Abstract
Plants have adopted a number of mechanisms to restore redox homeostasis in the chloroplast under fluctuating light conditions in nature. Chloroplast thioredoxin systems are crucial components of this redox network, mediating environmental signals to chloroplast proteins. In the reduced state, thioredoxins control the structure and function of proteins by reducing disulfide bridges in the redox active site of a protein. Subsequently, an oxidized thioredoxin is reduced by a thioredoxin reductase, the two enzymes together forming a thioredoxin system. Plant chloroplasts have versatile thioredoxin systems, including two reductases dependent on ferredoxin and NADPH as reducing power, respectively, several types of thioredoxins, and the system to deliver thiol redox signals to the thylakoid membrane and lumen. Light controls the activity of chloroplast thioredoxin systems in two ways. First, light reactions activate the thioredoxin systems via donation of electrons to oxidized ferredoxin and NADP+, and second, light induces production of reactive oxygen species in chloroplasts which deactivate the components of the thiol redox network. The diversity and partial redundancy of chloroplast thioredoxin systems enable chloroplast metabolism to rapidly respond to ever-changing environmental conditions and to raise plant fitness in natural growth conditions.
Highlights
Covalent modification of the amino acid side chain is the most common posttranscriptional mechanism to control protein function in cells
The cysteine residues (Cys) content in proteins has increased during their evolution, and the Cys forming disulfide bonds are more conserved than those not involved in redox regulation [1,2]
Two thioredoxin reductases exist in chloroplasts, using ferredoxin (FTR) or NADPH (NTRC) as an electron donor in the reduction of the TRX active site [6,20]
Summary
Covalent modification of the amino acid side chain is the most common posttranscriptional mechanism to control protein function in cells. They induce reductive cleavage of a disulfide bond in target proteins via a bimolecular nucleophilic substitution reaction. Plants are distinguished from other organisms by having highly versatile TRX systems, including two TRs dependent on ferredoxin (FTR) and NADPH (NTR) as reducing power, respectively, and multiple types of TRXs (h, o, f, m, x, y, z, and several TRX-like proteins) [3,4]. The majority of these TRXs are localized to plant chloroplasts, which emphasizes the impact of TRX-dependent regulation of proteins in chloroplasts. TRX systems on the redox signalling in fluctuating light conditions with specific focus on thiol-redox networks from stroma to thylakoids and lumen
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