Effect of local plant growth promoting rhizobacteria (PGPR) in inhibiting wheat common root rot pathogens

References 1. Aboukhaddour, R., Fetch, T., McCallum, B. D., Harding, M. W., Beres, B. L., & Graf, R. J. (2020). Wheat diseases on the prairies: A Canadian story. Plant Pathology, 69(3), 418-432. . 2. Al-Ahmad, H., Al-Maqtari, Q. A., Al-Hajj, N., & Al-Sheikh, A. (2005). Effect of Fusarium culmorum on yield and yield components of wheat in Syria. Arab Journal of Plant Protection, 23(2), 97-101. 3. Al-Ani R.A., Adhab M.A., Mahdi M.H., Abood H.M. (2012): Rhizobium japonicum as a biocontrol agent of soybean root rot disease caused by Fusarium solani and Macrophomina phaseolina. Plant Protection Science, 48: 149–155 4. Ali, H., Masar, M., Guler, A. C., Urbanek, M., Machovsky, M., & Kuritka, I. (2021). Heterojunction-based photocatalytic nitrogen fixation: principles and current progress. Nanoscale Advances, 3(22), 6358-6372. .5. Al-Sadi, A. M. (2021). Bipolaris sorokiniana-induced black point, common root rot, and spot blotch diseases of wheat: A review. Frontiers in cellular and infection microbiology, 11, 584899. 6. Alström, S., & Burns, R. G. (1989). Cyanide production by rhizobacteria as a possible mechanism of plant growth inhibition. Biology and Fertility of Soils, 7, 232-238. 7. Al-Thawadi, S.M.A. (2011) Ureolytic bacteria and calcium carbonate formation as a mechanism of strength enhancement of sand. Journal of Advanced Science and Engineering Research, 1(1), 98-114 8. Anbu, P., Kang, C. H., Shin, Y. J., & So, J. S. (2016). Formations of calcium carbonate minerals by bacteria and its multiple applications. Springerplus, 5(1), 1-26. 9. Anelise Beneduzi, Adriana Ambrosini and Luciane M.P. Passaglia (2012): Plant growth-promoting rhizobacteria (PGPR): Their potential as antagonists and biocontrol agents. Genetics and Molecular Biology, 35: 1044–1051 10. Bahadur, I., Maurya, R., Roy, P., & Kumar, A. (2019). Potassium-solubilizing bacteria (KSB): a microbial tool for K-solubility, cycling, and availability to plants. Plant Growth Promoting Rhizobacteria for Agricultural Sustainability: From Theory to Practices, 257-265. 11. Baldani, J. I., Reis, V. M., Videira, S. S., Boddey, L. H., & Baldani, V. L. D. (2014). The art of isolating nitrogen-fixing bacteria from non-leguminous plants using N-free semi-solid media: a practical guide for microbiologists. Plant and soil, 384, 413-431. 12. Berde, C. V., Gawde, S. S., & Berde, V. B. (2021). Potassium solubilization: Mechanism and functional impact on plant growth. Soil Microbiomes for Sustainable Agriculture: Functional Annotation, 133-148. 13. Bhavani, S., Singh, P., Qureshi, N., He, X., Biswal, A. K., Juliana, P., Dababat, A., & Mourad, A. M. (2021). Globally important wheat diseases: status, challenges, breeding and genomic tools to enhance resistance durability. Genomic designing for biotic stress resistant cereal crops, 59-128. . 14. Boro, M., Sannyasi, S., Chettri, D., & Verma, A. K. (2022). Microorganisms in biological control strategies to manage microbial plant pathogens: a review. Archives of Microbiology, 204(11), 666. 15. Campanella, V., Mandalà, C., Angileri, V., & Miceli, C. (2020). Management of common root rot and Fusarium foot rot of wheat using Brassica carinata break crop green manure. Crop Protection, 130, 105073.16. Cappuccino, J. G. and N. Sherman.1992. Biochemical activities of microorganisms. In: Microbiology, A Laboratory Manual. The Benjamin / Cummings Publishing Co. California, USA 17. Chandran, H., Meena, M., & Swapnil, P. (2021). Plant growth-promoting rhizobacteria as a green alternative for sustainable agriculture. Sustainability, 13(19), 10986. 18. Collinge, D. B., Jensen, D. F., Rabiey, M., Sarrocco, S., Shaw, M. W., & Shaw, R. H. (2022). Biological control of plant diseases–What has been achieved and what is the direction? Plant Pathology, 71(5), 1024-1047. . 19. Cook, R. J., & Veseth, R. J. (1991). Wheat health management (Plant Health Management Series). American Phytopathological Society Press. 20. Das, B., Sarma, H. K., Konwar, G., Saikia, J., & Rabha, J. (2016). Screening and Identification of traits in plant growth promoting rhizobacteria from rhizospheric soi106erse abosea bo106ombycid106ubterran106ubterranogy and Biochemistry 2(2), 11-18. 