| تعداد نشریات | 286 |
| تعداد نشریات سازمان | 84 |
| تعداد شمارهها | 3,005 |
| تعداد مقالات | 33,631 |
| تعداد مشاهده مقاله | 44,479,693 |
| تعداد دریافت فایل اصل مقاله | 30,130,503 |
بررسی پروفایل متابولیکی گیاه توت فرنگی در تعامل با باکتری اندوفیت Bacillus spp. سویه DM12 با استفاده از دستگاه کروماتوگرافی گازی– طیف سنجی جرمی و تعیین ویژگی های ضدقارچی سویه باکتری | ||
| مهار زیستی در گیاهپزشکی | ||
| دوره 11، شماره 2، اسفند 1402، صفحه 93-110 اصل مقاله (1.14 M) | ||
| نوع مقاله: مقاله پژوهشی | ||
| شناسه دیجیتال (DOI): 10.22092/bcpp.2024.367321.376 | ||
| نویسندگان | ||
| زهرا علی جانی1؛ جهانشیر امینی* 2؛ علی اکبر مظفری3 | ||
| 1پژوهشگر پسا دکتری گروه گیاهپزشکی، دانشکده کشاورزی، دانشگاه کردستان، سنندج، ایران. | ||
| 2استاد، گروه گیاهپزشکی، دانشکده کشاورزی، دانشگاه کردستان، سنندج، ایران. | ||
| 3استاد، گروه علوم باغبانی، دانشکده کشاورزی، دانشگاه کردستان، سنندج، ایران. | ||
| چکیده | ||
| قارچ Colletotrichum nymphaeae عامل بیماری آنتراکنوز توت فرنگی یکی از مهمترین بیماریهای این گیاه است که سبب آلودگی ریشه، برگ و میوه گیاه توت فرنگی در شرایط مختلف رشد میگردد. مشکل اصلی ارقام توت فرنگی در مقابل این بیماری پوسیدگی میوه است که کمیت و کیفیت و بازار پسندی میوه توت فرنگی را کاهش میدهد. در این تحقیق سویه باکتریایی اندوفیت از گیاهچههای سالم توتفرنگی (Fragaria × ananassa) جداسازی و اثرات آنتاگونیستی این سویه علیه قارچ عامل آنتراکنوز توتفرنگی Colletotrichum nymphaeae در شرایط آزمایشگاه، درون شیشه و گلخانه مورد بررسی قرار گرفت. سویه جداسازی شده با استفاده از ویژگیهای ریخت شناسی، بیوشیمیایی و آنالیز مولکولی ژن 16S rDNA در جنس Bacillus spp. قرار گرفت. سویه DM12 در آزمون کشت متقابل باعث کاهش رشد قارچ بیمارگر (%64/03) گردید. در آزمون تاثیر ترکیبات ضدقارچی تولید شده توسط باکتری اندوفیت میزان بازدارندگی از رشد میسلیوم و جوانه زنی اسپور قارچ بیمارگر به ترتیب %32/86 و %73/98 ارزیابی گردید. تاثیر متابولیت های فرار باکتریایی بر رشد میسلیوم قارچ بیمارگر ناچیز بود (%9/82). با توجه به آزمایشات بیوشیمیایی این سویه قادر به تولید آنزیم های پروتئاز، کیتیناز و پکتیناز و همچنین تولید سیدوفور، هورمون ایندول استیک اسید و جیبرلین بوده و توانایی حلالیت فسفات را دارد. سویه باکتری اندوفیت در شرایط درون شیشه قادر به بازدارندگی بیماری بر روی میوه توت فرنگی به میزان %90/87 گردید. همچنین درشرایط گلخانه در روش خیساندن خاک به میزان %72/22 و در روش اسپری اندام های هوایی به میزان %94/44 قادر به جلوگیری از گسترش بیماری بر روی گیاهچه های توت فرنگی شد. همچنین در این تحقیق تغییرات متابولیت های گیاهی در تیمارهای مختلف با باکتری اندوفیت در مقایسه با شاهد بررسی گردید. نتایج نشان داد که در تیمار شاهد منفی میزان ترکیبات استوگلیسرید (%19/418)، استیک اسید بوتیل استر (%4/734) و ریبیتول (%4/349)، در تیمار باکتری اندوفیت به تنهایی میزان ترکیبات تترامتیل دو–هگزامتان (%21/35)، اتیلن گلیکول منوایزوبوتیل اتر (%18/688) و میرتنول (%8/75)، در تیمار قارچ بیمارگر به تنهایی ترکیبات استوگلیسرید (%18/089)، استیک اسید منو گلیسرید (%17/96) و در تیمار قارچ بیمارگر همراه با باکتری اندوفیت ترکیبات ترت–بوتانتیول (%36/153)، اتوکسی تری اتیل سیلان (%14/126)، 5–متیل آمینو–1–2–3–4–تیاتریازول (%9/53) و 2–3–بوتاندیول (%7/795) بیشترین مقدار را داشتند. برخی از این ترکیبات مانند بوتاندیول، لاکتوز و تترادکان که در تیمار های باکتری اندوفیت به تنهایی و قارچ بیمارگر همراه با باکتری اندوفیت تولید شدند دارای خواص ضد قارچی می باشند. نتایج حاصل از این تحقیق نشان داد که سویه DM12 قادر به کاهش رشد میسلیوم، جوانه زنی اسپور، توسعه پوسیدگی میوه و شدت بیماری آنتراکنوز توت فرنگی در شرایط آزمایشگاه، درون شیشه و گلخانه می باشد. به منظور درک تعامل سویه DM12 با گیاه و سایر عوامل بیماریزای گیاهی و اثرات آن بر سیستم دفاعی گیاه، تحقیقات بیشتری مورد نیاز است. | ||
