| تعداد نشریات | 286 |
| تعداد نشریات سازمان | 84 |
| تعداد شمارهها | 2,998 |
| تعداد مقالات | 33,576 |
| تعداد مشاهده مقاله | 44,209,964 |
| تعداد دریافت فایل اصل مقاله | 20,562,784 |
بررسی الگوی بیان ژنهای دفاعی برنج تیمار شده با نانوذره نقره بیولوژیک در تعامل با Magnaporthe oryzae، قارچ عامل بیماری بلاست | ||
| مهار زیستی در گیاهپزشکی | ||
| دوره 8، شماره 2 - شماره پیاپی 16، اسفند 1399، صفحه 49-70 اصل مقاله (575.99 K) | ||
| نوع مقاله: مقاله پژوهشی | ||
| شناسه دیجیتال (DOI): 10.22092/bcpp.2021.125077 | ||
| نویسندگان | ||
| سمیه نظری* 1؛ حسین علائی2؛ ولی اله بابایی زاد3؛ علی مومنی4 | ||
| 1دانشگاه ولی عصر (عج) رفسنجان | ||
| 2دانشگاه ولی عصر (عج) رفسنجان، رفسنجان، کرمان | ||
| 3دانشگاه علوم کشاورزی و منابع طبیعی ساری، ساری، مازندران | ||
| 4موسسه تحقیقات برنج کشور، معاونت مازندران، آمل | ||
| چکیده | ||
| بلاست از مهمترین و مخربترین بیماریهای برنج در دنیا میباشد. نانوذرات عوامل ضدمیکروبی هستند که بهصورت محرکهای زیستی و غیرزیستی مورد استفاده قرار گرفته و میتوانند موجب القای مقاومت در گیاه در برابر عوامل بیمارگر شوند. تأثیرات نانو ذرات بیولوژیک و غیربیولوژیک مختلف در بازدارندگی بیمارگرهای قارچی مختلف گیاهان از جمله قارچ عامل بیماری بلاست به اثبات رسیده است. اما در مورد تاثیر نانوذره بیولوژیک بر کنترل این بیماری از طریق القاء مقاومت و بیان ژنهای دفاعی مطالعهای صورت نگرفته است. در این مطالعه، علاوه بر تأثیر مستقیم نانوذره نقره بیولوژیک سنتز شده از قارچ Trichoderma harzianum در شرایط آزمایشگاه، تأثیر غیرمستقیم آن از طریق القای مقاومت سیستمیک در رقم حساس طارم محلی بر قارچ بیمارگرMagnaporthe oryzae در شرایط گلخانه بررسی شد. بدین منظور، بیان چند ژن مهم دفاعی در گیاه تیمارشده با نانوذره بیولوژیک در مقایسه با گیاهان شاهد (تیمار فاقد نانوذره نقره بیولوژیک) در زمانهای مختلف پس از تلقیح با بیمارگر با روش Real–time qPCR مورد بررسی قرارگرفت. نتایج بررسی مستقیم حاکی از تأثیر مثبت غلظتهای مختلف نانوذره بیولوژیک در کاهش رشد بیمارگر در مقایسه با تیمار شاهد بود، به طوریکه میزان بازدارندگی از رشد بیمارگر در غلظتهای 5/4، 9، 18، 27 و 36 میکروگرم در میلیلیتر در مقایسه با تیمار شاهد به ترتیب 7، 28، 56، 81 و 92 درصد بود. بررسی فنوتیپی برهمکنش گیاه برنج و قارچ عامل بیماری بلاست در حضور نانوذره بیولوژیک نشان داد که اختلاف معنیداری بین شدت بیماری در گیاهان تیمار شده با نانوذره بیولوژیک در مقایسه با گیاهان شاهد وجود ندارد. همچنین تجمع ترانوشت ژنهای NPR1، PR2، PR3 وLOX بین دو تیمار مذکور، افزایش قابل ملاحظه و معنیداری را نشان نداد. بنابراین، تأثیر غیرمستقیم نانوذره نقره بیولوژیک سنتز شده بر بیمارگر از طریق القاء مقاومت و افزایش بیان ژنهای دفاعی گیاه برنج قابل توجه نمیباشد. | ||
| کلیدواژهها | ||
| القاگر؛ بیمارگر؛ ژنهای PR؛ مقاومت القایی؛ نیترات نقره؛ تریکودرما | ||
| عنوان مقاله [English] | ||
| Investigation of the expression pattern of defense-related genes in rice plants treated with biological silver nanoparticles and Magnaporthe oryzae, the fungus causing blast disease | ||
| نویسندگان [English] | ||
| somayeh nazari1؛ Hossein Alaei2؛ Valiollah Babaeizad3؛ Ali Momeni4 | ||
| 2Vali-e-Asr University of Rafsanjan, Rafsanjan, Kerman, Iran | ||
| 3Sari Agricultural Sciences and Natural Resources University, Sari, Mazandaran, Iran | ||
| 4Rice Research Institute of Iran, Mazandaran Branch, Agricultural Research, Education and Extension Organization, Mazandaran, Amol, Iran | ||
| چکیده [English] | ||
