Unveiling the Antibacterial Potential of Plant Defence Activators in Conjunction with Meteorological Variables against Bacterial Leaf Spot in Spinach
Abstract
Spinach is susceptible to various fungal, bacterial, and viral pathogens. Among these, bacterial leaf spot poses a significant threat, leading to substantial reductions in both yield and quality. Recent research focused on evaluating different plant defense activators for their effectiveness against bacterial leaf spot in spinach. Of the tested activators, Salicylic acid showed the lowest disease severity and incidence, with values of 24.76% and 27.73%, respectively, followed by Citric acid (27.43%, 32.76%), Benzoic acid (29.57%, 38.32%), and K2HPO4 (33.31%, 38.38%) under greenhouse and field conditions, compared to the control. Various epidemiological factors—including temperature (minimum and maximum), relative humidity (%), rainfall (mm), and wind speed (km/h)—were assessed for their impact on disease development in three local spinach varieties: Dasi Palak, Lahori Palak, and Swiss Chard Palak. The results showed that disease severity increased considerably when the temperature ranged from 26-28°C, relative humidity was 69-73%, rainfall was 0.5-1 mm, and wind speed was 1.5-2 km/h. All environmental factors exhibited a positive correlation with the development of bacterial leaf spot in spinach. Greenhouse and field trials were conducted using a Complete Randomized Design (CRD) and a Randomized Complete Block Design (RCBD), respectively. Based on the findings, the application of Salicylic acid is recommended as a reliable and ecologically sound strategy for managing bacterial leaf spot in spinach.
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References
Achuo, E., K. Audenaert, H. Meziane and M. Höfte. 2004. The salicylic acid‐dependent defence pathway is effective against different pathogens in tomato and tobacco. Plant Pathology, 53: 65-72.
Ahmad, S., R. Gordon‐Weeks, J. Pickett and J. Ton. 2010. Natural variation in priming of basal resistance: From evolutionary origin to agricultural exploitation. Molecular plant pathology, 11: 817-27.
Atiq, M., M. F. Ullah, N. A. Rajput, A. Hameed, S. Ahmad, M. Usman, A. Hasnain, A. Nawaz, S. Iqbal and H. Ahmad. 2024. Surveillance and management of brown spot of potato. Archives of Phytopathology and Plant Protection, 57: 1-18.
Baltrus, D. A., H. C. McCann and D. S. Guttman. 2017. Evolution, genomics and epidemiology of Pseudomonas syringae: Challenges in bacterial molecular plant pathology. Molecular plant pathology, 18: 152-68.
Chhipa, H. 2019. Applications of nanotechnology in agriculture. In, Methods in Microbiology. Elsevier.
Choi, H. K., G. C. Song, H.-S. Yi and C.-M. Ryu. 2014. Field evaluation of the bacterial volatile derivative 3-pentanol in priming for induced resistance in pepper. Journal of Chemical Ecology, 40: 882-92.
Diab, S., Y. Bashan, Y. Okon and Y. Henis. 1982. Effects of relative humidity on bacterial scab caused by Xanthomonas campestris pv. vesicatoria on pepper. Phytopathology, 72: 1257-60.
FAO. 2020. World Food and Agriculture Statistical year Book. Food and Agriculture Organization. Rome, Italy.
Hansen, M. A. 2009. Angular leaf spot of cucumber. Virginia Cooperative Extension. pp. 450-700.
Ibrahimpasic, K. 2013. Alpha lipoic acid and glycaemic control in diabetic neuropathies at type 2 diabetes treatment. Medical Archives, 67: 7-9.
Kennelly, M. M., F. M. Cazorla, A. de Vicente, C. Ramos and G. W. Sundin. 2007. Pseudomonas syringae diseases of fruit trees: Progress toward understanding and control. Plant Disease, 91: 4-17.
Koike, S., H. Azad and D. Cooksey. 2002. First report of bacterial leaf spot of spinach caused by a Pseudomonas syringae pathovar in California. Plant Disease, 86: 921-21.
Li, J., T. Long, T.-J. Sun, Y. Lu, J. Yin, Y.-B. Yang, G.-Y. Dai, X.-Y. Zhu and N. Yao. 2020. A pyrimidin-like plant activator stimulates plant disease resistance and promotes the synthesis of primary metabolites. International Journal of Molecular Sciences, 21: 2705.
Littell, R. C., P. Henry and C. B. Ammerman. 1998. Statistical analysis of repeated measures data using SAS procedures. Journal of animal science, 76: 1216-31.
Malik, L., M. Atiq, N. A. Rajput, M. Usman, A. Akram, A. Jabbar, M. N. Zahid, W. Ahmad and M. Qasim. 2023. Induction of resistance in mungbean against cercospora leaf spot through plant defense activators. Agricultural Sciences Journal, 5: 28-34.