| کلیدواژهها | ||
| آنتراکنوز توت فرنگی؛ متابولیت های ضد قارچی؛ Bacillus spp؛ GC-Mass | ||
| عنوان مقاله [English] | ||
| Analysis of strawberry metabolic profiling in interaction with Bacillus spp. strain DM12 using Gas Chromatography-Mass Spectrometry and Determination of its Antifungal Activity | ||
| نویسندگان [English] | ||
| Zahra Alijani1؛ Jahanshir Amini2؛ Ali Akbar Mozafari3 | ||
| 1Post- Doctora research, Department of Plant Protection, Faculty of Agriculture, University of Kurdistan, Sanandaj, Iran | ||
| 2Professor, Department of Plant Protection, Faculty of Agriculture, University of Kurdistan, Sanandaj, Iran | ||
| 3Professor, Department of Horticultural Sciences, Faculty of Agriculture, University of Kurdistan, Sanandaj, Iran. | ||
| چکیده [English] | ||
| Colletotrichum nymphaeae infects the roots, leaves and fruits of the plant at different developmental stages and is one of the most important diseases of strawberry. The principal problems to strawberry cultivation are fruit rot caused by anthracnose that affect the quality and quantity of production and marketing in the field, and post–harvest. An endophytic bacterial strain, isolated from Fragaria × ananassa, and antifungal properties against Colletotrichum nymphaeae was assayed under in vitro, in vivo, and greenhouse experiments. Bacterial strain was identified as Bacillus spp. DM12 (MH161581) using phenotypic, biochemical and molecular phylogenetic analysis of the 16S rDNA gene. DM12 strain inhibited mycelial growth of fungal pathogen (64.03%) using dual–culture test. The cell–free culture compounds produced by DM12 prevented mycelial growth and conidial germination of C. nymphaeae by 32.86% and 73.98%, respectively but, inhibition percentage of mycelial growth of pathogen by volatile compounds was less (9.82%). As well as, protease, chitinase, pectinase, siderophore, IAA, gibberellin, and phosphate solubilization tests for this strain were positive. Anthracnose disease at post–harvest on fruit suppressed by the strain DM12 (90.87%). Also, biocontrol efficacy on strawberry plants by drenching soil and spraying methods were 72.22% and 94.44%, respectively, 60 days after inoculation. PCR amplification represented the presence of genes of surfactin. In addition, metabolite profile of strawberry was changed on presence of bacterial strain that a number of metabolites in control treatment with maximum area percent were Acetoglyceride (19.418%), Acetic acid, butyl ester (4.734%) and Ribitol (4.349%), in treatment inoculated with DM12 strain alone were Tetramethyl–2–hexadecen (21.35%), Ethylene glycol monoisobutyl ether (18.688%) and Myrtenol (8.75%), in treatment inoculated with fungal pathogen alone were Acetoglyceride (18.089%) and Acetic acid, monoglyceride (17.96%) and in treatment inoculated with C. nymphaeae and DM12 strain together were tert–Butanethiol (36.153%), Ethoxy triethyl silane (14.126%), 5–(Methylamino)–1,2,3,4–thiatriazole (9.53%) and 2,3–Butanediol (7.795%). Some of these compounds, such as Butanediol, Lactose and Tetradecane, which were produced in DM12 strain alone and C. nymphaeae and DM12 strain together treatments, have antifungal properties. These results showed that strain DM12 has able to decrease mycelial growth, conidial germination, fruit decay development and disease severity of strawberry anthracnose under in vitro, in vivo and greenhouse conditions. Further works are required in order to understanding the interaction of DM12 with the plant and others phytopathogens and its effects on the plant defense system. . | ||
