The Effect of Laser Irradiation on The Activity of The Bacteria Bacillus Subtilis And Pseudomonas Fluorescens
Keywords:
Laser irradiation Bacillus subtilis, Pseudomonas fluorescens, bacteria stimulation, biological monitoring of plant diseases
Abstract
The paper discusses the problem of increasing the activity of phytopathogen-antagonistic bacteria under the effect of laser irradiation. It has been shown that short-term treatment of cells of Bacillus subtilis and Pseudomonas fluorescens with coherent light can increase bacterial growth rate and improve their fungicidal activity. It ensures high efficiency of environmentally safe measures for biological monitoring of plant diseases, which is in line with the principles of organic farming.
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References
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Sindhu, S.S., Sehrawat, A., Sharma, R., Dahiya, A. (2016). Biopesticides: use of rhizosphere bacteria for biological control of plant pathogens. Defence Life Science Journal, 1(2), 135-148.
Singh, U.B. Malviya, D., Wasiullah, Singh, S., Pradhan, J.K., Singh, B.P., Roy, M., Imram, M., Pathak, N., Baisyal, B.M., Rai, J.P., Sarma, B.K., Singh, R.K., Sharma, P.K., Kaur, S.D., Manna, M.C., Sharma, S.K., Sharma, A.K. (2016). Bio-protective microbial agents from rhizosphere eco-systems trigger plant defense responses provide protection against sheath blight disease in rice (Oryza sativa L). Microbiological research, 192, 300-312.
Suman, B. (2018). Cultural and Morphological Characterization of Native Pseudomonas fluorescens Isolates from Telangana. Int. J. Pure App. Biosci, 6(4), 592-597.
Syamala, M., Sivaji, M. (2017). Functional characterization of various plant growth promoting activity of Pseudomonas fluorescens and Bacillus subtilis from Aloe vera rhizosphere. Journal of Pharmacognosy and Phytochemistry, 6(3), 120-122.
Yasmin, S., Zaka, A., Imran, A., Zahid, M.A., Yousaf, S., Rasul, G., Arif, M., Mirza, M.S. (2016). Plant growth promotion and suppression of bacterial leaf blight in rice by inoculated bacteria. PloS one, 11(8).
Horuz, S., Aysan, Y. (2018). Biological control of watermelon seedling blight caused by acidovorax citrulliusing antagonistic bacteria from the genera Curtobacterium, Microbacterium and Pseudomonas. Plant Protect. Sci., 54(3), 138-146.
Huang, X., Zhang, N., Yong, X., Yang, X., Shen, Q. (2012). Biocontrol of Rhizoctonia solani damping-off disease in cucumber with Bacillus pumilus SQR-N43. Microbiological Research, 167(3), 135-143.
Kanjanamaneesathian, M., Meetum, P. (2018). Paenibacillus polymyxa as potential biological control agent isolated from vegetables grown hydroponically in Thailand. Kasem Bundit Engineering Journal, 8, 14-24.
Kiprushkina, E.I., Baranenko, D.A., Kolodyaznaya, V.S. (2017). A comparative study of fuel use and income analysis of potato production with bacteria-antagonists in Leningrad region of Russia. Energy Procedia, 113, 194-200.
Mohammadi, P., Tozlu, E., KoTan, R., KoTan, M. (2017). Potential of some bacteria for biological control of postharvest citrus green mould caused by Penicillium digitatum. Plant Protect. Sci., 53(3), 134-143.
Morgera, E., Caro, C.B., Durán, G.M. (2012). Organic agriculture and the law. Food and agriculture organization of the united nations. Rome.
Nikolaeva, M.A., Kalugina, S.A., Kartashova, L.V. (2016). Analiz rossiiskogo rynka organicheskikh produktov pitaniya [Analysis of the Russian market of organic food]. Siberian Trade and Economic Journal, 1(22), 226 – 230.
Novikov, I.I. (2017). Mikrobiologicheskaya zashchita rastenii - osnova fitosanitarnoi optimizatsii agroekosistem [Microbiological protection of plants is basis of phytosanitary optimization of agroecosystems]. Protection and quarantine of plants, 4, 3 – 6.
Pal, K.K., Gardener, B.M.S. (2006). Biological control of plant pathogens. The plant health instructor, 2, 1117-1142.
Petrovsky, A.S., Karakotov, S.D. (2017). Mikrobiologicheskie preparaty v rastenievodstve. Alternativa ili partnerstvo? [Microbiological preparations in crop production. Alternative or partnership?]. Plants protection and quarantine, 2, 14 – 18.
Rahmawati, H.K., Purnomo, A.J., Umniyatie, S., Pramiadi, D., Sari, N. (2016). Identification and characterization of chitinase enzyme producing bacteria from bat guano and its potential to inhibit the growth of fungus Colletotrichum sp. cause anthracnose on the chili by in vitro. Int J Adv Agricultural & Environmental Engg, 3, 249-254.
Shternis, M.V. (2012). Tendentsii razvitiya biotekhnologii mikrobnykh sredstv zashchity rastenii v Rossii [Trends in the development of microbial plant protection biotechnology in Russia ]. Vestnik of the Tomsk State University. Biology, 2(18), 92 – 100.
Sindhu, S.S., Sehrawat, A., Sharma, R., Dahiya, A. (2016). Biopesticides: use of rhizosphere bacteria for biological control of plant pathogens. Defence Life Science Journal, 1(2), 135-148.
Singh, U.B. Malviya, D., Wasiullah, Singh, S., Pradhan, J.K., Singh, B.P., Roy, M., Imram, M., Pathak, N., Baisyal, B.M., Rai, J.P., Sarma, B.K., Singh, R.K., Sharma, P.K., Kaur, S.D., Manna, M.C., Sharma, S.K., Sharma, A.K. (2016). Bio-protective microbial agents from rhizosphere eco-systems trigger plant defense responses provide protection against sheath blight disease in rice (Oryza sativa L). Microbiological research, 192, 300-312.
Suman, B. (2018). Cultural and Morphological Characterization of Native Pseudomonas fluorescens Isolates from Telangana. Int. J. Pure App. Biosci, 6(4), 592-597.
Syamala, M., Sivaji, M. (2017). Functional characterization of various plant growth promoting activity of Pseudomonas fluorescens and Bacillus subtilis from Aloe vera rhizosphere. Journal of Pharmacognosy and Phytochemistry, 6(3), 120-122.
Yasmin, S., Zaka, A., Imran, A., Zahid, M.A., Yousaf, S., Rasul, G., Arif, M., Mirza, M.S. (2016). Plant growth promotion and suppression of bacterial leaf blight in rice by inoculated bacteria. PloS one, 11(8).
Published
2019-08-31
How to Cite
Maslova, M., Grosheva, E., Budagovsky, A., & Budagovskaya, O. (2019). The Effect of Laser Irradiation on The Activity of The Bacteria Bacillus Subtilis And Pseudomonas Fluorescens. Amazonia Investiga, 8(21), 610-616. Retrieved from https://www.amazoniainvestiga.info/index.php/amazonia/article/view/146
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