The effect of different nitrogen sources (glucosamine sulfate, ammonium sulfate, aspartic acid, phenylalanine and peptone) in comparison to sodium nitrate, the major nitrogen compound in basal agar Czapek’s synthetic medium growth were studied on the linear growth of Rhizoctonia solani and its pathogenicity on faba bean germinated seeds. Ammonium sulfate exhibited faster liner growth and showed the same effect as the basal medium with sodium nitrate while glucosamine sulfate showed less growth rate compared with sodium nitrate. Glucosamine sulfate and ammonium sulfate showed a significant reduction in number of infection cushions which led to significant decrease of disease index in vitro. Under greenhouse conditions, glucosamine sulfate or peptone as a sole nitrogen sources in food requirements of Rhizoctonia solani inoculum depressed the virulence of the fungus. The effect of different amounts of glucosamine sulfate was determined on fungal growth rate, infection cushions, disease index in vitro and polyphenol oxidase activity. Increasing amount of glucosamine sulfate showed significant reduction of growth rate in comparison to the basal medium with sodium nitrate. All seeds subjected to R. solani grown on different amount of glucosamine sulfate showed the lower number of infection cushions, disease index and polyphenol oxidase activity compared with sodium nitrate. Under greenhouse conditions, disease index showed a significantly decreased effect when glucosamine sulfate used as soil applications and showed better effect on shoot weight and root weight compared with control plants treated with sodium nitrate. Our study proposes that glucosamine sulfate may act as controlling factor of pathogenicity genes of R. solani

Rhizoctonia solani; faba bean; Vicia faba; nitrogen sources; glucosamine sulfate; pathogenicity

Bach, D. 1927. La nutrition azotée des Mucorinées. Assimilation de l'ion nitrique.

Duvenhage, J. A., J. M. Kotzé and E. M. C. Maas. 1992. The influence of nitrogen and calcium on mycelial growth and disease severity of Phytophthora cinnamomi and the effect of calcium on resistance of avocado to root rot. South African Avocado Growers’ Association Yearbook, 15: 12-14.

Ghahramani, S. 2000. Fundamentals of probability 2nd ed., Prentice Hall, New Jersey.

Huber, D. M. and R. D. Watson. 1974. Nitrogen Form and Plant Disease. Annual Review of Phytopathology, 12: 139-165.

Islam, R. 2015. Effect of various carbon and nitrogen sources on mycelial growth of Fusarium spp. isolated from agricultural fields of Murshidabad. Indian Journal of Scientific Research and Technology, 3: 71-77.

Jabin, F. and S. Nasreen. 2016. Phytochemical analysis of some medicinal plants. International Journal of Applied Research, 2: 293-295.

Kim, H.-T., Y.-R. Chung and K.-Y. Cho. 2001. Mycelial melanization of Rhizoctonia solani AG1 affecting pathogenicity in rice. The Plant Pathology Journal, 17: 210-215.

Lakshman, D. K., N. Alkharouf, D. P. Roberts, S. S. Natarajan and A. Mitra. 2012. Gene expression profiling of the plant pathogenic basidiomycetous fungus Rhizoctonia solani AG 4 reveals putative virulence factors. Mycologia, 104: 1020-1035.

Littell, R. C., G. A. Milliken, W. W. Stroup and R. D. Wolfinger. 1996. SAS System for Mixed models. . SAS Institute, Cary, NC.

Maha Helmy, M. 2015. Phenotypic diversity and molecular identification of the most prevalent anastomosis group of Rhizoctonia solani isolated from diseased faba bean plants. American Journal of Life Sciences, 3: 47.

Marzluf, G. A. 1997. Genetic regulation of nitrogen metabolism in the fungi. Microbiology and Molecular Biology Reviews, 61: 17-32.

Mohamed, M. H., E. A. M. Gado, S. H. El-Deeb and M. H. Mostafa. 2014. Effect of nitrate levels as a fertilizer or as a fungal nutrition on the aggressiveness of Rhizoctonia solani on faba bean. European Journal of Advanced Research in Biological and Life Sciences, 2: 1-13.

Moromizato, Z., N. Matsuyama and S. Wakimoto. 1980. The effect of amino acids on sclerotium formation of Rhizoctonia solani Kuehn (AG-1). I. Inhibition of sclerotial formation by various amino acids. Japanese Journal of Phytopathology, 46: 15-20.

Murray, D. I. L. 1982. Penetration of barley root and coleoptile surfaces by Rhizoctonia solani. Transactions of the British Mycological Society, 79: 354-360.

Parihar, P. S., O. Prakash and H. Punetha. 2012. Investigation on defensive enzymes activity of Brassica juncea genotypes during pathogenesis of alternaria blight. Nature and Science, 10: 63-68.

Ritchie, F., R. A. Bain and M. P. McQuilken. 2009. Effects of nutrient status, temperature and pH on mycelial growth, sclerotial production and germination of Rhizoctonia solani from potato. Journal of Plant Pathology: 589-596.

Ritter, G. 1909. Ammoniak und nitrate als stickstoffquelle für schimmelpilze.

Shetty, H. S., N. S. Vasanthi, B. R. Sarosh and K. R. Kini. 2001. Inheritance of downy mildew resistance, β-1,3-glucanases and peroxidases in pearl millet [Pennisetum glaucum (L.) R. Br.] crosses. TAG Theoretical and Applied Genetics, 102: 1221-1226.

Stephen, R. C. and K. K. Fung. 1971. Nitrogen requirements of the fungal endophytes of Arundina chinensis. Canadian Journal of Botany, 49: 407-410.

Trivedi, A., S. K. Sharma, R. Chaudhary, D. K. Jajoria, R. Kumar Jain and S. K. Yadav. 2017. Management of dry root rot caused by Rhizoctonia solani in organic gram. International Journal of Current Microbiology and Applied Sciences, 6: 3647-3652.

Ünal, M. Ü. 2007. Properties of polyphenol oxidase from anamur banana (Musa cavendishii). Food Chemistry, 100: 909-913.

White, C. and G. M. Gadd. 1983. Effect of glucosamine on morphology of Verticillium alboatrum. Transactions of the British Mycological Society, 80: 533-536.