Response of some wild species of tomato against Peanut bud necrosis virus under open-field conditions
Downloads
Published
Keywords:
Solanum lycopersicum, S. peruvianum, peanut bud necrosis virus.Issue
Section
License
This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.
Thrips-borne Tospovirus pathogens adversely affect many globally important crops. Among 16 distinct virus species in the Tospovirus genus, four species including Peanut bud necrosis virus (PBNV) causing necrosis disease in tomato have been reported in India. Identification of stable sources and further utilization of wild relatives as gene sources to increase levels and diversify the bases of resistance may offer good management for the disease. A total of 13 wild species of tomato (Solanum peruvianum), two S. pimpinellifolium, one S. chilense, one S. pennellii and three check cultivars (S. lycopersicum) along with two cultivars (S. lycopersicum) having the Sw-5 and Sw-7 genes were evaluated under field conditions during three consecutive seasons (June to October 2008, July to December 2009, August 2010 to February 2011). Among all, a high degree of field resistance (>80%) was detected in seven lines of S. peruvianum (L00735, L00671, L00887, L06138), S. chilense (TL02226) and S. pimpinellifolium (L03708, TL02213) lines. The field data was also supported by negative reaction against a polyclonal antiserum of the nucleocapsid protein (N) of PBNV in direct antigen coating-enzyme linked immunosorbent assay (DAC-ELISA). The cultivars with Sw-5 and Sw-7 genes were highly susceptible to PBNV.Abstract
How to Cite
Downloads
Anonymous, 2010. Package of practices of the important horticultural crops of Andhra Pradesh. YSR Hortl. Univ., West Godavari district. Akram, M., Jain, R.K., Vikas Chaudhary, Ahlawat, Y.S., and Khurana, S.M.P. 2004. Comparison of groundnut bud necrosis virus isolates based on movement protein (NSm) gene sequences. Ann. Appl. Biol. 145: 285-89. Campbell, C.L. and Madden, L.V. 1990. Introduction to Plant Disease Epidemiology, John Wiley and Sons, New York, 532 p. Cho, J.J., Mau, R.F.L., Hamasaki, R.T. and Gonsalves, D. 1988. Detection of Tomato spotted wilt virus in individual thrips by enzymelinked immunosorbent assay. Phyotopath. 78: -52. de Avila, A.C., de Hann, P., Kormelink, R., Resende, R.deo., Kitajima, E.W., Goldbach R.E. and Peters, J.R. 1993. Classification of tospoviruses based on phylogeny of nucleoprotein gene sequences. J. General Virol. : 153-59. Gordillo, L.F., Stevens, M.R., Millard, M.A. and Geary, B. 2008. Screening two Lycopersicon peruvianum collections for resistance to Tomato spotted wilt virus. Pl. Dis. 92: 694-04. Greenough, D.R., Black, L.L. and Bond, W.P. Aluminum-surfaced mulch: an approach to control of Tomato spotted wilt virus in solanaceous crops. Pl. Dis. 74: 805-08. Jain, R.K., Umamaheswaran, K., Bhat, A.I., Thien, H.X. and Ahlawat, Y.S. 2002. Necrosis disease on cowpea, mungbean and tomato is caused by groundnut bud necrosis virus. Indian Phytopath. 55: 354 Krishna Kumar, N.K., Ullman, N.K. and Cho, J.J. Evaluation of Lycoperscion germplasm for tomato spotted wilt tospovirus resistance by mechanical and thrips transmission. Pl. Dis. 77: -41 Krishna-Kumar N.K., Ullman, D.E. and Cho, J.J. Resistance among Lycopersicon species to Frankliniella occidentalis (Thysanoptera: Thripidae). J. Ecol. Entomol. 