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کارایی قارچ کش بیولوژیک حاصل از جدایه های جهش یافته تریکودرما درکنترل بیماری پوسیدگی ذغالی سویا | ||
| آفات و بیماری های گیاهی | ||
| مقاله 6، دوره 87، شماره 2 - شماره پیاپی 109، اسفند 1398، صفحه 209-226 اصل مقاله (1.08 M) | ||
| نوع مقاله: مدیریت آفات و بیماریهای گیاهی | ||
| شناسه دیجیتال (DOI): 10.22092/jaep.2019.127133.1294 | ||
| نویسندگان | ||
| فرهاد گوهرزاد1؛ محمد علی تاجبک قنبری* 2؛ سمیرا شهبازی3 | ||
| 1گروه گیاهپزشکی-دانشکده علوم زراعی-دانشگاه علوم کشاورزی و منابع طبیعی ساری-ایران | ||
| 2گروه گیاهپزشکی، دانشکده علوم زراعی، دانشگاه علوم کشاورزی و منابع طبیعی ساری، ایران | ||
| 3پژوهشکده کشاورزی هسته ای، پژوهشگاه علوم و فنون هسته ای، سازمان انرژی اتمی ایران، کرج | ||
| چکیده | ||
| پوسیدگی ذغالی، مهمترین بیماری قارچی سویا در کشور است. با توجه به نبود ارقام مقاوم، خاکبرد بودن و دامنه بیماریزایی وسیع Macrophomina phaseolina ، کنترل شیمیایی و زراعی، به تنهایی موفق نیستند. برای ارتقای کارایی کنترل بیولوژیک بیماری در سویا، از گونه والد Trichoderma koningii NAS-K1 و جدایه جهشیافته منتخب NAS-K1M25، در شرایط گلخانه استفاده شد. القای جهش، موجب افزایش کارایی کنترل بیولوژیکی بیماری شد. کارایی بیوفرمولاسیونهای پودر، گرانول و پوشش بذر، تهیه شده از این جدایهها، بهطور جداگانه ارزیابی شد. بیوفرمولاسیون پودر، بهترین نتیجه را در کاهش بیماری، بیوفرمولاسیون گرانول، بیشترین تأثیر را در افزایش رشد و عملکرد گیاه و بیوفرمولاسیون پوشش بذر، بهترین نتیجه را در بهبود خصوصیات جوانهزنی و شاخص ویگور داشت. با استفاده از این بیوفرمولاسیونها، شاخصهای رشد سویا نسبت به نمونه شاهد و تیمار سم شیمیایی، افزایش نشان داد. بیشترین افزایش عملکرد در حضور بیمارگر، با استفاده از تیمار بیوفرمولاسیون پوشش بذر با جدایه جهشیافته منتخب مشاهده شد. بررسی میزان زندهمانی ماده بیولوژیک در بیوفرمولاسیونهای پودر و گرانول، نشان داد که این شاخص تا مدت 11 ماه در دمای اتاق، کاهش ناچیزی داشته و همچنان مؤثر است اما نگهداری در دمای 4 درجه سلسیوس تأثیر مثبت در فعال ماندن ماده بیولوژیک دارد. | ||
| کلیدواژهها | ||
| القای جهش؛ پوسیدگی ذغالی؛ تریکودرما؛ سویا؛ قارچکش بیولوژیک | ||
| عنوان مقاله [English] | ||
| Efficiency of biological fungicide prepared from mutant Trichoderma isolates on reducing of soybean charcoal rot disease damage | ||
| نویسندگان [English] | ||
| Farhad Goharzad1؛ Mohammad Ali Tajick Ghanbary2؛ samira shahbazi3 | ||
| 1Department of Plant protection, Sari Agricultural Sciences and Natural Resources University, Sari, Iran. | ||
| 2Department of Plant Protection, Sari Agricultural Sciences and Natural Resources University, Sari , Iran | ||
| 3Nuclear Agriculture School, Nuclear Science and Technology Research Institute (NSTRI), Atomic Energy Organization of Iran (AEOI), Karaj, Iran. | ||
| چکیده [English] | ||
| Charcoal rot is the most important fungal disease on soybean in Iran. According to the absence of the resistant cultivars, soil inhabitant and the high pathogenicity rate of the pathogen, chemical and crop control alone is not succeed. To improve the efficiencyof disease biological control on soybean in greenhouse, the wild type Trichoderma koningii NAS-K1 (non radiated) and the selective mutant NAS-K1M25 isolates were used. The induction of mutation in wild type increases the biological control efficiency of the disease. The efficiency of powder, granular and seed coating bio-formulations, were evaluated separately in greenhouse. Powder has the best effect in reducing the disease; granular bio-formulation has the best effect on plant growth and its yield and seed coating, has the best effect on seed germination characteristics and vigor index. The application of these bio-formulations increased soybean growth indices compared to the control and chemical treatments. The highest yield production increase in the presence of the pathogen was observed by seed coating treated with NAS-K1M25. Study on viability of biological agent in powder and granular bio-formulations, showed that it has slight decrease and still effective for a period of 11 months at room temperature, but keeping it at 4 °C has a positive effect on it. | ||