| Blast is one of the most important and destructive rice diseases in the world. Nanoparticles are antimicrobial agents used as biological and non–biological stimulants and can induce resistance in plant against pathogens. Effects of different biological and non–biological nanoparticles on inhibition of various plant fungal pathogens has been proved. However, no study has been done about the effect of biological nanoparticles on control of this disease through induction of resistance and expression of defense genes. In this study, in addition to direct effect of biological silver nanoparticles synthesized using Trichoderma harzianum fungus in vitro, its indirect effect was investigated by inducing systemic resistance in susceptible local Tarom cultivar on pathogenic fungus Magnaporthe oryzae under greenhouse conditions. For this purpose, expression of several important defense genes investigated in biological silver nanoparticle–treated plants in comparison with control plant (without biological silver nanoparticle) using real–time qPCR technique at different times after pathogen inoculation. The results showed a positive effect of different concentrations of biological nanoparticles in reduction of pathogen growth in comparison with the control treatment so that the amount of inhibition of pathogen growth in different concentrations (36, 27, 18, 9, 4.5 ppm) was 92, 81, 56, 28 and 7 percent compared to the control treatment, respectively. Phenotypic study of rice plant interaction with the fungus causing blast disease in presence of biological nanoparticle showed that there was no significant difference between the disease severities in biological nanoparticle–treated plants compared to control plants. Also, accumulation of transcripts of NPR1, PR2, PR3 and LOX genes between two mentioned treatments did not show significant increase. Therefore, indirect effect of biological silver nanoparticle on pathogenic fungus by induced resistance and increasing the rice plant defense genes is not considerable. | ||
| کلیدواژهها [English] | ||
| induced resistance, inducer, pathogen, PR genes, silver nitrate, Trichoderma | ||
| مراجع | ||
|
Abdelmalek, G.A.M. & Salaheldin, T.A. 2016. Silver Nanoparticles as a Potent Fungicide for Citrus Phytopathogenic Fungi. Journal of Nanomedicine Research, 3: 1–8. Agrios, G.N. 2005. Plant pathology. Elsevier Academic Press Burlington, MA. Akram, A., Ongena, M., Duby, F., Dommes, J. & Thonart, P. 2008. Systemic resistance and lipoxygenase–related defence response induced in tomato by Pseudomonas putida strain BTP1. BMC Plant Biology, 8: 1–12. Akter, R. 2019. Efficacy of silver nanoparticles against rice blast disease and farmers perception about its management in Bangladesh. Agroecology Master’s Programme, 63 pp. Al Abboud, M.A. 2018. Fungal biosynthesis of silver nanoparticles and their role in control of Fusarium wilt of sweet pepper and soil–borne fungi in vitro. International Journal of Pharmacology, 14: 773–780. Ali, S.M., Yousef, N.M.H. & Nafady, N.A. 2015. Application of Biosynthesized Silver nanoparticles for the control of land snail Eobania vermiculata and some plant pathogenic fung. Journal of Nanomaterials, 2015: 1–10. Anusuya, S. & Sathiyabama, M. 2015. β–d–Glucan nanoparticle pre–treatment induce resistance