88: 1057-65. Paterson, R.G., Scott, S.J. and Gergerich, R.C. Resistance in two Lycopersicon species to an Arkansas isolate of Tomato spotted wilt virus. Euphytica, 43: 173-78 Qui, W.P. and Moyer, J.W. 1999. Tomato spotted wilt tospovirus adapts to TSWV N gene-derived resistance by genome reassortment. Phytopath. : 575-82 Rosello, S., Diez, M.J., Lacasa, A., Jorda, C. and Nuez, F. 1997. Testing resistance to TSWV introgressed from Lycopersicon peruvianum by artificial transmission techniques. Euphytica, 98: -98. Sain, S.K. and Chadha, M.L. 2007. Major viral diseases incidence on important vegetable crops in Hyderabad. In: 10th International Plant Virus Epidemiology Symposium’ Controlling Epidemics of Emerging and Established Plant Virus Diseases-The Way Forward, 15-19 Oct , ICRISAT, Patancheru, India, p. 114. Singh, B.R. and Tripathi, D.P. 1991. Loss due to leaf curl and spotted wilt diseases of tomato. Madras Agric. J. 78: 34-36 Snedecor, G.W. and Cochran, W.G. 1980. Statistical Methods (7th edn.), The Iowa University Press, Ames, Iowa, USA, 507 p. Stevens, M.R., Scott, S.J. and Gergerich, R.C. Evaluation of seven Lycopersicon species for resistance to Tomato spotted wilt virus (TSWV). Euphytica, 80: 79-84. Swift, C.E. 2006. Fact sheet on Tomato spotted wilt virus. Tri river area, Colorado State University Cooperative Extension.2775 US Hwy 50. http:// www.ext.colostate.edu. Soler, S., Cebolla-Cornejo, J. and Nuze, F. 2003. Control of diseases induced by tospoviruses in tomato: an update of the genetic approach. Phytopath. Mediterr. 42: 207-19. Zaccardelli, M., Perrone, D., Galdo, A. Del., Campanile, F., Parrella, G. and Giordano, I. Tomato genotypes resistant to Tomato spotted wilt virus evaluated in open field crops in Southern Italy. Acta Hort. 789: 147-49.
References
Similar Articles
- S. Rajamanickam, S. Rageshwari, P. Renukadevi, S. Nakkeeran, Occurrence of Plantago asiatica mosaic virus infecting oriental lily in India , Indian Journal of Horticulture: Vol. 74 No. 04 (2017): Indian Journal of Horticulture
- Jai Prakash, A.K. Singh, Screening of papaya genotypes against the viral diseases , Indian Journal of Horticulture: Vol. 70 No. 03 (2013): Indian Journal of Horticulture
- K.P. Sajith, S. Uma, M.S. Saraswathi, S. Backiyarani, P. Durai, Macropropagation of banana - Effect of bio-fertilizers and plant hormones , Indian Journal of Horticulture: Vol. 71 No. 03 (2014): Indian Journal of Horticulture
- Bichhinna M. Rout, Amish K. Sureja, Sabtharishi Subramanian, Prasanta Kumar Dash, Anilabh Das Munshi, Studies on the transmission of Squash Leaf Curl China Virus causing yellow mosaic and leaf curl disease in pumpkin , Indian Journal of Horticulture: Vol. 81 No. 01 (2024): Indian Journal of Horticulture
- Harish Kumar, Rachna Arora, Anirudh Thakur, Sandeep Sharma, Impact assessment of growing media and bioinoculents on growth and bud take of rough lemon , Indian Journal of Horticulture: Vol. 77 No. 03 (2020): Indian Journal of Horticulture
- Kajal K Biswas, Shruti Godara, Dipak Nayak, Distribution of Citrus tristeza virus in the Darjeeling hills and their biological symptoms in mandarin orchards , Indian Journal of Horticulture: Vol. 71 No. 03 (2014): Indian Journal of Horticulture
- YRahul Chandel, A. T. Sadashiva, T. H. Singh, Evaluation of tomato parental lines for leaf curl disease resistance and its validation through molecular markers , Indian Journal of Horticulture: Vol. 76 No. 04 (2019): Indian Journal of Horticulture
- R. Bhatia, Chander Parkash, S.S. Dey, Chandresh Chandel, V. Bhardwaj, In vitro propagation of a self-incompatible cabbage line ‘Sel. 5’ , Indian Journal of Horticulture: Vol. 70 No. 03 (2013): Indian Journal of Horticulture
- Aroosa Khalil, M.K. Sharma, Nowsheen Nazir, A.S. Sundouri, Effect of bud load and fertilizer application on growth, yield and quality of Sahebi grape , Indian Journal of Horticulture: Vol. 75 No. 03 (2018): Indian Journal of Horticulture
- Rehana Javid, W.M. Wani, G.H. Rather, N.A. Ganai, Influence of irrigation levels and phenological stages on yield and quality attributes of sweet cherry cv. Regina , Indian Journal of Horticulture: Vol. 79 No. 1 (2022): Indian Journal of Horticulture
<< < 1 2 3 4 5 6 7 8 9 10 > >>
You may also start an advanced similarity search for this article.
