Coordination of Cyclic Electron Flow and Water–Water Cycle Facilitates Photoprotection under Fluctuating Light and Temperature Stress in the Epiphytic Orchid Dendrobium officinale

Photosystem I (PSI) is the primary target of photoinhibition under fluctuating light (FL). Photosynthetic organisms employ alternative electron flows to protect PSI under FL. However, the understanding of the coordination of alternative electron flows under FL at temperature stresses is limited. To address this question, we measured the chlorophyll fluorescence, P700 redox state, and electrochromic shift signal in leaves of Dendrobium officinale exposed to FL at 42 °C, 25 °C, and 4 °C. Upon a sudden increase in illumination at 42 °C and 25 °C, the water–water cycle (WWC) consumed a significant fraction of the extra reducing power, and thus avoided an over-reduction of PSI. However, WWC was inactivated at 4 °C, leading to an over-reduction of PSI within the first seconds after light increased. Therefore, the role of WWC under FL is largely dependent on temperature conditions. After an abrupt increase in light intensity, cyclic electron flow (CEF) around PSI was stimulated at any temperature. Therefore, CEF and WWC showed different temperature responses under FL. Furthermore, the enhancement of CEF and WWC at 42 °C quickly generated a sufficient trans-thylakoid proton gradient (ΔpH). The inactivation of WWC at 4 °C was partially compensated for by an increased CEF activity. These findings indicate that CEF and WWC coordinate to protect PSI under FL at temperature stresses.

[1]  Wei Huang,et al.  The water-water cycle is not a major alternative sink in fluctuating light at chilling temperature. , 2021, Plant science : an international journal of experimental plant biology.

[2]  M. Brestič,et al.  Glycinebetaine mitigated the photoinhibition of photosystem II at high temperature in transgenic tomato plants , 2021, Photosynthesis Research.

[3]  Wei Huang,et al.  Photosystem I is tolerant to fluctuating light under moderate heat stress in two orchids Dendrobium officinale and Bletilla striata. , 2020, Plant science : an international journal of experimental plant biology.

[4]  Wei Huang,et al.  The water-water cycle facilitates photosynthetic regulation under fluctuating light in the epiphytic orchid Dendrobium officinale , 2020 .

[5]  O. Sytar,et al.  Chlorophyll-depleted wheat mutants are disturbed in photosynthetic electron flow regulation but can retain an acclimation ability to a fluctuating light regime , 2020 .

[6]  Wei Huang,et al.  The water-water cycle is more effective in regulating redox state of photosystem I under fluctuating light than cyclic electron transport. , 2020, Biochimica et biophysica acta. Bioenergetics.

[7]  M. Paunov,et al.  Special issue in honour of Prof. Reto J. Strasser - Photosynthetic efficiency of two Platanus orientalis L. ecotypes exposed to moderately high temperature - JIP-test analysis , 2020 .

[8]  Wei Huang,et al.  Moderate heat stress accelerates photoinhibition of photosystem I under fluctuating light in tobacco young leaves , 2020, Photosynthesis Research.

[9]  W. Weckwerth,et al.  Adjustment of photosynthetic activity to drought and fluctuating light in wheat , 2020, Plant, cell & environment.

[10]  Wei Huang,et al.  Responses of photosystem I compared with photosystem II to combination of heat stress and fluctuating light in tobacco leaves. , 2020, Plant science : an international journal of experimental plant biology.

[11]  I. Terashima,et al.  Increased stomatal conductance induces rapid changes to photosynthetic rate in response to naturally fluctuating light conditions in rice. , 2020, Plant, cell & environment.

[12]  T. Morosinotto,et al.  Regulation of electron transport is essential for photosystem I stability and plant growth , 2019, bioRxiv.

[13]  Ji‐Hua Wang,et al.  Photosynthetic regulation under fluctuating light in field-grown Cerasus cerasoides: A comparison of young and mature leaves. , 2019, Biochimica et biophysica acta. Bioenergetics.

[14]  Wei Huang,et al.  Stimulation of cyclic electron flow around photosystem I upon a sudden transition from low to high light in two angiosperms Arabidopsis thaliana and Bletilla striata. , 2019, Plant science : an international journal of experimental plant biology.

[15]  M. Brestič,et al.  Transient Heat Waves May Affect the Photosynthetic Capacity of Susceptible Wheat Genotypes Due to Insufficient Photosystem I Photoprotection , 2019, Plants.

[16]  Wei Huang,et al.  Photosynthetic regulation under fluctuating light in young and mature leaves of the CAM plant Bryophyllum pinnatum. , 2019, Biochimica et biophysica acta. Bioenergetics.