| کلیدواژهها [English] | ||
| Antifungal metabolites, Bacillus spp, GC-Mass, Strawberry anthracnose | ||
| مراجع | ||
|
Aaisha, G.A. & Barate DL. 2016. Isolation and identification of pectinolytic bacteria from soil samples of Akola Region, India. International Journal of Current Microbiology and Applied Science, 5:514-524. Ahsan, T., Chen, J., Zhao, X., Irfan, M. & Wu, Y. 2017. Extraction and identification of bioactive compounds (eicosane and dibutyl phthalate) produced by Streptomyces strain KX852460 for the biological control of Rhizoctonia solani AG-3 strain KX852461 to control target spot disease in tobacco leaf. AMB Express, 7(1):1-9. Aliferis, K.A., Faubert, D. & Jabaji S. 2014. A metabolic profiling strategy for the dissection of plant defense against fungal pathogens. PLoS One, 9(11): e111930. Alijani, Z., Amini, J., Ashengroph, M. and Bahramnejad, B. 2019. Antifungal activity of volatile compounds produced by Staphylococcus sciuri strain MarR44 and its potential for the biocontrol of Colletotrichum nymphaeae, causal agent strawberry anthracnose. International Journal of Food Microbiology, 307:108276. doi:10.1016/j.ijfoodmicro. Al-Imara, E. & JA Al-Gazzawy, G. 2020. The study of purified secondary metabolites extracts of Bacillus subtilis and its chemotaxis effect on biofilm-forming bacteria. DYSONA-Life Science. 1(1):1-13. Alori, E.T., Glick, B.R. & Babalola, O.O. 2017. Microbial phosphorus solubilization and its potential for use in sustainable agriculture. Frontiers in Microbiology, 8:1-8. Amini, J., Farhang, V., Javadi, T. & Nazemi, J. 2016. Antifungal Effect of Plant Essential Oils on Controlling Phytophthora Species. Plant Pathology Journal, 32(1):16-24. Arrebola, E., Jacobs, R. & Korsten, L. 2010. Iturin A is the principal inhibitor in the biocontrol activity of Bacillus amyloliquefaciens PPCB004 against postharvest fungal pathogens. Journal of Applied Microbiology, 108(2):386-395. Ben Abdallah, R.A., Mejdoub-Trabelsi, B., Nefzi, A., Jabnoun-Khiareddin, H. & Daami-Remadi, M. 2016. Isolation of endophytic bacteria from Withania somnifera and assessment of their ability to suppress Fusarium wilt disease in tomato and to promote plant growth. Journal of Plant Pathology and Microbiology, 7:1-11. Berg, G., Eberl, L. & Hartmann, A. 2005. The rhizosphere as a reservoir for opportunistic human pathogenic bacteria. Environmental Microbiology, 7:1673–1685. Bergey, D.H. and Holt, J.G. 1994. Bergeys manual of determinative bacteriology, nine ed. Lippincott Williams and Wilkins, Philadelphia. Bibi, F. 2017. Diversity of antagonistic bacteria isolated from medicinal plant Peganum harmala L. Saudi Journal of Biological Sciences, 24:1288–1293. Boukaew, S. & Prasertsan, P. 2020. Efficacy of volatile compounds from Streptomyces philanthi RL‐1‐178 as a biofumigant for controlling growth and aflatoxin production of the two aflatoxin‐producing fungi on stored soybean seeds. Journal of applied microbiology. 