| کلیدواژهها [English] | ||
| Biological fungicide, charcoal rot, induction of mutation, soybean Trichoderma | ||
| مراجع | ||
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ABBASI, S., N. SAFAIE and M. SHAMSBAKHSH, 2014. Evaluation of gamma-induced mutants of Trichoderma harzianum for biological control of charcoal rot of melon (Macrophominaphaseolina) in laboratory and greenhouse conditions." Journal of Crop Protection, 3(4): 509-521. ABDEL-LATEIF, K.S. 2017. Trichoderma as biological control weapon against soil born plant pathogens. African Journal of Biotechnology, 16, No. 50: 2299-2306. AHMADI, K., H. GHOLIZADEH, H.R. EBADZADEH, F. HATAMI, R. HOSSEINPOUR, H. ABDESHAH, M.M. REZAEE and M. FAZLI-ESTABRAGH, 2017. Agricultural Statistics of Iran, Information and Communication Technology Center, Planing
and Economic Affair, Ministry of Agriculture-Jahad, 3: 239. ALEAGHAEE, SH., S. REZAEE, M. EBADI and H.R. ZAMANIZADEH, 2018. The efficacy of some native Trichoderma isolates in induction of resistance in tomato against Fusarium oxysporum f.sp. lycopersici, the causal agent of Fusarium wilt disease. Journal of Entomology and Phytopatology, 85(2): 219-233. ANONYMOUS, 2019. “The most important achievements of major projects in the field of agriculture were announced”. Information and Public Relations Center, Ministry of Agriculture-Jahad, (https://ab_qazvin.maj.ir/Index.aspx?page_=dorsaetoolsenews&lang=1&sub=0&PageID=118732&PageIDF=0&tempname=main). BABU, B.K., A.K. SAXENA, A.K. SRIVASTAVA and D.K. ARORA, 2007. Identification and detection of Macrophomina phaseolina by using species-specific oligo-nucleotide primers and probe. Mycologia, 99: 797–803. BAHARVAND, A., S. SHAHBAZI, H. AFSHARMANESH, M.A. EBRAHIMI and H. ASKARI, 2014. Investigation of gamma irradiation on morphological characteristics and antagonist potential of Trichoderma viride against M. phaseolina. International Journal of Farming and Allied Sciences 3, No.11: 1157-1164. BARARI, H. 2016. Biocontrol of tomato to Fusarium Wilt by Trichoderma species under in vitro and in vivocondition.Cercetari Agronomice in Maldova, 165: 91- 98. BENITEZ, T., A.M. Rincon, M.C. Limon and A.C. Codon, 2004. Biocontrol mechanisms of Trichoderma strains. International Microbiology, 7: 249-260. CARDONA, R and H. RODRIGUEZ, 2006. Effects of Trichoderma harzianum fungus on the incidence of the charcoal rot disease on sesame. Review of the Faculdade de Agronomia. (LUZ), 23: 42-47. CUMAGUN, C.J.R. 2012. Managing Plant Diseases and Promoting Sustainability and Productivity with Trichoderma: The Philippine Experience. Journal of Agricultural Science and Technology, 14: 699-714. GAJERA, H., R. DOMADIYA, S. PATEL, M. KAPOPARA and B. GOLAKIYA, 2013. Molecular mechanism of Trichoderma as bio-control agents against phytopathogen system–a review. Curr Res Microbiol Biotechnol, 1(4): 133-142. ELAD, Y., I. CHET and Y. HENIS, 1982. Degradation of plant pathogenic fungi by Trichoderma harzianum. Canadian Journal of Microbiology. 