Potential regulation of gene expression in photosynthetic cells by redox and energy state: approaches towards better understanding

doi:10.1093/aob/mcn081

AOBPreview originally published online on May 20, 2008
Annals of Botany 2009 103(4):599-607; doi:10.1093/aob/mcn081

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Potential regulation of gene expression in photosynthetic cells by redox and energy state: approaches towards better understanding

T. Pfannschmidt^*, K. Bräutigam, R. Wagner, L. Dietzel, Y. Schröter, S. Steiner and A. Nykytenko

Junior Research Group, Department for Plant Physiology, Friedrich-Schiller-University Jena, Dornburger Str. 159, 07743 Jena, Germany

^* For correspondence. E-mail Thomas.Pfannschmidt{at}uni-jena.de

Received: 29 January 2008 Returned for revision: 11 March 2008 Accepted: 21 April 2008 Published electronically: 20 May 2008

Background: Photosynthetic electron transport is performed by a chain ofredox components that are electrochemically connected in series.Its efficiency depends on the balanced action of the photosystemsand on the interaction with the dark reaction. Plants are sessileand cannot escape from environmental conditions such as fluctuatingillumination, limitation of CO₂ fixation by low temperatures,salinity, or low nutrient or water availability, which disturbthe homeostasis of the photosynthetic process. Photosyntheticorganisms, therefore, have developed various molecular acclimationmechanisms that maintain or restore photosynthetic efficiencyunder adverse conditions and counteract abiotic stresses. Recentstudies indicate that redox signals from photosynthetic electrontransport and reactive oxygen species (ROS) or ROS-scavengingmolecules play a central role in the regulation of acclimationand stress responses.

Scope: The underlying signalling network of photosynthetic redox controlis largely unknown, but it is already apparent that gene regulationby redox signals is of major importance for plants. Signallingcascades controlling the expression of chloroplast and nucleargenes have been identified and dissection of the different pathwaysis advancing. Because of the direction of information flow,photosynthetic redox signals can be defined as a distinct classof retrograde signals in addition to signals from organellargene expression or pigment biosynthesis. They represent a vitalsignal of mature chloroplasts that report their present functionalstate to the nucleus. Here we describe possible problems inthe elucidation of redox signalling networks and discuss someaspects of plant cell biology that are important for developingsuitable experimental approaches.

Conclusions: The photosynthetic function of chloroplasts represents an importantsensor that integrates various abiotic changes in the environmentinto corresponding molecular signals, which, in turn, regulatecellular activities to counterbalance the environmental changesor stresses.

Key words: Photosynthesis, redox signals, gene expression, regulatory network, retrograde signalling, cross-talk, plastids, higher plants

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