Electrical signals as an option of communication with plants: a review
暂无分享,去创建一个
Luis Miguel Contreras-Medina | Miguel Ángel García-Servín | Magdalena Mendoza-Sánchez | L. M. Contreras-Medina | Magdalena Mendoza-Sánchez | Miguel A. Garcia-Servin | Magdalena Mendoza-Sánchez
[1] Patrick Favre,et al. Voltage-dependent action potentials in Arabidopsis thaliana. , 2007, Physiologia plantarum.
[2] Halina Dziubinska,et al. Ways of signal transmission and physiological role of electrical potentials in plants , 2011 .
[3] E. Jovanov,et al. Anisotropy and nonlinear properties of electrochemical circuits in leaves of Aloe vera L. , 2011, Bioelectrochemistry.
[4] Lyubov Katicheva,et al. Proton cellular influx as a probable mechanism of variation potential influence on photosynthesis in pea. , 2014, Plant, cell & environment.
[5] J. Pickett,et al. How rapid is aphid-induced signal transfer between plants via common mycelial networks? , 2013, Communicative & integrative biology.
[6] M. Roelfsema,et al. Action potential in Chara cells intensifies spatial patterns of photosynthetic electron flow and non-photochemical quenching in parallel with inhibition of pH banding , 2008, Photochemical & photobiological sciences : Official journal of the European Photochemistry Association and the European Society for Photobiology.
[7] Rainer Matyssek,et al. Characteristics of Electrical Signals in Poplar and Responses in Photosynthesis1 , 2005, Plant Physiology.
[8] D. R. Pereira,et al. Electrome alterations in a plant-pathogen system: Toward early diagnosis. , 2020, Bioelectrochemistry.
[9] Gustavo M. Souza,et al. Plant electrome: the electrical dimension of plant life , 2019, Theoretical and Experimental Plant Physiology.
[10] V. G. Retivin,et al. Generation of action potential induces preadaptation of Cucurbita pepo L. stem tissues to freezing injury , 1997 .
[11] V. Sukhov,et al. The role of Ca2+, H+, and Cl− ions in generation of variation potential in pumpkin plants , 2011, Russian Journal of Plant Physiology.
[12] R. Guevara-González,et al. Influence of Elicitors and Eustressors on the Production of Plant Secondary Metabolites , 2019, Natural Bio-active Compounds.
[13] Yong Li,et al. SPAD-based leaf nitrogen estimation is impacted by environmental factors and crop leaf characteristics , 2015, Scientific Reports.
[14] The effects of Ni2+ on electrical signaling of Nitellopsis obtusa cells , 2016, Journal of Plant Research.
[15] Vilma Kisnieriene,et al. Charophyte electrogenesis as a biomarker for assessing the risk from low-dose ionizing radiation to a single plant cell. , 2014, Journal of environmental radioactivity.
[16] D. K. R. Babajee. On the Kung-Traub Conjecture for Iterative Methods for Solving Quadratic Equations , 2016, Algorithms.
[17] V. Sukhov,et al. Spatial and Temporal Dynamics of Electrical and Photosynthetic Activity and the Content of Phytohormones Induced by Local Stimulation of Pea Plants , 2020, Plants.
[18] J. Fromm,et al. Electrical signals and their physiological significance in plants. , 2007, Plant, cell & environment.
[19] M. Farag,et al. Sub‐lethal Levels of Electric Current Elicit the Biosynthesis of Plant Secondary Metabolites , 2008, Biotechnology progress.
[20] Transport processes in stimulated and non-stimulated leaves of Mimosa pudica , 1988, Trees.
[21] M. Filek,et al. The effect of wounding the roots by high temperature on the respiration rate of the shoot and propagation of electric signal in horse bean seedlings (Vicia faba L. minor) , 1997 .
[22] J. Fromm,et al. Electrical signaling and gas exchange in maize plants of drying soil , 1998 .
[23] J. Fisahn,et al. Analysis of the transient increase in cytosolic Ca2+ during the action potential of higher plants with high temporal resolution: requirement of Ca2+ transients for induction of jasmonic acid biosynthesis and PINII gene expression. , 2004, Plant & cell physiology.
[24] Hubert H. Felle,et al. Systemic signalling in barley through action potentials , 2007, Planta.