against Pythium aphanidermatum infection in turmeric. International Journal of Biological Macromolecules, 74: 278–282. Cao, H., Li, X. & Dong, X. 1998. Generation of broad–spectrum disease resistance by overexpression of an essential regulatory gene in systemic acquired resistance. Proceeding of the National Academy of Sciences USA, 95: 6531–6536. Chern, M–S., Fitzgerald, H.A., Canlas, P.E., Navarre, D.A. & Ronald, P.C. 2005. Overexpression of a rice NPR1 homolog leads to constitutive activation of defense response and hypersensitivity to light. Molecular Plant–Microbe Interaction, 18: 511–20. Chern, M–S., Fitzgerald, H.A., Yadav, R.C., Canlas, PE., Dong, X. & Ronald, P.C. 2001. Evidence for a disease–resistance pathway in rice similar to the NPR1–mediated signaling pathway in Arabidopsis. The Plant Journal, 27: 101–113. Colling, D.B., Kragh, K.M., Mikkelsen, J.D., Nielsen, K.K., Rasmussen, U. & Vad, K. 1993. Plant chitinases. The Plant Journal, 3: 31–40. Devi, P., Sakkaravarthi, K., Kamil, D., Borah, J.L., Narayansamy, P. & Chowluru, S.N. 2013. Biosynthesis of silver nanoparticles from Trichoderma species. Indian Journal of Experimental Biology, 51: 543–547. Dong, X. 1998. SA, JA, ethylene, and disease resistance in plants. Current Opinion in Plant Biology, 1: 316–323. Edreva, A. 2005. Pathogenesis–related proteins: Research progress in the last 15 years. General and Applied Plant Physiology, 31: 105–124. Elamawi, R.M., Al–Harbi, R.E. & Hendi, A.A. 2018. Biosynthesis and characterization of silver nanoparticles using Trichoderma longibrachiatum and their effect on phytopathogenic fungi. Egyptian Journal of Biological Pest Control, 28: 1271–1283. Elamawi, R.M.A. & El–Shafey, R.A.S. 2013. Inhibition effects of silver nanoparticles against rice blast disease caused by Magnaporthe grisea. Egyptian Journal of Agricultural Research, 91: 1271–1283. El–Eraky, A.M., Moubasher, A.H., Ismail, M.A., El–Shaer, A.H. & Gouda, H.A. 2017. Mycosynthesis of silver nanoparticles and their role in the control of Fusarium wilt of pepper. Journal of Basic & Applied Mycology (Egypt), 8: 25–34. Elgorban, A.M., Aref, S.M., Seham, S.M., Elhindi, K.M., Bahkali, A.H., Sayed, S.R. & Manal, M.A. 2016. Extracellular synthesis of silver nanoparticles using Aspergillus versicolor and evaluation of their activity on plant pathogenic fungi. Mycosphere, 7: 844–852. Feng, J–X., Cao, L., Li, J., Duan, C–J., Luo, X.M., Le, N., Wei, H., Liang, S., Chu, Ch., Pan, Q. & Tang, J–L. 2011 Involvement of OsNPR1/NH1 in rice basal resistance to blast fungus Magnaporthe oryzae. European Journal of Plant Patholology, 131: 1–16. Filippi, M.C., Silva, G.B., Silva–Lobo, V.L., Viana, H.F. & Prabhu, A.S. 2014. Induction of resistance to rice leaf blast by avirulent isolates of Magnaporthe oryzae. Amazonian Journal of Agricultural and Environmental Science, 57: 388–395. Fitzgerald, H.A., Chern, M.S., Navarre, R. & Ronald, P.C. 2004. Overexpression of (At) NPR1 in rice leads to a BTH– and environmented–induced lesion–mimic/cell death phenotype. Molecular Plant Microbe Interaction, 17: 140–151. Friedrich, L., Lawton, K., Dietrich, R., Willits, M., Cade, R. & Ryals, J. 2001. NIM1 overexpression in Arabidopsis potentiates plant disease resistance and results in