129(3): 652-664. Cao, Y., Zhang, Z.H., Ling, N., Yuan, Y.J., Zheng, X.Y., Shen, B.A. & Shen, Q.R. 2011. Bacillus subtilis SQR 9 can control Fusarium wilt in cucumber by colonizing plant roots. Biology and Fertility of Soils, 47:495–06. Cao, Y., Xu, Z., Ling, N., Yuan, Y., Yang, X., Chen, L., Shen, B. & Shen, Q. 2012. Isolation and identification of lipopeptides produced by B. subtilis SQR 9 for suppressing Fusarium wilt of cucumber. Horticultural Science, 135:32–39. Chen, Y., Gao, X., Chen, Y., Qin, H., Huang, L. & Han, Q. 2014. Inhibitory efficacy of endophytic Bacillus subtilis EDR4 against Sclerotinia sclerotiorum on rapeseed. Biological Control. 78:67-76. Compant, S., Duffy, B., Nowak, J., Clément, C. & Barka, E.A. 2005. Use of plant growth-promoting bacteria for biocontrol of plant diseases: principles, mechanisms of action, and future prospects. Applied and Environmental Microbiology, 71(9):4951-4959. Cui, T.B., Chai, H.Y. & Jiang, L.X. 2012. Isolation and partial characterization of an antifungal protein produced by Bacillus licheniformis BS-3. Molecules, 17(6):7336-7347. Davis, K.R., Lyon, G.D., Darvill, A.G. & Albersheim, P. 1984. Host-pathogen interactions: XXV. Endopolygalacturonic acid lyase from Erwinia carotovora elicits phytoalexin accumulation by releasing plant cell wall fragments. Plant Physiology, 74(1):52-60. De Curtis, F., Lima, G., Vitullo, D. & De Cicco, V. 2010. Biocontrol of Rhizoctonia solani and Sclerotium rolfsii on tomato by delivering antagonistic bacteria through a drip irrigation system. Crop Protection, 29(7):663-70. Delp, B. & Milholland, R.D. 1980. Evaluation strawberry plants for resistance to Colletotrichum fragariae. Plant Disease, 64:1071-1073. Dias, A.C.F., Costa, F.E.C., Andrete, F.D., Lacava, P.T., Teixeira, M.A., Assumpcao, L.C., Araujo, W.L., Azevedo, J. & Melo, I. 2009. Isolation of micropropagated strawberry endophytic bacteria and assessment of their potential for plant growth promotion. World Journal of Microbiology and Biotechnology, 25:189-195. Effantin, G., Rivasseau, C., Gromova, M., Bligny, R. & Hugouvieux‐Cotte‐Pattat, N. 2011. Massive production of butanediol during plant infection by phytopathogenic bacteria of the genera Dickeya and Pectobacterium. Molecular Microbiology, 82(4):988-997. Embaby, E.M. & Abd-Ellatif, A.A. 2013. Species identification of Colletotrichum the causal agent of strawberry anthracnose and their effects on fruit quality and yield losses. Research Journal of Applied Sciences, 9:3845-56. Encinas-Basurto, D., Valenzuela-Quintanar, M.I., Sánchez-Estrada, A., Tiznado-Hernández, M.E., Rodríguez-Félix, A. & Troncoso-Rojas, R. 2017. Alterations in volatile metabolites profile of fresh tomatoes in response to Alternaria alternata (Fr.) Keissl. 1912 infection. Chilean Journal of Agricultural Research, 77(3):94-201. Espinel-Ingroff, A., Arthington-Skaggs, B., Iqbal, N., Ellis, D., Pfaller, M.A., Messer, S., Rinaldi, M., Fothergill, A., Gibbs, D.L. & Wang, A. 2007. Multicenter evaluation of a new disk agar diffusion method for susceptibility testing of filamentous fungi with voriconazole, posaconazole, itraconazole, amphotericin B, and caspofungin. Journal of Clinical Microbiology, 45(6):1811-1820. Essghaier, B., Fardeau, M.C., Cayol, J.L., Hajlaoui, M.R., boudabous, A., Jijakli, H. & Sadfi-Zouaoui, N. 