[25] C. Ulrichs,et al. Effects of intermittent-direct-electric-current (IDC) on polyphenols and antioxidant activity in radish (Raphanus sativus L.) during growth. , 2009 .
[26] V. Sukhov,et al. Evaluation of the open time of calcium channels at variation potential generation in wheat leaf cells , 2015, Plant signaling & behavior.
[27] Jörg Fromm,et al. Action potentials in maize sieve tubes change phloem translocation , 1994 .
[28] P. Minchin,et al. Electrical signalling and systemic proteinase inhibitor induction in the wounded plant , 1992, Nature.
[29] M. Hajirezaei,et al. Electrical signaling along the phloem and its physiological responses in the maize leaf , 2013, Front. Plant Sci..
[30] Ondřej Novák,et al. Electrical and chemical signals involved in short-term systemic photosynthetic responses of tobacco plants to local burning , 2006, Planta.
[31] Bratislav Stankovic,et al. Action potentials and variation potentials in sunflower: An analysis of their relationships and distinguishing characteristics , 1998 .
[32] R. Evert,et al. Transmission of Electric Signals in Sieve Tubes of Zucchini Plants , 1988 .
[33] N. Yu,et al. Changes in the power spectrum of electrical signals in maize leaf induced by osmotic stress , 2012 .
[34] Vilma Kisnieriene,et al. Electrical signalling in Nitellopsis obtusa: potential biomarkers of biologically active compounds. , 2018, Functional plant biology : FPB.
[35] V. Sukhov,et al. Ionic nature of burn-induced variation potential in wheat leaves. , 2014, Plant & cell physiology.
[36] Tadeusz Zawadzki,et al. Transmission route for action potentials and variation potentials in Helianthus annuus L. , 2001 .
[37] Chhaya,et al. An overview of recent advancement in phytohormones-mediated stress management and drought tolerance in crop plants , 2021 .
[38] J. Reinitz,et al. Dynamic filtration of the expression pattern variability of Drosophila zygotic segmentation genes , 2008 .
[39] H. Felle,et al. Dissection of heat-induced systemic signals: superiority of ion fluxes to voltage changes in substomatal cavities , 2009, Planta.
[40] Zhongyi Wang,et al. High-resolution non-contact measurement of the electrical activity of plants in situ using optical recording , 2015, Scientific Reports.
[41] J. Fromm,et al. Effect of simultaneously induced environmental stimuli on electrical signalling and gas exchange in maize plants. , 2018, Journal of plant physiology.
[42] Ekaterina Sukhova,et al. Long-distance electrical signals as a link between the local action of stressors and the systemic physiological responses in higher plants. , 2019, Progress in biophysics and molecular biology.
[43] Jörg Fromm,et al. Characteristics of Action Potentials in Willow (Salix viminalis L.) , 1993 .
[44] V. Sukhov,et al. Simulation of action potential propagation in plants. , 2011, Journal of theoretical biology.
[45] B. Pickard,et al. Properties of action potentials in Drosera tentacles , 1972, Planta.
[46] V. Sukhov,et al. The mechanism of propagation of variation potentials in wheat leaves. , 2012, Journal of plant physiology.
[47] Luis Miguel Contreras-Medina,et al. A Review of Methods for Sensing the Nitrogen Status in Plants: Advantages, Disadvantages and Recent Advances , 2013, Sensors.
[48] R. Ward. THE INFLUENCE OF ELECTRIC CURRENTS ON THE GROWTH OF TOMATO PLANTS , 1996 .
[49] V. Sukhov,et al. Burning-induced electrical signals influence broadband reflectance indices and water index in pea leaves , 2020, Plant signaling & behavior.
[50] E. Farmer,et al. GLUTAMATE RECEPTOR-LIKE genes mediate leaf-to-leaf wound signalling , 2013, Nature.
[51] R. Agosti. Touch-induced action potentials in Arabidopsis thaliana , 2014 .
[52] V. Sukhov. Electrical signals as mechanism of photosynthesis regulation in plants , 2016, Photosynthesis Research.
[53] R. Matyssek,et al. Involvement of respiratory processes in the transient knockout of net CO2 uptake in Mimosa pudica upon heat stimulation. , 2014, Plant, cell & environment.
[54] S. Müller,et al. Effect of a Single Excitation Stimulus on Photosynthetic Activity and Light-dependent pH Banding in Chara Cells , 2004, The Journal of Membrane Biology.