28:719-725. ETEBARIAN, H.R. 2006. Evaluation of Trichoderma isolates for biological control of charcoal stem rot in melon caused by Macrophomina phaseolina. Journal of Agricultural Science and Technology, 8: 243-250. HAGGAG, W.M. and H.A.A. MOHAMED, 2002. Enhanecment of antifungal metabolite production from gamma-ray induced mutants of some Trichoderma species for control onion white disease. Plant Pathology Bulletin, 11: 45-56. HAGGAG, W.M. and S.A. ABO-SEDERA, 2005. Characteristics of three Trichoderma species in peanut haulms compost involved in biocontrol of cumin wilt disease. International Journal Agriculture Biology, 7(2): 222-229. HARMAN, G.E and P.K. KUBICEK, 1998. Trichoderma and Gliocladium. Vol. 2. Enzymes, Biological Control and Commercial Applications. Taylor and Francis, Londan, pp. 1-393. HARMAN, G.E., C.R. HOWELL, A. VITERBO, I. CHET and M. LORITO, 2004. Trichoderma species-opportunictic, avirulant plant symbionts. Nature Review Microbiology, 2: 43-56. HARMAN, G.E. 2006. Overview of mechanisms and uses of Trichoderma sp. Phytopathology. 96: 190-194. HARTMAN, G.L., J.B. SINCLAIR and J.C. RUPE, 1999. Compendium of Soybean Diseases, (4th Ed.), American Phytopathological Society Press, St Paul, MN, USA. JAYARAJ, J. and N.V. RADHAKRISHNAN, 2003. "Development of UV-induced carbendazim-resistant mutants of Trichoderma harzianum for integrated control of damping-off disease of cotton caused by Rhizoctonia solani." Journal of Plant Diseases and Protection 110, No. 5: 449-460. KHAN, M.R and J. GUPTA, 1998. Antagonistic efficacy of Trichoderma species against Macrophomina phaseolina on eggplant. Journal of Plant Diseases and Protection, 105(4): 387-393 KUKUK, C., M. KIVANC, E. KINAKI and G. KINACI, 2007. Efficacy of Trichoderma harzianum (Riffaii) on inhabitation of ascochyta blight disease of chickpea. Annals of Microbiology, 57:665-668. KUMAR, S. 2013. Trichoderma: a biological weapon for managing plant diseases and promoting sustainability. International Journal of Agriculture Science and Medical veterinary 1, No. 3: 106-121. LATIFI, N. 1993. Soybean Cultivation (Farming, Physiology, Consumption). Academic jahad publications, Mashhad University, 163 p. MEHRABI, M. and D. ZAFARI, 2008. The efficacy of Trichoderma isolates on stimulation of wheat growth. Iran's agricultural science publishing. Page 93 (In Persian). 39(1): 9-16. MISHRA, V.K. 2010. In vitro antagonism of Trichoderma species against Pythium aphanidermatum. Journal of Phytology. MOHAMADI, A.S., S. SHAHBAZI and H. ASKARI, 2014. Investigation of γ-radiation on morphological characteristics and antagonist potential of Trichoderma viride against Rhizoctonia solani. International Research Journal of Applied and Basic Sciences 8, No. 3: 329-336. MONTE, E. 2001. Understanding Trichoderma: between biotechnology and microbial ecology. Int. Microbiology, 4: 1-4. MORADI, R., S. SHAHBAZI, H. AHARI MOSTAFAVI, M.A. EBRAHIMI, H. ASKARI and M. MIRMAJLESI, 2013. Investigation of Gamma Radiation Effects on Morphological and Antagonistic Characteristics of Trichoderma harzianum. Crop Biotechnology, 4: 109-117. MOTTAGHIAN, A., H. PIRDASHTI, M.A. BAHMANYAR, A. SHAHSAVARI and R. HASANPOUR, 2009. Effect of three Trichoderma species and different amounts of enriched municipal waste compost on growth parameters in spinach (spinacia oleracea). In: Proceeding of 5th International Scientific Conference of Iran and Russia on Agricultural Development Problems. Saint