Research status and Development trend of Plant Electrical signals at Home and abroad

AUTHORS

Peipei Zhu,College of Electricity and Information,Heilongjiang Bayi Agricultural university,Daqing 163319,Heilongjian,China
Fangming Tian,College of Electricity and Information,Heilongjiang Bayi Agricultural university,Daqing 163319,Heilongjian,China
Huan Li,College of Electricity and Information,Heilongjiang Bayi Agricultural university,Daqing 163319,Heilongjian,China
Feng Tan,College of Electricity and Information,Heilongjiang Bayi Agricultural university,Daqing 163319,Heilongjian,China

ABSTRACT

The present situation and future development trend of plant electrical signal at home and abroad are reviewed in this paper. The measurement technology, production mechanism and characteristics of the plant electrical signal and the change characteristics of the plant electricity under the external stimulation are briefly summarized. The basic characteristics of the plant electrical signal are: low frequency (<5 Hz), weak (μV), random non-stationary time-varying signal. breaking the password between the electric signal and the physiological state of the plant, which can lay a theoretical foundation for preventing and controlling the disease and the insect pest of the plant according to the electric signal of the plant, and can be used for producing the plant electrical signal in the near future, Life and related scientific research services provide some help.

 

KEYWORDS

plant electrical signal; time-varying signal; measurement technique

REFERENCES

[1]    Zhao D J,Wang Z Y,Li J,et al. Recording extracellular signals in plants:a modeling and experimental study[J]. Mathematical & Computer Modelling,013,58(3-4):556-563. (in Chinese)
[2]    Zhao D J, wang Z Y, li J, et al. Research on key issues of extracellular measurement of plant electrical signals based on model and experiment [J].(2010),(s1): 137-146. (in Chinese)
[3]    Xue L, Zhao D J, Wang Z Y, et al. The calibration model in potassium ion flux non-invasive measurement of plants in vivo in situ[J].(2016), 3(2): 76-82. (in Chinese)
[4]    Li T, Wang Z Y, Zhao D J, et al. Development of a portable multi-channel system for plant physiological signal recording[J].(2016), 3(2): 124-132(in Chinese)
[5]    Guo J, Zhao B G, Liu Y F, et al. Transmission of electric waves in plants [J]. Journal of nanjing forestry university,(2000),24(3):71-76. (in Chinese)
[6]    Julien J L,Desbiez M O,Jaegher G DE.Characheristics of the wave of depolarization induced by wounding in Bidens polosa L[J]. J Exp Bot,(1991),234:131-137.
[7]    Brenner E D, Stahlberg R, Mancuso S, et al. Plant neurobiology: an integrated view of plant signaling[J]. (2006), 11(8): 413-419.
[8]    Lu J X, Ding W M, li l, et al. Research status of plant electrical signal analysis technology [J]. Anhui agricultural science,(2009),37(30):14583-14584. (in Chinese)
[9]    Lou C H. Root-crown relationship in higher plants [J]. Life sciences,(1994),6(5):1-6. (in Chinese)
[10]  Zhao Z C. research on weak electrical signals of plants [J]. Journal of China institute of metrology,(2002),13(3):253-257. (in Chinese)
[11]  Zebelo S A, Maffei M E. Signal transduction in plant–insect Interactions: From Membrane Potential Variations to Metabolomics[M]. (2012): 143-172.
[12]  Matthias R Z, Heiko M, Axel M F, et al. System potentials, a novel electrical long-distance apoplastic signal in plants, induced by wounding[J].(2010), 149(8): 1593-1600.
[13]  Gurovich L a J C I C. Electrophysiology of Woody Plants[J]. (2012).
[14]  Mwesigwa J,Collins D,Volkov A G..Electrochemical signaling in green plants:effects of 2,4-dinitrophenol on variation and action potentials in soybean [J]. Bioelectrochemistry,(2000), 51: 201-205.
[15]  Sakamoto M,Sumiya K.The bioelectrical potentials of young woody plants[J].Wood research,(1984),70:42-46.
[16]  Paszewski A,Zawadzki T.Action potentials in lupinus angustifolius shoots 3 Determination of the refractory periods[J].J Exp Bot,(1976),27:369-374.
[17]  Pickard B G.Action potential in higher plants[J].Bot REV,(1973),39:172-201.
[18]  Paszewski A,Zawadzki T.Action potentials in lupinus angustifolius shoots[J].J Exp Bot,(1973),24:804-809.
[19]  Guo J Y, Yang X L. research progress of electrical signals in higher plants [J]. Chinese agricultural science bulletin,(2005),21(10):188-191. (in Chinese)
[20]  Chen Y G, Li Y G. pest control of garden plants [M]. Beijing: chemical industry press,(2012). (in Chinese)
[21]  LEVITT J.Responses of plants to Environmental Stress [M] .New York :Academic,(1980).
[22]  Su C B, Jing C G, Bai J R. experimental method and device for observation of albiflora earthquake [J]. Shanxi earthquake,(1999)(7): 7-10. (in Chinese)
[23]  Greenham C, Müller K J a J O B S. Conductance Changes and Responses in Potato Tubers Following Inf'ection with Various Sthains of Phytophthora and with Pythium[J], (1956), 9(2): 199-212.
[24]  Caruso F, Tattar T, Mount M. Changes in electrical restance in the carly stages of Fusarium wilt of tomato[C]. Proc. Am. Phytopathol. Soc, (1974).
[25]  Zhou X M, Wang X C, Leng Q . study on plant electric wave transmission using aphid proboscis puncture technique [J]. Plant physiology communications,(1997),33(3): 202-204. (in Chinese)
[26]  SHIINA T , T AZAWA M .Action potential in Luffa cylindrica and its effects on elongation growth [J] .Plantand Cell Physiol, (1986), 27:1081-1089.
[27]  Hua B G, Yang W D, Li X Y. electrochemical wave transfer and protoplasmic contraction in rapid tendril bending of loofah [J]. Chinese science bulletin,(1995),40(15):1501-1503. (in Chinese)
[28]  Gil P M, Gurovich L, Schaffer B, et al. Root to leaf electrical signaling in avocado in response to light and soil water content.[J]. Journal of Plant Physiology, (2008), 165(10):1070-1078.
[29]  Gil P M, Saavedra J, Schaffer B, et al. Quantifying effects of irrigation and soil water content on electrical potentials in grapevines (Vitis vinifera ) using multivariate statistical methods[J]. Scientia Horticulturae, (2014), 173(3):71-78.
[30]  Vladimir Sukhov. Electrical signals as mechanism of photosynthesis regulation in plants[J]. (2016),373–387.
[31]  Joanna M. Nassar, Sherjeel M. Khan, Diego Rosas Villalva, et al. Compliant plant wearables for localized microclimate and plant growth monitoring[J].(2018),2:24.
[32]  Howink A L.The conduction of Excitation in Mimosa pudica[J].RecTrav Bot-Neel,(1935),32:51- 91.
[33]  Guo J, Zhao B G, Liu Y F, et al. Radio transmission in healthy black pine seedlings [J]. Journal of nanjing forestry university,(2000),24(3):77-80. (in Chinese)
[34]  Zhao B G, Guo J, Zhang Y Q, et al. Changes of electric wave transmission in black pine seedlings inoculated with pine wood nematode [J]. Journal of nanjing forestry university, (2000),24(3): 81-83. (in Chinese)
[35]  Guo J, Zhao B G, Liu Y F. electric wave transmission in plants [J]. Journal of nanjing forestry university, (2000),24(3): 71-76. (in Chinese)
[36]  ZAWADZKI T , DAVIES E, DZIUBINSKA H, et a1.Characteristic of action potentials in Helianthus annuus [J] .Physiological Plantarum, (1991), 83:601-604.
[37]  Volkov A G, Haack R A. Insect-induces biolectrochemical signals in potato plants [J] .Bioele-ctrochem ,Bioenerg ,(1995), 35:55-60.
[38]  STANKOVIC B, DAVIES E.Wounding evokes rapid changes in tissue deformation, electrical potential, tran-scription, and translation in tomato[ J] .Plant and Cell Phy siology ,(1997), 39:268-274.
[39]  STANKOVIC B,ZAWADZKI T,DAVIES E.Character-ization of the variation potential in sunflower[J] .Plant Phy siology ,(1997),115:1083-1088.
[40]  FAV RE P, G REPPIN H, AGOSTI R D.Repetitive action potentials induced in Arabidopsis thaliana leaves by wounding and potassium chloride application[J] .Plant Physiol Biochem, (2001), 39:961-969.
[41]  SHVEHSOV A T , MWESIGW A J, VOLKOV A G .Plant electrophysiology :FCCP induces action potentials and excitation waves in soybean[ J] .Plant Science , (2001),161:901-909.
[42]  SAKAMO TO M ,SUMIYA K .The bioelectrical potentials of young woody plants[ J] .Wood research , (1984), 70:42-46.
[43]  KOPPAN A ,SZA RKA L , WESZTERGOM V.Annual fluctuation in amplitudes of daily variations of electrical signals measured in the trunk of a standing tree[ J] .Life Sciences, (2000), 323:559-563.
[44]  Pyatygin S, Opritov V, Vodeneev V. Signaling role of action potential in higher plants[J].(2008), 55(2): 285-291.
[45]  Mousavi SA, Chauvin A, Pascaud F, et al. GLUTAMATE RECEPTOR-LIKE genes mediate leaf-to-leaf wound signalling[J]. Nature, (2013), 500(7463):422-6.