enhanced effectiveness of fungicides. Molecular Plant Microbe Interaction, 14: 1114–1124. Golshani, F., Fakheri, B.A., Behshad, E. & Mohammadpour Vashvaei, R. 2015. PRs proteins and their Mechanism in Plants. Biological Forum – An International Journal, 7: 477–495. Grover, A. & Gowthaman, R. 2003. Strategies for development of fungus–resistant transgenic plants. Current Science, 84: 330–340. Guilger–Casagrande, M., Pasquoto–Stigliani, T., Bilesky–Jose, N., Grillo, R., Abhilash, P.C., Fraceto, L.F., & Lima, R.D. 2017. Biogenic silver nanoparticles based on Trichoderma harzianum: synthesis, characterization, toxicity evaluation and biological activity. Scientific Reports, 7: 1–13. Hao, Z.N., Wang, L.P. & Tao, R.X. 2009. Expression patterns of defence genes and antioxidant defence responses in a rice variety that is resistant to leaf blast but susceptible to neck blast. Physiological and Molecular Plant Pathology, 74: 167–174. Harman, G.E., Howell, C.R., Viterbo, A., Chet, I. & Lorito, M. 2004. Trichoderma species—opportunistic, avirulent plant symbionts. Nature reviews microbiology, 2: 43–56. Heydari–Nezhad, A.M., Babaeizad, V. & Rahimian H. 2015. Studying PR2 and PAL genes involvement in rice resistance against Acidovorax avenae subsp. Avenae. Agricultural Biotechnology Journal, 7(4): 67–82. (In Persian with English summary). Howard, R.J. & Valent, B. 1996. Breaking and entering: host penetration by the fungal rice blast pathogen Magnaporthe grisea. Annual Reviews in Microbiology, 50: 491–512. Imada, K., Sakai, S., Kajihara, H., Tanaka, S. & Ito, S. 2016. Magnesium oxide nanoparticles induce systemic resistance in tomato against bacterial wilt disease. Plant Pathology, 65: 551–560. IRRI. 2013. Standard Evaluation System for Rice. International Rice Research Institute, P.O. Box 933, 1099 Manila, Philippines, 1–55. Jain, N., Vergish, S. & Khurana, J.P. 2018. Validation of house–keeping genes for normalization of gene expression data during diurnal/ circadian studies in rice by RT–qPCR. Scientific Reports, 8: 1–14. Jo, Y–K., Kim, B.H. & Jung, G. 2009. Antifungal activity of silver ions and nanoparticles on phytopathogenic fungi. Plant Disease, 93: 1037–1043. Jwa, N–S., Agrawal, G.K., Tamogami, S., Yonekura, M., Han, O., Iwahashi, H. & Rakwal, R. 2006. Role of defense/stress–related marker genes, proteins and secondary metabolites in defining rice self–defense mechanisms. Plant Physiology and Biochemistry, 44: 261–273. Kanmani, N. 2018. Biosynthesis of silver nanoparticles and their evaluation of antifungal activity against Magnaporthe oryzae. Journal of Pharmacognosy and Phytochemistry, 7: 1638–1648. Khosravi, V. 2006. Identification of new races of Magnaporthe grisea, the causal agent of rice blast disease in Mzandaran. Final Report of Research Project. Iranian Rice Research Institute Publication, 27 pp. Kim, J.S., Kuk, E., Yu, K.N. & Kim, J.H. 2007. Antimicrobial effects of silver nanoparticles. Nanomedicine: Nanotechnology, Biology, and Medicine, 3: 95–101. Kim, S.T., Kim, S.G., Hwang, D.H., Kang, S.Y., Kim, H.J., Lee, B.H., Lee, J.J. & Kang, K.Y. 2004. Proteomic analysis of pathogen–responsive proteins from rice leaves induced by rice blast fungus, Magnaporthe grisea. Proteomics, 4 