Petersburg, Russia, 8-9 October: 267-270. MUKHERJEE, M., B.A. HORWITZ, P.D. SHERKHANE, R. HADAR and P.K. MUKHERJEE, 2006. A secondary metabolite biosynthesis cluster in Trichoderma virens: evidence from analysis of genes underexpressed in a mutant defective in morphogenesis and antibiotic production. Current genetics 50, No. 3: 193-202. PAPAVIZAS, G.C., J.A. LEWIS and T.H.A.E. MOITY, 1982. Evaluation of new biotypes of Trichoderma harzianum for tolerance to benomyl and enhanced biocontrol capabilities." Phytopathology 72, No. 1: 126-132. PUSHVAPAVATHI, Y., S.N. DASH, N. MADHAVI and D. DEEPIKA, 2016. Biological control of Fusarium wilts disease of banana with emphasis on Trichoderma spp. and Pseudomonas spp. Plant Archives, 16: 51- 59. SALARI, E., E. MAHDIKHANI MOGHADAM, H. ROUHANI, R. SABERI RISEH and M. MEHRABI KOOSHKI, 2014. Efficacy of Trichoderma in seed coating and soil application methods on tomato growth indices. Journal of Plant Protection, 28(4): 7-12. SHAHBAZI, S., H. ASKARI, N. PIRVALI BEIRANVAND and H. AHARI MOSTAFAVI, 2018. Completion Report of Biological Material Production and Technical Knowledge Project to Reduce damage of Soil Disease in Greenhouse Products Based on Trichoderma. Nuclear Science and Technology Research Institute (NSTRI), Atomic Energy Organization of Iran (AEOI), 314 p. (In Persian with English summary). SHAHSAVARI, A., H. PIRDASHTI, A. MOTTAGHIAN and M.A. TAJIK GHANBARI, 2010. Response of wheat (Triticum aestivum L.) growth parameters and yield to co-inoculation of farmyard manure, Tricoderma spp. And pseudomonas app. Journal of Agro Ecology, 2 (3): 448-458. SREEDEVI, B., M. CHARITHA DEVI and D.V.R. SAIGOPAL, 2011. Isolation and screening of effective Trichoderma spp. against the root rot pathogen Macrophomina phaseolina. Journal of Agricultural Technology, 7(3): 623-635. TERZIC, D., V. POPOVIC, M. TATIC and V. VASILEVA, 2018. Soybean area, yield and production in world. 22th Eco-Conference, Ecological Movement of Novisad, October, Serbia: 135-145. TIMMERS, A.C.J. 2008. The role of the plant cytoskeleton in the interaction between legumes and rhizobia. Journal of Microscopy, 231: 247–256. VASEBI, Y., A. ALIZADEH and N. SAFAIE, 2011. Biological Control of Soybean Charcoal Rot Caused by Macrophomina Phaseolina Using Trichoderma harzianum. Agriculture knowledge and sustainable production, 22(1): 41-54 (In Persian with English summary). VERMA, M., S.K. BRAR, R.D. TYAGI, R.Y. SURAMPALLI and J.R. VALERO, 2007. Antagonistic fungi, Trichoderma spp.: panoply of biological control. Biochemical Engineering Journal, 37(1): 1-20. WRATHER, J.A., S.R. KEDIG and D.D. TYLER, 1998. Tillage effects on Macrophomina phaseolina population density and soybean yields. Plant Disease, 82: 247-250. YAZDANI, M., H. PIRDASHTI and M.A. TAJIK GHANBARI, 2008. Effect of Tricoderma spp. and different organic manures on growth and development in soybean [Glysine max (L.) Merril.]. Electron journal of Crop production, 1(3): 65-82. YEDIDIA, I., N. BENHAMOU and I. CHET, 1999. Induction of defense responses in cucumber plants (Cucumis sativus L.) by the biocontrol agent Trichoderma harzianum. Applied Environmenal Microbiology, 653:1061-1070. ZHANG, F., J. YUAN, X. YANG, Y. CUI, L. CHEN, W. RAN and Q. SHEN, 2013. Putative Trichoderma harzianum mutant promotes cucumber growth by enhanced production of indole acetic acid and plant colonization. Plant and Soil, 368(1-2): 433-444. | ||
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