[55] J. Fisahn,et al. Localized Wounding by Heat Initiates the Accumulation of Proteinase Inhibitor II in Abscisic Acid-Deficient Plants by Triggering Jasmonic Acid Biosynthesis , 1996, Plant physiology.
[56] D. Bowles,et al. Defense-related proteins in higher plants. , 1990, Annual review of biochemistry.
[57] B. Cerabolini,et al. Seed germination and conservation of endangered species from the Italian Alps: Physoplexis comosa and Primula glaucescens , 2004 .
[58] Vladimir Sukhov,et al. Variation potential in higher plants: Mechanisms of generation and propagation , 2015, Plant signaling & behavior.
[59] Jun Ding,et al. Comprehensive Profiling of Phytohormones in Honey by Sequential Liquid-Liquid Extraction Coupled with Liquid Chromatography-Mass Spectrometry. , 2017, Journal of agricultural and food chemistry.
[60] J. Flexas,et al. Photosynthetic responses of soybean (Glycine max L.) to heat-induced electrical signalling are predominantly governed by modifications of mesophyll conductance for CO(2). , 2013, Plant, cell & environment.
[61] A. Sievers,et al. Action Potentials Evoked by Light in Traps of Dionaea muscipula Ellis , 1998 .
[62] Eric Davies,et al. Intercellular communication in plants: electrical stimulation of proteinase inhibitor gene expression in tomato , 1997, Planta.
[63] C. Müller,et al. Multivariate characterization of spontaneously generated electrical signals evoked by electrical stimulation in abscisic acid mutant tomato plants , 2021 .
[64] M. Friedel,et al. Performance of reflectance indices and of a handheld device for estimating in‐field the nitrogen status of grapevine leaves , 2020, Australian Journal of Grape and Wine Research.
[65] Lyubov Katicheva,et al. Simulation of Variation Potential in Higher Plant Cells , 2013, The Journal of Membrane Biology.
[66] S. Sopory,et al. Electrical signal from root to shoot in Sorghum bicolor: induction of leaf opening and evidence for fast extracellular propagation. , 2001, Plant science : an international journal of experimental plant biology.
[67] Stanisław Karpiński,et al. Electrical Signaling, Photosynthesis and Systemic Acquired Acclimation , 2017, Front. Physiol..
[68] Andrea Vitaletti,et al. Comparison of Decision Tree Based Classification Strategies to Detect External Chemical Stimuli from Raw and Filtered Plant Electrical Response , 2017, ArXiv.
[69] Jörg Fromm,et al. Transport processes in stimulated and non-stimulated leaves of Mimosa pudica , 1988, Trees.
[70] F. Baluška,et al. Anaesthetics stop diverse plant organ movements, affect endocytic vesicle recycling and ROS homeostasis, and block action potentials in Venus flytraps , 2017, Annals of botany.
[71] V. A. Opritov,et al. Analysis of Possible Involvement of Local Bioelectric Responses in Chilling Perception by Higher Plants Exemplified by Cucurbita pepo , 2005, Russian Journal of Plant Physiology.
[72] J. Fisahn,et al. Proteinase Inhibitor II Gene Expression Induced by Electrical Stimulation and Control of Photosynthetic Activity in Tomato Plants , 1995 .
[73] M. Hajirezaei,et al. The Biochemical Response of Electrical Signaling in the Reproductive System of Hibiscus Plants , 1995, Plant physiology.
[74] A. S. Ferreira,et al. Osmotic stress decreases complexity underlying the electrophysiological dynamic in soybean. , 2017, Plant biology.
[75] K. Ljung,et al. Plant Hormonomics: Multiple Phytohormone Profiling by Targeted Metabolomics1[OPEN] , 2018, Plant Physiology.
[76] Maqshoof Ahmad,et al. Role of Phytohormones in Stress Tolerance of Plants , 2016 .
[77] V. Sukhov,et al. Influence of propagating electrical signals on delayed luminescence in pelargonium leaves: Experimental analysis , 2008 .
[78] Emil Jovanov,et al. Kinetics and Mechanism of Dionaea muscipula Trap Closing1[C][OA] , 2007, Plant Physiology.
[79] A. Volkov,et al. Electrostimulation of Aloe Vera L., Mimosa Pudica L. and Arabidopsis Thaliana: Propagation and Collision of Electrotonic Potentials , 2013 .