3569–3578. Kim, S.W., Jung, J.H., Lamsal, K., Kim, W.S., Min, J.S. & Lee, Y.S. 2012. Antifungal Effects of Silver Nanoparticles (AgNPs) against Various Plant Pathogenic Fungi. Mycobiology, 40: 53–58 Kim, S.W., Kim, K.S., Lamsal, K., Kim, Y–J., Kim, S.B., Jung, M., Sim, S.J., Kim, H.S., Chang, S–J., Kim, J.K. & Lee, Y.S. 2009. An in vitro study of the antifungal effect of silver nanoparticles on oak wilt pathogen Raffaelea sp. .Journal of Microbiology and Biotechnology, 19: 760–764. Li, Q., Chen, F., Sun, L., Zhang, Z., Yang, Y. & He, Z. 2006. Expression profiling of rice genes in early defense responses to blast and bacterial blight pathogens using cDNA microarray. Physiological and Molecular Plant Pathology, 68: 51–60. Lin, W., Anuratha, C., Datta, K., Potrykus, I., Muthukrishnan, S. & Datta, S.K. 1995. Genetic engineering of rice for resistance to sheath blight. Nature Biotechnology, 13: 686–691. Livak, K.J. & Schmittgen, T.D. 2001. Analysis of relative gene expression data using real–time quantitative PCR and the 2−ΔΔCT method. Methods, 25: 402–408. Mahdizadeh, V., Safaie, N. & Khelghatibana, F. 2015. Evaluation of antifungal activity of silver nanoparticles against some phytopathogenic fungi and Trichoderma harzianum. Journal of Crop Protection, 4: 291–300. Makandar, R., Essing, J.S., Schapaugh, M.A., Trick, H.N. & Shah, J. 2006. Genetically engineered resistance to Fusarium head blight in wheat by expression of Arabidopsis NPR1. Molecular Plant Microbe Interaction, 19: 123–129. Mandal, D., Bolander, M.E., Mukhopadhyay, D., Sarkar, G. & Mukherjee, P. 2006. The use of microorganisms for the formation of metal nanoparticles and their application. Applied Microbiology and Biotechnology, 69: 485–492. Mishra, S. & Singh, H. 2015. Biosynthesized silver nanoparticles as a nanoweapon against phytopathogens: exploring their scope and potential in agriculture. Applied Microbiology and Biotechnology, 99: 1097–1107. Mishra, S., Singh, B.R., Singh, A., Keswani, C., Naqvi, A.H. & Singh, H.B. 2014. Biofabricated Silver Nanoparticles Act as a Strong Fungicide against Bipolaris sorokiniana Causing Spot Blotch Disease in Wheat. PLOS ONE, 9: 1–11. Motalebi, A., Mahdian, S.A., Tajic Ghanbari, M.A., Ghasemi Mir, S. 2016. Comparision of the effects of silver nanoparticles synthesized by the fungus Trichoderma viride against the fungus Rhizoctonia solani of rice sheath blight and bacteria spot of rice striped Acidovorax avenae. 22nd Iranian plant protection congress, 27–30 AUG, Karaj, Iran, 340. (In Persian with English summary). Padasht Dehkaei, F. & Izadyar, M. 2007. Study on the biological control of rice blast disease in the field condition. J. Agric. Sci. Natur. Resource, 13: 1–9. Park, H–J., Kim, S.H., Kim, H.J. & Choi, S–H. 2006. A new composition of nanosized silica silver for control of various plant disease. Plant Pathology Journal, 22: 295–302. Pham, T.T., Nguyen, T.H., Thi, T.V., Nguyen, T–T., Le, T.D., Vo, D.M.H., Nguyen, D.H., Nguyen, C.K., Nguyen, D.C., Nguyen, T.T. & Bach, L.G. 2019. Investigation of chitosan nanoparticles loaded with protocatechuic acid (PCA) for the resistance of Pyricularia oryzae fungus against rice blast. Polymers, 11: 1–10. Pieterse, C.M.J. & Van Loon, L.C. 2004. NPR1: the spider in the web of induced resistance