[17]  Wei Huang,et al.  The role of water-water cycle in regulating the redox state of photosystem I under fluctuating light. , 2019, Biochimica et biophysica acta. Bioenergetics.

[18]  Wei Huang,et al.  Photoinhibition of photosystem I under fluctuating light is linked to the insufficient ΔpH upon a sudden transition from low to high light , 2019, Environmental and Experimental Botany.

[19]  E. Aro,et al.  Consequences of photosystem‐I damage and repair on photosynthesis and carbon use in Arabidopsis thaliana , 2019, The Plant journal : for cell and molecular biology.

[20]  C. Miyake,et al.  What Quantity of Photosystem I Is Optimum for Safe Photosynthesis?1 , 2019, Plant Physiology.

[21]  T. Shikanai,et al.  PGR5-Dependent Cyclic Electron Flow Protects Photosystem I under Fluctuating Light at Donor and Acceptor Sides1 , 2018, Plant Physiology.

[22]  T. Morosinotto,et al.  Balancing protection and efficiency in the regulation of photosynthetic electron transport across plant evolution. , 2018, The New phytologist.

[23]  M. Brestič,et al.  Phenotyping of isogenic chlorophyll-less bread and durum wheat mutant lines in relation to photoprotection and photosynthetic capacity , 2018, Photosynthesis Research.

[24]  G. Peltier,et al.  Hunting the main player enabling Chlamydomonas reinhardtii growth under fluctuating light , 2018, The Plant journal : for cell and molecular biology.

[25]  M. Brestič,et al.  Altitude of origin influences the responses of PSII photochemistry to heat waves in European beech (Fagus sylvatica L.) , 2017 .

[26]  Rebecca A. Slattery,et al.  The Impacts of Fluctuating Light on Crop Performance1[OPEN] , 2017, Plant Physiology.

[27]  T. Demura,et al.  Chloroplastic ATP synthase builds up a proton motive force preventing production of reactive oxygen species in photosystem I , 2017, The Plant journal : for cell and molecular biology.

[28]  Ute Armbruster,et al.  The regulation of the chloroplast proton motive force plays a key role for photosynthesis in fluctuating light. , 2017, Current opinion in plant biology.

[29]  G. Peltier,et al.  Flavodiiron Proteins Promote Fast and Transient O2 Photoreduction in Chlamydomonas1[OPEN] , 2017, Plant Physiology.

[30]  C. Miyake,et al.  The Liverwort, Marchantia, Drives Alternative Electron Flow Using a Flavodiiron Protein to Protect PSI1[OPEN] , 2017, Plant Physiology.

[31]  T. Morosinotto,et al.  Flavodiiron proteins act as safety valve for electrons in Physcomitrella patens , 2016, Proceedings of the National Academy of Sciences.

[32]  I. Terashima,et al.  Elucidation of Photoprotective Mechanisms of PSI Against Fluctuating Light photoinhibition. , 2016, Plant & cell physiology.

[33]  M. Brestič,et al.  High temperature specifically affects the photoprotective responses of chlorophyll b-deficient wheat mutant lines , 2016, Photosynthesis Research.

[34]  S. Takumi,et al.  Superoxide and Singlet Oxygen Produced within the Thylakoid Membranes Both Cause Photosystem I Photoinhibition1[OPEN] , 2016, Plant Physiology.

[35]  M. Badger,et al.  Artificial remodelling of alternative electron flow by flavodiiron proteins in Arabidopsis , 2016, Nature Plants.

[36]  T. Shikanai,et al.  A physiological role of cyclic electron transport around photosystem I in sustaining photosynthesis under fluctuating light in rice , 2016, Scientific Reports.

[37]  T. Shikanai,et al.  Role of cyclic electron transport around photosystem I in regulating proton motive force. , 2015, Biochimica et biophysica acta.

[38]  M. Suorsa,et al.  Photoprotection of photosystems in fluctuating light intensities. , 2015, Journal of experimental botany.

[39]  O. Sytar,et al.  Repetitive light pulse-induced photoinhibition of photosystem I severely affects CO2 assimilation and photoprotection in wheat leaves , 2015, Photosynthesis Research.

[40]  O. Sytar,et al.  Low PSI content limits the photoprotection of PSI and PSII in early growth stages of chlorophyll b-deficient wheat mutant lines , 2015, Photosynthesis Research.

[41]  J. Serôdio,et al.  Frequently asked questions about in vivo chlorophyll fluorescence: practical issues , 2014, Photosynthesis Research.