[80] Ondřej Novák,et al. The role of electrical and jasmonate signalling in the recognition of captured prey in the carnivorous sundew plant Drosera capensis. , 2017, The New phytologist.
[81] F. R. Forsyth,et al. Electrical stimulation and its effects on growth and ion accumulation in tomato plants , 1971 .
[82] Nicolas Tremblay,et al. Opportunities for improved fertilizer nitrogen management in production of arable crops in eastern Canada: A review , 2009 .
[83] Di Li,et al. CORRIGENDUM: The work mechanism and sub-bandgap-voltage electroluminescence in inverted quantum dot light-emitting diodes , 2015, Scientific Reports.
[84] A. Hashem,et al. Phytohormones and Beneficial Microbes: Essential Components for Plants to Balance Stress and Fitness , 2017, Front. Microbiol..
[85] T. Takamura,et al. Growth Acceleration of Bean Sprouts by the Application of Electrochemical Voltage in a Culturing Bath , 1994 .
[86] João Paulo Papa,et al. Automatic classification of plant electrophysiological responses to environmental stimuli using machine learning and interval arithmetic , 2018, Comput. Electron. Agric..
[87] Electrically induced changes in amaranth seed enzymatic activity and their effect on bioactive compounds content after germination , 2018, Journal of Food Science and Technology.
[88] A. Meyer,et al. Growth, membrane potential and endogenous ion currents of willow (Salix viminalis) roots are all affected by abscisic acid and spermine , 1997 .
[89] Nobuhiro Suzuki,et al. ROS, Calcium, and Electric Signals: Key Mediators of Rapid Systemic Signaling in Plants1[OPEN] , 2016, Plant Physiology.
[90] A. Bulychev,et al. Inactivation of plasmalemma conductance in alkaline zones of Chara corallina after generation of action potential , 2010, Biochemistry (Moscow) Supplement Series A: Membrane and Cell Biology.
[91] V. Sukhov,et al. Mathematical model of action potential in higher plants with account for the involvement of vacuole in the electrical signal generation , 2017, Biochemistry (Moscow), Supplement Series A: Membrane and Cell Biology.
[92] V. Sukhov,et al. Participation of intracellular and extracellular pH changes in photosynthetic response development induced by variation potential in pumpkin seedlings , 2015, Biochemistry (Moscow).
[93] V. Sukhov,et al. Application of a mathematical model of variation potential for analysis of its influence on photosynthesis in higher plants , 2016, Biochemistry (Moscow) Supplement Series A: Membrane and Cell Biology.
[94] Hubert H. Felle,et al. System Potentials, a Novel Electrical Long-Distance Apoplastic Signal in Plants, Induced by Wounding1 , 2009, Plant Physiology.
[95] B. Pickard,et al. Receptor potentials and action potentials in Drosera tentacles , 1972, Planta.
[96] Silke Lautner,et al. Environmental stimuli and physiological responses: The current view on electrical signalling , 2015 .
[97] L. Rustioni,et al. Drought increases chlorophyll content in stems of Vitis interspecific hybrids , 2021, Theoretical and Experimental Plant Physiology.
[98] Andrea Vitaletti,et al. Exploring strategies for classification of external stimuli using statistical features of the plant electrical response , 2015, Journal of The Royal Society Interface.
[99] V. Sukhov,et al. The electrical signal-induced systemic photosynthetic response is accompanied by changes in the photochemical reflectance index in pea. , 2019, Functional plant biology : FPB.
[100] R. Nakamura,et al. Induction by Electric Currents of Ethylene Biosynthesis in Cucumber (Cucumis sativus L.) Fruit. , 1991, Plant physiology.
[101] V. Vodeneev,et al. Reversible changes of extracellular pH during action potential generation in a higher plant Cucurbita pepo , 2006, Russian Journal of Plant Physiology.
[102] S. Mancuso,et al. Stem electrical properties associated with water stress conditions in olive tree , 2020, Agricultural Water Management.
[103] Y. Shtessel,et al. Electrotonic signal transduction between Aloe vera plants using underground pathways in soil: Experimental and analytical study , 2017 .
[104] V. Shepherd,et al. Mechano-perception in Chara cells: the influence of salinity and calcium on touch-activated receptor potentials, action potentials and ion transport. , 2008, Plant, cell & environment.