signaling pathways. Current Opinion in Plant Biology, 7:456–464. Pieterse, C.M.J., Zamioudis, C., Berendsen, R.L., Weller, D.M., Van Wees, S.C.M. & Bakker, P.A.H.M. 2014. Induced Systemic Resistance by Beneficial Microbes. Annual Review of Phytopathology, 52:347–75. Porta, H. & Rocha–Sosa, M. 2002. Plant Lipoxygenases. Physiological and Molecular Features. Plant Physiology, 130: 15–21. Reymond, P. & Farmer, E.E. 1998. Jasmonate and salicylate as global signals for defense gene expression. Current Opinion in Plant Biology, 1: 404–411. Quilis, J., Peñas, G., Messeguer, J., Brugidou, C. & Segundo, B.S. 2008. The Arabidopsis AtNPR1 Inversely Modulates Defense Responses Against Fungal, Bacterial, or Viral Pathogens While Conferring Hypersensitivity to Abiotic Stresses in Transgenic Rice. MPMI, 21: 1215–1231. Rai, M., Ingle, A.P., Gupta, I.R., Birla, S.S., Yadav, A.P. & Abd–Elsalam, K.A. 2013. Potential role of biological systems in formation of nanoparticles: mechanism of synthesis and biomedical applications. Current Nanoscience, 9: 576–587. Ribot, C., Hirsch, J., Batzergue, S., Tharreau, D., Notteghem, J.L., Lebrun, M–H. & Morel, J–B. 2008. Susceptibility of rice to the blast fungus Magnaporthe grisea. Journal of Plant Physiology, 165: 114–124. Rios, J.A., Rodrigues, F.A., Debona, D., Resende, R.S., Moreira, W.R. & Andrade, C.C.L. 2014. Induction of resistance to Pyricularia oryzae in wheat by acibenzolar–S–methyl, ethylene and jasmonic acid. Tropical Plant Pathology, 39: 224–233. Roy, S., Mukherjee, T., Chakraborty, S. & Kumar, T. 2013. Biosynthesis, characterization, and antifungal activity of silver nanoparticles synthesized by the fungu Aspergillus foetidus MTCC8876. Digest Journal of Nanomaterials and Biostructures, 8: 197–205. Saha, S., Sarkar, J., Chattopadhyay. D., Patra. S., Chakraborty, A. & Acharya, K. 2010. Production of silver nanoparticles by a phytopathogenic fungus Bipolaris nodulosa and its antimicrobial activity. Digest Journal of Nanomaterials and Biostructures, 5: 887–895. Sayari, M., Babaeizad, V., Tajick Ghanbari, M.A. & Rahimian, H. 2014. Expression of the pathogenesis related proteins, NH–1, PAL, and lipoxygenase in the iranian Tarom and Khazar rice cultivars, in reaction to Rhizoctonia solani–the causal agent of rice sheath blight. Journal of Plant Protection Research, 54: 36–43. Sena, A.P.A., Chaibub, A.A., Côrtes, M.V.C.B., Silva, G.B., Silva–Lobo, V.L., Prabhu, A.S., Filippi, M.C.C. & Araújo, L.G. 2013. Increased enzymatic activity in rice leaf blast suppression by crude extract of Epicoccum sp. Tropical plant pathology, 38: 1–17. Shelar, G.B. & Chavan, A.M. 2015. Myco–synthesis of silver nanoparticles from Trichoderma harzianum and its impact on germination status of oil seed. Biolife, 3:109–113. Singh, P., Singh, A., Singh, H. & Dhakad, B. 2012. Biological control of rice blast disease with Trichoderma harzianum in direct seeded rice under medium low land rainfed conditions. Environment and Ecology, 30: 834–837. Shoresh, M., Yedidia, I. & Chet, I. 2005. Involvement of jasmonic acid/ethylene Signaling pathway in the systemic resistance induced in cucumber by Trichoderma asperellum T203. Phythopathology, 95: 76–84. Soltani Nejad, M., Shahidi Bonjar, G.H., Khatami, M., Amini, A. & Aghighi, S. 