The Impacts of Phosphorus Deficiency on the Photosynthetic Electron Transport Chain1[OPEN]
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S. Husted | C. Spetea | M. Pribil | S. B. Schmidt | A. Carstensen | Andrei Herdean | Anurag Sharma | Søren Husted
[1] D. Kramer,et al. NPQ(T) : a chlorophyll fluorescence parameter for rapid estimation and imaging of non-photochemical quenching of excitons in photosystem-II-associated antenna complexes. , 2017, Plant, cell & environment.
[2] D. Kramer,et al. The higher plant plastid NAD(P)H dehydrogenase-like complex (NDH) is a high efficiency proton pump that increases ATP production by cyclic electron flow , 2017, The Journal of Biological Chemistry.
[3] S. Allakhverdiev,et al. Variable chlorophyll fluorescence and its use for assessing physiological condition of plant photosynthetic apparatus , 2016, Russian Journal of Plant Physiology.
[4] E. Młodzińska,et al. Phosphate Uptake and Allocation – A Closer Look at Arabidopsis thaliana L. and Oryza sativa L. , 2016, Front. Plant Sci..
[5] A. Ruban. Nonphotochemical Chlorophyll Fluorescence Quenching: Mechanism and Effectiveness in Protecting Plants from Photodamage1 , 2016, Plant Physiology.
[6] G. Garab,et al. The Arabidopsis thylakoid transporter PHT4;1 influences phosphate availability for ATP synthesis and plant growth. , 2015, The Plant journal : for cell and molecular biology.
[7] Byoung Ryong Jeong,et al. Proteomic Analysis Provides New Insights in Phosphorus Homeostasis Subjected to Pi (Inorganic Phosphate) Starvation in Tomato Plants (Solanum lycopersicum L.) , 2015, PloS one.
[8] K. H. Laursen,et al. Sensitive Detection of Phosphorus Deficiency in Plants Using Chlorophyll a Fluorescence1 , 2015, Plant Physiology.
[9] C. Spetea,et al. The membrane proteome of stroma thylakoids from Arabidopsis thaliana studied by successive in-solution and in-gel digestion. , 2015, Physiologia plantarum.
[10] X. Zhang,et al. Changes in plant growth and photosynthetic performance of Zizania latifolia exposed to different phosphorus concentrations under hydroponic condition , 2015, Photosynthetica.
[11] S. Baldwin,et al. Replace, reuse, recycle: improving the sustainable use of phosphorus by plants. , 2015, Journal of experimental botany.
[12] Stuart White,et al. Tracking phosphorus security: indicators of phosphorus vulnerability in the global food system , 2015, Food Security.
[13] M. Höök,et al. Phosphate rock production and depletion : Regional disaggregated modeling and global implications , 2014 .
[14] A. N. Tikhonov,et al. The cytochrome b6f complex at the crossroad of photosynthetic electron transport pathways. , 2014, Plant physiology and biochemistry : PPB.
[15] Huan Chen,et al. Comparative Proteomic Analyses Provide New Insights into Low Phosphorus Stress Responses in Maize Leaves , 2014, PloS one.
[16] Govindjee,et al. Modeling chlorophyll a fluorescence transient: Relation to photosynthesis , 2014, Biochemistry (Moscow).
[17] D. Kramer,et al. Control of Non-Photochemical Exciton Quenching by the Proton Circuit of Photosynthesis , 2014 .
[18] Govindjee,et al. Non-Photochemical Quenching and Energy Dissipation in Plants, Algae and Cyanobacteria , 2014, Advances in Photosynthesis and Respiration.
[19] Alexander N. Tikhonov,et al. pH-Dependent regulation of electron transport and ATP synthesis in chloroplasts , 2013, Photosynthesis Research.
[20] S. Hotchandani,et al. Re-evaluation of the side effects of cytochrome b6f inhibitor dibromothymoquinone on photosystem II excitation and electron transfer , 2013, Photosynthesis Research.
[21] M. Hawkesford,et al. Mineral composition analysis: measuring anion uptake and anion concentrations in plant tissues. , 2013, Methods in molecular biology.
[22] Govindjee,et al. Chlorophyll a fluorescence induction: a personal perspective of the thermal phase, the J–I–P rise , 2012, Photosynthesis Research.
[23] Govindjee,et al. On the Relation between the Kautsky Effect (chlorophyll a Fluorescence Induction) and Photosystem Ii: Basics and Applications of the Ojip Fluorescence Transient Q , 2022 .
[24] A. Rubin,et al. Membrane potential is involved in regulation of photosynthetic reactions in the marine diatom Thalassiosira weissflogii. , 2011, Journal of photochemistry and photobiology. B, Biology.
[25] N. Ramankutty,et al. Agronomic phosphorus imbalances across the world's croplands , 2011, Proceedings of the National Academy of Sciences.
[26] D. Ort,et al. Measurement of chloroplast ATP synthesis activity in Arabidopsis. , 2011, Methods in molecular biology.
[27] M. Blair,et al. Strategies for improving phosphorus acquisition efficiency of crop plants. , 2010 .
[28] Natasha Gilbert,et al. Environment: The disappearing nutrient , 2009, Nature.
[29] Matthew P. Johnson,et al. The Photosystem II Light-Harvesting Protein Lhcb3 Affects the Macrostructure of Photosystem II and the Rate of State Transitions in Arabidopsis[W][OA] , 2009, The Plant Cell Online.
[30] D. Cordell,et al. The story of phosphorus: Global food security and food for thought , 2009 .
[31] Ian J. Wright,et al. Leaf phosphorus influences the photosynthesis–nitrogen relation: a cross-biome analysis of 314 species , 2009, Oecologia.