CITATION

  • APA:
    Zhu,P.& Tian,F.& Li,H.& Tan,F.(2019). Research status and Development trend of Plant Electrical signals at Home and abroad. International Journal of Bio-Science and Bio-Technology, 11(1), 1-10. 10.21742/IJBSBT.2019.11.1.01
  • Harvard:
    Zhu,P., Tian,F., Li,H., Tan,F.(2019). "Research status and Development trend of Plant Electrical signals at Home and abroad". International Journal of Bio-Science and Bio-Technology, 11(1), pp.1-10. doi:10.21742/IJBSBT.2019.11.1.01
  • IEEE:
    [1] P.Zhu, F.Tian, H.Li, F.Tan, "Research status and Development trend of Plant Electrical signals at Home and abroad". International Journal of Bio-Science and Bio-Technology, vol.11, no.1, pp.1-10, Jun. 2019
  • MLA:
    Zhu Peipei, Tian Fangming, Li Huan and Tan Feng. "Research status and Development trend of Plant Electrical signals at Home and abroad". International Journal of Bio-Science and Bio-Technology, vol.11, no.1, Jun. 2019, pp.1-10, doi:10.21742/IJBSBT.2019.11.1.01

ISSUE INFO

  • Volume 11, No. 1, 2019
  • ISSN(p):2233-7849
  • ISSN(e):2208-9810
  • Published:Jun. 2019

DOWNLOAD