2017. In vitro and in vivo antifungal properties of silver nanoparticles against Rhizoctonia solani, a common agent of rice sheath blight disease. IET Nanobiotechnology, 11: 236–240. Soltani, A. & Torabi, B. 2014. Design and analysis of agricultural experiments with the SAS program. Mashhad University Press, Iran. Song, F. & Goodman, R.M. 2001. Molecular biology of disease resistance in rice. Physiological and Molecular Plant Pathology, 59: 1–11. Song, J.J., Kanokmedhakul, S., Kanokmedhalkul, K. & Soytong, K. 2018. Application of nano–particles derived from Chaetomium elatum ChE01 to control Pyricularia oryzae causing rice blast. International Journal of Agricultural Technology, 14: 923–932. Song, J.J., Soytong, K., Kanokmedhakul, S., Kanokmedhakul, K. & Poeaim, S. 2020. Antifungal activity of microbial nanoparticles derived from Chaetomium spp. against Magnaporthe oryzae causing rice blast. Plant Protection Science, 56: 180–190. Sugano, S., Jiang, C.J., Miyazawa, S.I., Masumoto, C., Yazawa, K., Hayashi, N., Shimono, M., Nakayama, A., Miyao, M. & Takatsuji, H. 2010. Role of OsNPR1 in rice defense program as revealed by genome–wide expression analysis. Plant Molecular Biology, 74: 549–562. Syu, Y.Y., Hung, J.H., Chen, J.C. & Chuang, H.V. 2014. Impacts of size and shape of silver nanoparticles on Arabidopsis plant growth and gene expression. Plant Physiology and Biochemistry, 83: 57–64. Thakur, M. & Udayashankar, A.C. 2019. Lipoxygenases and Their Function in Plant Innate Mechanism. Bioactive Molecules in Plant Defense, 133–143. Tomah, A.A., Alamer, I.S.A., Li, B. & Zhang, J.Z. 2020. Mycosynthesis of Silver Nanoparticles Using Screened Trichoderma Isolates and Their Antifungal Activity against Sclerotinia sclerotiorum. Nanomaterials, 10: 1955. Vahabi, K. & Karimi Dorcheh, S. 2014. Biosynthesis of silver nano–particles by Trichoderma and its medical applications. Biotechnology and Biology of Trichoderma, 29: 393–404. Van Loon, L.C. & Van Strien, E.A. 1999. The families of pathogenesis–related proteins, their activities and comparative analysis of PR–1 type proteins. Physiological and Molecular Plant Pathology, 55: 85–97. Van Loon, L.C., Rep, M., Pieterse, C.M.J. 2006. Significance of inducible defense–related proteins in infected plants. Annual Review of Phytopathology, 44: 135–62. Vidhyasekaran, P. 2002. Bacterial disease resistance in plants: molecular biology and biotechnological applications, 452 Pp. The Haworth Press, Binghamton, NY. Wang, D., Weaver, N.D., Kesarwanti, M. & Dong, X. 2005. Induction of protein secretory pathway is required for systemic acquired resistance Science, 308: 1036–1040. Yuan, Y., Zhong, S., Li, Q., Zhu, Z., Lou, Y., Wang, L., Wang, J., Wang, M., Li, Q., Yang, D. & He, Z. 2007. Functional analysis of rice NPR1–like genes reveals that OsNPR1/NH1 is the rice orthologue conferring disease resistance with enhanced herbivore susceptibility. Plant Biotechnology Journal, 5: 313–324. Zare, F. 2017. Study of the ability of some Trichoderma strains in inducing resistance to control cucumber root rot. MSc. Thesis. Faculty of Agriculture, Vali–e–Asr University of Rafsanjan. (In Persian with English summary). | ||
|
آمار تعداد مشاهده مقاله: 479 تعداد دریافت فایل اصل مقاله: 458 |
||