central role in sensing environmental cues with focus on chloroplast metabolism." @default.
W3030092835 created "2020-06-05" @default.
W3030092835 creator A5012666877 @default.
W3030092835 creator A5076890525 @default.
W3030092835 date "2020-05-28" @default.
W3030092835 modified "2023-09-24" @default.
W3030092835 title "Regulatory thiol oxidation in chloroplast metabolism, oxidative stress response and environmental signaling in plants" @default.
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W3030092835 doi "https://doi.org/10.1042/bcj20190124" @default.
W3030092835 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/32463881" @default.
W3030092835 hasPublicationYear "2020" @default.
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