2009. Biological control of grey mould in strawberry fruits by halophilic bacteria. Journal of Applied Microbiology, 106:833–846. Garrido, C., Carbú, M., Fernández-Acero, F.J., González-Rodríguez, V.E. & Cantoral, J.M. 2011. New insight in the study of strawberry fungal pathogens. G3: Genes, Genomes, Genetics, 5(1):24-39. Geng, H., Yu, X., Lu, A., Cao, H., Zhou, B., Zhou, L. & Zhao, Z. 2016. Extraction, chemical composition, and antifungal activity of essential oil of bitter almond. International Journal of Molecular Sciences, 17(9):1-14. Gond, S.K., Bergen, M.S., Torres, M.S. & White Jr, J.F. 2015. Endophytic Bacillus spp. produce antifungal lipopeptides and induce host defense gene expression in maize. Microbiology Research, 172:79-87. Grimont, F. & Grimont, P.A. 2006. The genus Serratia. pp.219-244. In: Dworkin, M., Falkow, S., Rosenberg, E., Schleifer, K.H. & Stackebrandt, E. (eds.), The Prokaryotes: Volume 6: Proteobacteria: Gamma Subclass. Springer. Guardado-Valdivia, L., Tovar-Pérez, E., Chacón-López, A., López-García, U., Gutiérrez-Martínez, P., Stoll, A. & Aguilera, S. 2018. Identification and characterization of a new Bacillus atrophaeus strain B5 as biocontrol agent of postharvest anthracnose disease in soursop (Annona muricata) and avocado (Persea americana). Microbiology Research, 210:26-32. Hall, T.A. 1999. BioEdit: a user-friendly biological sequence alignment editor and analysis program for Windows 95/98/NT. In: Nucleic acids symposium series. 41(41), 95-98. [London]: Information Retrieval Ltd., c1979-c2000. Hallmann, J., Quadt-Hallmann, A., Mahaffee, W.F. & Kloepper, J.W. 1997. Bacterial endophytes in agricultural crops. Canadian Journal of Microbiology, 43:895–914. Hidayati, U., Chaniago, I.A., Munif, A. & Santosa, D.A. 2014. Potency of plant growth promoting endophytic bacteria from rubber plants (Hevea brasiliensis). Agronomy Journal, 13(3):147-52. Holbrook, A.A., Edge, W.J.W. & Bailey, F. 1961. Spectrophotometric method for determination of Gibberellic acid. Journal of Chemistry, 28:159-167. Huang, H., Wu, Z., Tian, C., Liang, Y., You, C. & Chen, L. 2015. Identification and characterization of the endophytic bacterium Bacillus atrophaeus XW2, antagonistic towards Colletotrichum gloeosporioides. Annals of Microbiology, 65(3):1361-71. Ibrahim, D., Lee, C.C. & Sheh-Hong, L. 2014. Antimicrobial activity of endophytic fungi isolated from Swietenia macrophylla leaves. Natural Product Communications, 9(2):247-50. Islam, M.R., Jeong, Y.T., Lee, Y.S. & Song, C.H. 2012. Isolation and identification of antifungal compounds from Bacillus subtilis C9 inhibiting the growth of plant pathogenic fungi. Mycobiology, 40(1):59-65. Islam, S., Akanda, A.M., Prova, A., Islam, M.T. & Hossain, M.M. 2016. Isolation and identification of plant growth promoting rhizobacteria from cucumber rhizosphere and their effect on plant growth promotion and disease suppression. Frontiers in Microbiology, 6:1-12. Jangir, M., Pathaka, R., Sharma, S. & Sharmab, S. 2018. Biocontrol mechanisms of Bacillus sp., isolated from tomato rhizosphere, against Fusarium oxysporum f. sp. lycopersici. Biological Control, 123:60-70. Karanja, E.N., Boga, H.I., Muigai, A.W., Wamunyokoli, F., Kinyua, J. & Nonoh, J.O. 2012. Growth characteristics and production of secondary metabolites