[32] B. Persson,et al. Arabidopsis ANTR1 Is a Thylakoid Na+-dependent Phosphate Transporter , 2008, Journal of Biological Chemistry.
[33] E. Blancaflor,et al. Functional analysis of the Arabidopsis PHT4 family of intracellular phosphate transporters. , 2008, The New phytologist.
[34] J. Hammond,et al. Sucrose Transport in the Phloem: Integrating Root Responses to Phosphorus Starvation Sensing and Signalling P Availability , 2022 .
[35] K. Takizawa,et al. Depletion of stromal P(i) induces high 'energy-dependent' antenna exciton quenching (q(E)) by decreasing proton conductivity at CF(O)-CF(1) ATP synthase. , 2008, Plant, cell & environment.
[36] K. Takizawa,et al. Depletion of stromal Pi induces high ‘energy‐dependent’ antenna exciton quenching (qE) by decreasing proton conductivity at CFO‐CF1 ATP synthase , 2007 .
[37] D. Leister,et al. The E subunit of photosystem I is not essential for linear electron flow and photoautotrophic growth in Arabidopsis thaliana , 2007, Planta.
[38] R. Strasser,et al. A non-invasive assay of the plastoquinone pool redox state based on the OJIP-transient , 2007, Photosynthesis Research.
[39] G. Queval,et al. A plate reader method for the measurement of NAD, NADP, glutathione, and ascorbate in tissue extracts: Application to redox profiling during Arabidopsis rosette development. , 2007, Analytical biochemistry.
[40] Alison M. Smith,et al. Quantification of starch in plant tissues , 2006, Nature Protocols.
[41] R. Strasser,et al. Methylviologen and dibromothymoquinone treatments of pea leaves reveal the role of photosystem I in the Chl a fluorescence rise OJIP. , 2005, Biochimica et biophysica acta.
[42] K. Takizawa,et al. Plasticity in light reactions of photosynthesis for energy production and photoprotection. , 2004, Journal of experimental botany.
[43] I. Rao,et al. 7 Role of Phosphorus in Photosynthetic Carbon Metabolism , 2005 .
[44] D. Leister,et al. Mutants for photosystem I subunit D of Arabidopsis thaliana: effects on photosynthesis, photosystem I stability and expression of nuclear genes for chloroplast functions. , 2004, The Plant journal : for cell and molecular biology.
[45] Govindjee,et al. Polyphasic rise of chlorophyll a fluorescence in herbicide-resistant D1 mutants of Chlamydomonas reinardtii , 1995, Photosynthesis Research.
[46] Wim J. Vredenberg,et al. System Analysis and Photoelectrochemical Control of Chlorophyll Fluorescence in Terms of Trapping Models of Photosystem II: A Challenging View , 2004 .
[47] L. Natr. Plant Analysis: An Interpretation Manual , 2004, Photosynthetica.
[48] K. Dietz,et al. Phosphate transport across biomembranes and cytosolic phosphate homeostasis in barley leaves , 2004, Planta.
[49] F. Franck,et al. Resolution of the Photosystem I and Photosystem II contributions to chlorophyll fluorescence of intact leaves at room temperature. , 2002, Biochimica et biophysica acta.
[50] C. Bowler,et al. Molecular plant biology : a practical approach , 2002 .
[51] K. Niyogi,et al. Non-photochemical quenching. A response to excess light energy. , 2001, Plant physiology.
[52] D. Kramer,et al. Contribution of electric field (Δψ) to steady-state transthylakoid proton motive force (pmf) in vitro and in vivo. Control of pmf parsing into Δψ and ΔpH by ionic strength , 2001 .
[53] H. Scheller,et al. The PSI-H subunit of photosystem I is essential for state transitions in plant photosynthesis , 2000, Nature.
[54] C. Boyer,et al. A cDNA Encoding Starch Branching Enzyme I from Maize Endosperm , 1995, Plant physiology.
[55] A. Fredeen,et al. Leaf Phosphate Status, Photosynthesis, and Carbon Partitioning in Sugar Beet (IV. Changes with Time Following Increased Supply of Phosphate to Low-Phosphate Plants) , 1995, Plant physiology.
[56] Govindjee,et al. The Fo and the O-J-I-P Fluorescence Rise in Higher Plants and Algae , 1992 .
[57] D. Randall,et al. Whole Leaf Carbon Exchange Characteristics of Phosphate Deficient Soybeans (Glycine max L.). , 1989, Plant physiology.
[58] T. Sharkey,et al. Stromal Phosphate Concentration Is Low during Feedback Limited Photosynthesis. , 1989, Plant physiology.
[59] R. J. Porra,et al. Determination of accurate extinction coefficients and simultaneous equations for assaying chlorophylls a and b extracted with four different solvents: verification of the concentration of chlorophyll standards by atomic absorption spectroscopy , 1989 .
[60] E. Schlodder,et al. pH dependence of oxygen evolution and reduction kinetics of photooxidized chlorophyll aII (P-680) in photosystem II particles from Synechococcus sp. , 1987 .
[61] C. Giersch,et al. Inorganic Phosphate Concentration in the Stroma of Isolated Chloroplasts and Its Influence on Photosynthesis , 1987 .
[62] J. Briantais,et al. A quantitative study of the slow decline of chlorophyll a fluorescence in isolated chloroplasts. , 1979, Biochimica et biophysica acta.
[63] U. Heber,et al. Role of orthophosphate and other factors in the regulation of starch formation in leaves and isolated chloroplasts. , 1977, Plant physiology.