McGuffie, K. and A. Henderson-Sellers. 2014. The climate modelling primer. John Wiley and Sons.
Miano, T. F. 2016. Nutritional value of Spinacia oleraecea spinach-An overview. International Journal of Life sciences and review, 2: 172-74.
Planas-Marquès, M., M. Bernardo-Faura, J. Paulus, F. Kaschani, M. Kaiser, M. Valls, R. A. van der Hoorn and N. S. Coll. 2018. Protease activities triggered by Ralstonia solanacearum infection in susceptible and tolerant tomato lines. Molecular & Cellular Proteomics, 17: 1112-25.
Pohronezny, K., M. A. Moss, W. Dankers and J. Schenk. 1990. Dispersal and management of Xanthomonas campestris pv. vesicatoria during thinning of direct-seeded tomato. Plant Disease, 74: 800-05.
Ranjan, R., P. Jha, B. Rai, R. Kumari and S. Kumar. 2021. Management of bacterial wilt of potato and tomato caused by R. solanacearum through resistance inducer chemicals. The Pharma Innovation Journal, 10: 01-06.
Scortichini, M., E. Stefani, J. Elphinstone and M. Bergsma Vlami. 2013. PM 7/110 (1) Xanthomonas spp. (Xanthomonas euvesicatoria, Xanthomonas gardneri, Xanthomonas perforans, Xanthomonas vesicatoria) causing bacterial spot of tomato and sweet pepper. BULLETIN OEPP, 43: 7-20.
Shad, M., M. Usman and Q. A. Gardner. 2023. Structural-functional characterization of cytochrome b in bc1 and b6 f complexes along with polymorphic analysis. Pakistan Journal of Zoology, 55: 975-86.
Shaheen, H., N. Rajput, M. Atiq, L. Amrao, W. Arshad, G. Kachelo, M. Usman and M. Tahir. 2023. Synthetic fungicides for controlling brown leaf spot of rice caused by Bipolaris oryzae. International Journal of Biology and Chemistry, 16: 33-42.
Sharma, D. and Y. Singh. 2019. Characterization of Ralstonia solanacearum isolates using biochemical, cultural, molecular methods and pathogenicity tests. Journal of Pharmacognosy and Phytochemistry, 8: 2884-89.
Shila, S., M. Islam, N. Ahmed, K. Dastogeer and M. Meah. 2013. Detection of Pseudomonas syringae pv. lachrymans associated with the seeds of cucurbits. Universal Journal of Agricultural Research, 1: 1-8.
Singh, A., A. Jain, B. K. Sarma, R. S. Upadhyay and H. B. Singh. 2014. Rhizosphere competent microbial consortium mediates rapid changes in phenolic profiles in chickpea during Sclerotium rolfsii infection. Microbiological research, 169: 353-60.
Steel, R. G., J. H. Torrie and D. A. Dickey. 1997. Principles and procedures of statistics: A biometrical approach. McGraw-Hill: United States of America.
Sun, T.-J., Y. Lu, M. Narusaka, C. Shi, Y.-B. Yang, J.-X. Wu, H.-Y. Zeng, Y. Narusaka and N. Yao. 2015. A novel pyrimidin-like plant activator stimulates plant disease resistance and promotes growth. PLoS One, 10: e0123227.
Tahat, M., K. Sijam and R. Othman. 2010. Spores germination and Ralstonia solanacearum growth in vitro. International Journal of Plant Pathology, 1: 1-12.
Tahir, Z. B., M. Atiq, N. A. Rajput, A. Akram, A. M. Arif, S. Iqbal, S. Ali, A. Nawaz, M. Usman and A. Husnain. 2023. Determination of biochemical base line of resistance against bacterial leaf spot of chilli after application of plant defense activators. Journal of Global Innovations in Agricultural Sciences, 11: 61-67.
Usman, M., M. Atiq, N. A. Rajput, S. T. Sahi, M. Shad, N. Lili, S. Iqbal, A. M. Arif, U. Ahmad and K. S. Khan. 2024. Efficacy of green synthesized silver based nanomaterials against early blight of tomato caused by Alternaria solani. Journal of Crop Health, 76: 105-15.
Yamamoto, K., Y. Oda, A. Haseda, S. Fujito, T. Mikami and Y. Onodera. 2014. Molecular evidence that the genes for dioecism and monoecism in Spinacia oleracea L. are located at different loci in a chromosomal region. Heredity, 112: 317-24.
DOI: 10.33687/phytopath.013.02.4822
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Copyright (c) 2024 Muhammad Atiq, Sanawar Abbas Shah, Muhammad Muzammil Jahangir, Muhammad Jalal Arif, Muhammad Dildar Gogi, Rashad Waseem Khan, Muhammad Azam, Muhammad Jahanzaib Matloob, Muhammad Idrees
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