from selected novel Streptomyces species isolated from selected Kenyan national parks. Scientific Conference Proceedings. Karimi, K., Arzanlou, M. & Pertot, I. 2019. Weeds as potential inoculum reservoir for Colletotrichum nymphaeae causing strawberry anthracnose in Iran and Rep-PCR fingerprinting as useful marker to differentiate C. acutatum complex on strawberry. Frontiers in Microbiology, 10(129):1-13. Kumar, K.V.K., Yellareddygari, S.K., Reddy, M.S., Kloepper, J.W., Lawrence, K.S., Zhou, X.G., Sudini, H., Groth, D.E., Raju, S.K. & Miller, M.E. 2012. Efficacy of Bacillus subtilis MBI 600 against sheath blight caused by Rhizoctonia solani and on growth and yield of rice. Rice Science, 19(1):55–63. Lata, K. 2015. Gas chromatography-mass spectrometry analysis of bioactive constituents from the marine Streptomyces. Asian Journal of Pharmaceutical and Clinical Research, 8:244-246. Li, S., Zhang, N., Zhang, Z., Luo, J., Shen, B., Zhang, R. & Shen, Q. 2013. Antagonist Bacillus subtilis HJ5 controls Verticillium wilt of cotton by root colonization and biofilm formation. Biology and Fertility of Soils, 49:295–03. Liu, B., Huang, L.L., Buchenauer, H. & Kang, Z.S. 2010. Isolation and partial characterization of an antifungal protein from the endophytic Bacillus subtilis strain EDR4. Pesticide Biochemistry and Physiology, 98:305-311. Mates, A.D.P.K., Pontes, N. & Halfeld-Vieira, B.A. 2019. Bacillus velezensis GF267 as a multi-site antagonist for the control of tomato bacterial spot. Biological Control, 107:2411-2502. Manso, T. & Nunes, C. 2011. Metschnikowia andauensis: a novel biocontrol agent of fruit postharvest diseases. In International Symposium on Biological Control of Postharvest Diseases: Challenges and Opportunities. Meliah, S., Sulistiyani, T.R., Lisdiyanti, P., Kanti, A., Sudiana, I. & Kobayashi, M. 2021. Antifungal Activity of Endophytic Bacteria Associated with Sweet Sorghum (Sorghum bicolor). Journal of Mathematical and Fundamental Sciences, 53(1):16-30. Mengistu, A.A. 2020. Endophytes: Colonization, behaviour, and their role in defense mechanism. International Journal of Microbiology, 1:1-8. Monte, E. 2001. Understanding Trichoderma: between biotechnology and microbial ecology. International Microbiology, 4:1–4. Mora, I., Cabrefiga, J. & Montesinos, E. 2011. Antimicrobial peptide genes in Bacillus strains from plant environments. International Microbiology, 14(4):213-223. Moreira, R.R., Nesi, C.N. & De Mio, L.L.M. 2014. Bacillus spp. and Pseudomonas putida as inhibitors of the Colletotrichum acutatum group and potential to control Glomerella leaf spot. Biological Control, 72:30-37. Murashige, T. & Skoog, F. 1962. A revised medium for rapid growth and bio assays with tobacco tissue cultures. Physiologia Plantarum, 15(3):473-497. Ongena, M., Jourdan, E., Adam, A., Paquot, M., Brans, A., Joris, B., Arpigny, J.L. & Thonart, P. 2007. Surfactin and fengycin lipopeptides of Bacillus subtilis as elicitors of induced systemic resistance in plants. Applied and Environmental Microbiology journal, 9:1084–1090. Ongena, M. & Jacques, P. 2008. Bacillus lipopeptides: versatile weapons for plant disease biocontrol. Trends in Microbiology, 16:115–125. Ordentlich, A., Elad, Y. & Chet, I. 1988. The role of chitinase of Serratia marcescens in biocontrol of Sclerotium rolfsii. Phytopathology, 