[105] A. Jagendorf,et al. Signals involved in wound-induced proteinase inhibitor II gene expression in tomato and potato plants. , 1995, Proceedings of the National Academy of Sciences of the United States of America.
[106] Qiao Zhou,et al. Using a one-dimensional convolutional neural network with a conditional generative adversarial network to classify plant electrical signals , 2020, Comput. Electron. Agric..
[107] J. D. Rhodes,et al. Evidence for Physically Distinct Systemic Signalling Pathways in the Wounded Tomato Plant , 1999 .
[108] A. Bulychev,et al. Light-Triggered Action Potentials and Changes in Quantum Efficiency of Photosystem II in Anthoceros Cells , 2005, Russian Journal of Plant Physiology.
[109] É. Badel,et al. Stem bending generates electrical response in poplar , 2020, bioRxiv.
[110] T. Sibaoka,et al. Rapid plant movements triggered by action potentials , 1991, The botanical magazine = Shokubutsu-gaku-zasshi.
[111] B. Stanković,et al. Both action potentials and variation potentials induce proteinase inhibitor gene expression in tomato , 1996, FEBS letters.
[112] P. Hedden. A novel gibberellin promotes seedling establishment , 2019, Nature Plants.
[113] V. Sukhov,et al. Analysis of the photosynthetic response induced by variation potential in geranium , 2011, Planta.
[114] Analysis of Correlations between the Indexes of Light-Dependent Reactions of Photosynthesis and the Photochemical Reflectance Index (PRI) in Pea Leaves under Short-Term Illumination , 2019, Biochemistry (Moscow), Supplement Series A: Membrane and Cell Biology.
[115] V. Sukhov,et al. Influence of electrical signals on pea leaf reflectance in the 400–800-nm range , 2019, Plant signaling & behavior.
[116] V. Sukhov,et al. Influence of the variation potential on photosynthetic flows of light energy and electrons in pea , 2018, Photosynthesis Research.
[117] A. Mithöfer,et al. Herbivore-Triggered Electrophysiological Reactions: Candidates for Systemic Signals in Higher Plants and the Challenge of Their Identification1 , 2016, Plant Physiology.
[118] Jörg Fromm,et al. Transport processes in stimulated and non-stimulated leaves of Mimosa pudica , 1988, Trees.
[119] E. Król,et al. Electrical Signals in Long-Distance Communication in Plants , 2006 .
[120] A. San Bautista,et al. Effect of different levels of nitrogen in nutrient solution and crop system on nitrate accumulation in endive , 2017 .
[121] Lan Huang,et al. Development of a portable multi-channel system for plant physiological signal recording , 2016 .
[122] Lan Huang,et al. Plant Electrical Signal Classification Based on Waveform Similarity , 2016, Algorithms.
[123] A. Volkov,et al. Insect-induced biolectrochemical signals in potato plants , 1995 .
[124] Vladimir Sukhov,et al. Mathematical Models of Electrical Activity in Plants , 2017, The Journal of Membrane Biology.
[125] A. Volkov,et al. Electrical signal transmission in the plant-wide web. , 2019, Bioelectrochemistry.
[126] A. Bulychev,et al. Action potential in a plant cell lowers the light requirement for non-photochemical energy-dependent quenching of chlorophyll fluorescence. , 2007, Biochimica et biophysica acta.
[127] O. Novák,et al. Triggering a false alarm: wounding mimics prey capture in the carnivorous Venus flytrap (Dionaea muscipula). , 2017, The New phytologist.
[128] J. Schultz,et al. Rapid Changes in Tree Leaf Chemistry Induced by Damage: Evidence for Communication Between Plants , 1983, Science.
[129] Vladimir Sukhov,et al. Influence of variation potential on resistance of the photosynthetic machinery to heating in pea. , 2014, Physiologia plantarum.
[130] Rainer Hedrich,et al. Venus Flytrap: How an Excitable, Carnivorous Plant Works. , 2018, Trends in plant science.
[131] H. Dziubinska,et al. Effects of ion channel inhibitors on cold- and electrically-induced action potentials in Dionaea muscipula , 2006, Biologia Plantarum.
[132] J. Majada,et al. Hormonal profiling: Development of a simple method to extract and quantify phytohormones in complex matrices by UHPLC-MS/MS. , 2017, Journal of chromatography. B, Analytical technologies in the biomedical and life sciences.