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Efficacy of different concentrations of microcapsules containing Talaromyces flavus with two formulations of powder and suspension in controlling Fusarium wilt disease of tomato

Document Type : Plant Pathology

Authors

1 Islamic Azad University, Varamin- Pishva Branch

2 Scientific Board Member, Iranian Research Institute of Plant Protection

3 ّFaculty of Plant Pathology Department, , Islamic Azad University, Varamin,Pishva Branch

Abstract

The efficiency of powder microcapsules and suspension microcapsules of Talaromyces flavus with concentrations of 106 × 2, 106 × 4, 106 × 6, 106 × 8 and 107 colony forming units per gram of formulation in soil addition method and a concentration of 107 colony forming units per gram of formulation in seed impregnation method was compared with registered fungicide Talaromin in two methods of seed impregnation and addition to soil to control Fusarium wilt disease of tomatoes. The results showed that the most effective treatments were related to the different concentrations of suspension microcapsules by soil addition method and powder microcapsules by seed coating method and the highest concentration (107 colony forming units per gram) in adding to soil method reduced significantly 83- 96% the severity of the disease compared to the infected control.

Keywords

References
ABD-ELSALAM, K. A. and M. A. ALGHUTHAINY. 2015. Nanobiofungicides: are they next generation of fungicides. Journal of Nanotechnology and Materials Science, No. 2: 1-3.
ANITHA, A. and M. RABEETH. 2010. Degradation of fungal cell walls of phytopathogenic fungi by lytic enzyme of Streptomyces griseus. African Journal of Plant Science, No. 4: 61-66.
ATFANNEJAD DEZFOOLI, R., L. NARAGHI and A. NIAZMAND. 2014. A comparative study on different antagonistic mechanisms of Talaromyces flavus and Trichoderma harzianum in terms of growth inhibition of Fusarium oxysporum f. sp. lycopersici, causal agent of tomato wilt disease in laboratory conditions. International Journal of Research and Review, No. 2: 115-127.
CHAUD, M., E. B. SOUTO, A. ZIELINSKA, P. SEVERINO, F. BATAIN, J. OLIVERIA-JUNIOR and T. ALVES. 2012. Nanopesticides in Agriculture: Benefits and Challenge in Agricultural Productivity, Toxicological Risks to Human Health and Environment. Toxics, No. 9: 131.
CHITARRA, G. S. 2003. Germination inhibitors of fungal spores: Identification and mode of action. Ph.D. thesis Wageningen University, Wageningen, The Netherlands. With summaries in English and Dutch), 120 pages.
ENGELELKES, C. A., R. L. NUCLO and D. R. FRAVEL. 1997. Effect of carbon, Nitrogen, and CN ratio on growth, sporulation, and biocontrol efficacy of Talaromyces flavus. Phytopathology, No. 87: 500-505.
HAMMOUDI, O., M. SALAN, R. ABUAMSHA and
R. EHLERS. 2012. Effectiveness of bacterial and fungal isolates to control Phoma lingam on oilseed rape, Brassica napus. American Journal of Plant sciences, No. 3: 773-779.
JOHNSON, k. B. and J. A. DILEONE. 1999. Effect of antibiosis on antagonist dose-plant disease response relationships for the biological control of crown gall of tomato and cherry. Phytopathology, No. 89: 974-980.
KHALIL, M. S., M. A. ABDEL-SATTAR, I. N. ALEY, K. A. ABED-ELSALAM and J. A. VERREET. 2003. Genetic affinities of Fusarium spp. and their correlation with origin and pathogenicity. African Journal of Biotechnology, No. 2: 109-113.
KHAN, N. T. and N. JAMEEL. 2016. Antifungal activity of silver nanoparticles produced from fungus, Penicillium fellutanum at different pH. Journal of Microbial and Biochemical Technology, No. 8: 440-443.
LIU, L., J. W. KLOPPER and S. TUZUN. 1995. Induction of systemic resistance in cucumber against Fusarium wilt by plant growth promoting rhizobacteria. Phytopathology, No. 85: 695-698.
NARAGHI, L., A. HEYDARI, S. REZAEE and M. RAZAVI. 2010a. Biological control of greenhouse cucumber Verticillium wilt disease by Talaromyces flavus. Phytopathologia Mediterranea, No. 49: 321-329.
NARAGHI, L., A. HEYDARI, S. REZAEE, M. RAZAVI and H. JAHANIFAR. 2010b. Study on antagonistic effects of Talaromyces flavus on Verticillium albo-atrum, the causal agent of potato wilt disease. Crop Protection, No. 29: 658-662.
NARAGHI, L., A. HEYDARI, S. REZAEE, M. RAZAVI, H. GAHANIFAR and E. MAHMOODI KHALEDI. 2010c. Biological control of tomato Verticillium wilt disease by Talaromyces flavus. Journal of Plant Protection Research, No. 50: 360-365.
NARAGHI, L., M. NEGAHBAN, A. HEYDARI, M. RAZAVI and H. AFSHARI AZAD. 2018. The effects of nanoparticles on sporulation and active population of Talaromyces flavus. International Journal of Bio-Technology and Research, No. 8: 27-38.
NEGAHBAN, M., S. MOHARAMIPOUR, M. ZANDI and M. H. PEZESHKI. 2011. Oil nano-encapsulation by coacervation method on nutritional indices of Ttribolium castaneum (Col: Tenebrionidae). The International journal of artificial organs, No. 34: 667-667.
SAJJADI, A. 2014. The effect of synthetic nanofertilizer on tobacco collar rot. Proceedings of the 21st Iranian Plant Protection Congress, Urmia University, September 1-4, 2014, page 135.
TOMASSETO, F., J. M. TYLIANAKIS, M. REALE, S. WRATTEN and S. L. GOLDSON. 2017. Intensified agriculture favors evolved resistance to biological control. Proceedings of National Academy of Sciences of the United States of America, No. 114: 3885-3890. 
Applied Entomology and Phytopathology
Volume 90, Issue 1 - Serial Number 114
September 2022
Pages 1-9
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