78(1):84-88. Pandey, S.S., Singh, S., Babu, C.S., Shanker, K., Srivastava, N.K. & Kalra, A. 2016. Endophytes of opium poppy differentially modulate host plant productivity and genes for the biosynthetic pathway of benzylisoquinoline alkaloids. Planta, 43:1097-1114. Patil, S., Bheemaraddi, M.C., Shivannavar, C.T. & Gaddad, M.S. 2014. Biocontrol activity of siderophore producing Bacillus subtilis CTS-G24 against wilt and dry root rot causing fungi in chickpea. Journal of Agriculture and Veterinary Science, 7:63-68. Paul, N.C., Ji, S.H., Deng, J.X. & Yu, S.H. 2013. Assemblages of endophytic bacteria in chili pepper (Capsicum annuum L.) and their antifungal activity against phytopathogens in vitro. Plant Omics, 6(6):441-448. Peng, X., Zhang, H., Bai, Z. & Li, B. 2004. Induced resistance to Cladosporium cucumerinum in cucumber by pectinases extracted from Penicillium oxalicum. Phytoparasitica, 32(4):377-87. Rakotoniriana, E.F., Rafamantanana, M., Randriamampionona, D., Rabemanantsoa, C., Urveg-Ratsimamanga, S., El Jaziri, M., Munaut, F., Corbisier, A.M., Quetin-Leclercq, J. & Declerck, S. 2013. Study in vitro of the impact of endophytic bacteria isolated from Centella asiatica on the disease incidence caused by the hemibiotrophic fungus Colletotrichum higginsianum. Antonie Van Leeuwenhoek, 103:121-133. Schulz, S. & Dickschat, J.S. 2007. Bacterial volatiles: the smell of small organisms. Natural product reports. 24(4):814-842. Shanmugaiah, V., Mathivanan, N., Balasubramanian, N. & Manoharan, P.T. 2008. Optimization of cultural conditions for production of chitinase by Bacillus laterosporous MML2270 isolated from rice rhizosphere soil. African Journal of Biotechnology, 7:2562-2568. Tiru, M., Muleta, D., Bercha, G. & Adugna, G. 2013. Antagonistic effect of rhizobacteria against coffee wilt disease caused by Gibberella xylarioides. Asian Journal of Plant Pathology, 7:109-122. Vahabi, K., Meichsner, D. & Oelmüller, R. 2014. Interaction of Arabidopsis and Piriformospora indica in a hydroponic system. Endocytobiosis. Cell Research, 25:53-55. Yan, F., Ye, X., Li, C., Wang, P., Chen, S. & Lin, H. 2021. Isolation, purification, gene cloning and expression of antifungal protein from Bacillus amyloliquefaciens MG-3. Food Chemistry, 349:1-7. Yang, P., Sun, Z.X., Liu, S.Y., Lu, H.X., Zhou, Y. & Sun, M. 2013. Combining antagonistic bacteria in different growth stages of cotton for control of Verticillium wilt. Crop Protection, 47:17-23. Yi, H.S., Heil, M., Adame-Alvarez, R.M., Ballhorn, D.J. & Ryu, C.M. 2009. Airborne induction and priming of plant defenses against a bacterial pathogen. Plant Physiology, 151(4):2152-2161. Yu, X., Ai, C., Xin, L. & Zhou, G. 2011. The siderophore-producing bacterium, Bacillus subtilis CAS15, has a biocontrol effect on Fusarium wilt and promotes the growth of pepper. European Journal of Soil Biology, 47(2):138–45. Zhang, D., Yu, S., Yang, Y., Zhang, J., Zhao, D., Pan, Y. & Zhu, J. 2020. Antifungal effects of volatiles produced by Bacillus subtilis against Alternaria solani in potato. Frontiers in Microbiology. 11:1196. Zhao, Q., Ran, W., Wang, H., Li, X., Shen, Q., Shen, S. & Xu, Y. 2013. Biocontrol of Fusarium wilt disease in muskmelon with Bacillus subtilis Y-IVI. Biocontrol, 58:283–92. | ||
|
آمار تعداد مشاهده مقاله: 98 تعداد دریافت فایل اصل مقاله: 36 |
||