[42]  H. Fukayama,et al.  Repetitive short-pulse light mainly inactivates photosystem I in sunflower leaves. , 2014, Plant & cell physiology.

[43]  K. Noguchi,et al.  Roles of the cyclic electron flow around PSI (CEF-PSI) and O₂-dependent alternative pathways in regulation of the photosynthetic electron flow in short-term fluctuating light in Arabidopsis thaliana. , 2014, Plant & cell physiology.

[44]  David M Kramer,et al.  The Response of Cyclic Electron Flow around Photosystem I to Changes in Photorespiration and Nitrate Assimilation1[W][OPEN] , 2014, Plant Physiology.

[45]  K. Siebke,et al.  Continuous ECS-indicated recording of the proton-motive charge flux in leaves , 2013, Photosynthesis Research.

[46]  E. Aro,et al.  Flavodiiron proteins Flv1 and Flv3 enable cyanobacterial growth and photosynthesis under fluctuating light , 2013, Proceedings of the National Academy of Sciences.

[47]  V. Paakkarinen,et al.  PROTON GRADIENT REGULATION5 Is Essential for Proper Acclimation of Arabidopsis Photosystem I to Naturally and Artificially Fluctuating Light Conditions[W] , 2012, Plant Cell.

[48]  P. Joliot,et al.  Regulation of cyclic and linear electron flow in higher plants , 2011, Proceedings of the National Academy of Sciences.

[49]  C. Miyake Alternative electron flows (water-water cycle and cyclic electron flow around PSI) in photosynthesis: molecular mechanisms and physiological functions. , 2010, Plant & cell physiology.

[50]  Wei Huang,et al.  The different effects of chilling stress under moderate light intensity on photosystem II compared with photosystem I and subsequent recovery in tropical tree species , 2010, Photosynthesis Research.

[51]  T. Sharkey,et al.  Moderate heat stress reduces the pH component of the transthylakoid proton motive force in light-adapted, intact tobacco leaves. , 2009, Plant, cell & environment.

[52]  Hui-yuan Gao,et al.  Heterogeneous behavior of PSII in soybean (Glycine max) leaves with identical PSII photochemistry efficiency under different high temperature treatments. , 2009, Journal of plant physiology.

[53]  D. Kramer,et al.  Regulating the proton budget of higher plant photosynthesis. , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[54]  Congming Lu,et al.  Heat stress induces a reversible inhibition of electron transport at the acceptor side of photosystem II in a cyanobacterium , 2005 .

[55]  H. Scheller,et al.  Photoinhibition of photosystem I at chilling temperature and subsequent recovery in Arabidopsis thaliana. , 2004, Plant & cell physiology.

[56]  S. Allakhverdiev,et al.  Environmental stress inhibits the synthesis de novo of proteins involved in the photodamage-repair cycle of Photosystem II in Synechocystis sp. PCC 6803. , 2004, Biochimica et biophysica acta.

[57]  David M. Kramer,et al.  New Fluorescence Parameters for the Determination of QA Redox State and Excitation Energy Fluxes , 2004, Photosynthesis Research.

[58]  K. Sonoike,et al.  Irreversible damage to photosystem I by chilling in the light: cause of the degradation of chlorophyll after returning to normal growth temperature , 2002, Planta.

[59]  D. Kramer,et al.  The proton to electron stoichiometry of steady-state photosynthesis in living plants: A proton-pumping Q cycle is continuously engaged. , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[60]  K. Asada,et al.  THE WATER-WATER CYCLE IN CHLOROPLASTS: Scavenging of Active Oxygens and Dissipation of Excess Photons. , 1999, Annual review of plant physiology and plant molecular biology.

[61]  K. Noguchi,et al.  The cause of PSI photoinhibition at low temperatures in leaves of Cucumis sativus, a chilling-sensitive plant , 1998 .

[62]  K. Sonoike Selective photoinhibition of photosystem I in isolated thylakoid membranes from cucumber and spinach , 1995 .

[63]  Wei Huang,et al.  Photosystem I photoinhibition induced by fluctuating light depends on background low light irradiance , 2021 .

[64]  U. Schreiber,et al.  Non-photochemical fluorescence quenching and quantum yields in PS I and PS II: Analysis of heat-induced limitations using Maxi-Imaging- PAM and Dual-PAM-100 , 2008 .

[65]  U. Heber,et al.  Heat sensitivity of chloroplasts and leaves: Leakage of protons from thylakoids and reversible activation of cyclic electron transport , 1999, Photosynthesis Research.