21. Dastager, S.G., Deepa. C.K , Pandey A, . 2011. Potential plant growth-promoting activity of Serratia nematodiphila NII-0928 on black pepper (Piper nigrum L.). World J. Microbiol. Biotechnol. 27: 259-265. 22. de Bruijn I., de Kock M.J.D., Yang M., de Waard P., van Beek T.A., Raaijmakers J.M. (2007): Genome-based discovery, structure prediction and functional analysis of cyclic lipopeptide antibiotics in Pseudomonas species. Molecular Microbiology, 63: 417–428 23. Dimkić, I., Janakiev, T., Petrović, M., Degrassi, G., & Fira, D. (2022). Plant-associated Bacillus and Pseudomonas antimicrobial activities in plant disease suppression via biological control mechanisms-A review. Physiological and Molecular Plant Pathology, 117, 101754. 24. Döbereiner J, Pedrosa FO. Nitrogen-fixing bacteria in nonleguminous crop plants. Science & Technology Books. 1995. 25. Döbereiner, J., Baldani, V.L.D. and Baldani, J.I. (1995) Como isolar e identificar bactérias diazotróficas de plantas não-leguminosas. Embrapa-SPI, Brasília 26. Edi-Premono, M., M.A. Moawad, and P.L.G. Vleck (1996). Effect of phosphate solubilizing Pseudomonas putida on the growth of maize and its survival in the rhizosphere. Indonesian J. Crop. Sci.11:13-23. 27. El-Gremi, S. M., Draz, I. S., & Youssef, W. A. E. (2017). Biological control of pathogens associated with kernel black point disease of wheat. Crop Protection, 91, 13-19.28. Erginbas-Orakci, G., Poole, G., Nicol, J. M., Paulitz, T., Dababat, A. A., & Campbell, K. (2016). Assessment of inoculation methods to identify resistance to Fusarium crown rot in wheat. Journal of Plant Diseases and Protection, 123, 19-27. 29. Esther Menendez & Paula Garcia-Fraile (2017). Role of bacterial biofertilizers in agriculture and forestry. AIMS Bioengineering, 4(3), 318-336 30. Etesami, H., Jeong, B. R., & Glick, B. R. (2021). Contribution of arbuscular mycorrhizal fungi, phosphate–solubilizing bacteria, and silicon to P uptake by plant. Frontiers in Plant Science, 12, 699618. . 31. Fahsi, N., Mahdi, I., Mesfioui, A., Biskri, L., & Allaoui, A. (2021). Plant Growth-Promoting Rhizobacteria isolated from the Jujube (Ziziphus lotus) plant enhance wheat growth, Zn uptake, and heavy metal tolerance. Agriculture, 11(4), 316. 32. Fernandez, M. R., Zentner, R. P., DePauw, R. M., Gehl, D., & Stevenson, F. C. (2005). Impacts of crop production factors on common root rot of barley in eastern Saskatchewan. Canadian Journal of Plant Science, 85(3), 645-654 33. Food and Agriculture Organization. (2021). WHEAT. FAO 34. Gao, Q.-M., Zhu, S., Kachroo, P., & Kachroo, A. (2015). Signal regulators of systemic acquired resistance. Frontiers in plant science, 6, 228. 35. George, P., Gupta, A., Gopal, M., Thomas, L., Thomas, G.V. 2013. Multifarious beneficial traits and plant growth promoting potential of Serratia marcescens KiSII and Enterobacter sp. RNF267 isolated from the rhizosphere of coconut palms (Cocos nucifera L.). World J. Microbiol. Biotechnol. 29: 109-117. 36. Gerda, P., Cost, R. N., Kroc, N. P., Neste, E. W.’’& Ph'U’ G.’. (181). Manual of methods for general bacteriology. 37. Govaerts, B., Mezzalama, M., Sayre, K. D., Crossa, J., Nicol, J. M., & Deckers, J. (2006). Long-term consequences of tillage, residue management, and crop rotation on maize/wheat root rot and nematode populations in subtropical highlands. Applied soil ecology, 32(3), 305-315. 38. Grimont, F., Grimont, P.A.D. 2006. The Genus Serratia. In: Dworkin, M., Falkow, S., Rosenberg, E., Schleifer, K-H., Stackebrandt, E. (Eds) The Prokaryotes Volume 6: Proteobacteria: Gamma Subclass, pp. 219-244. 39. Grover, M., Bodhankar, S., Sharma, A., Sharma, P., Singh, J., & Nain, L. (2021). PGPR mediated alterations in root traits: way toward sustainable crop production. Frontiers in Sustainable Food Systems, 4, 618230.40. Gultyaeva, E., Yusov, V., Rosova, M., Mal’chikov, P., Shaydayuk, E., Kovalenko, N., Wanyera, R., Morgounov, A., Yskakova, G., & Rsaliyev, A. (2020). Evaluation of resistance of spring durum wheat germplasm from Russia and Kazakhstan to fungal foliar pathogens. Cereal research communications, 48, 71-79. 41. Gupta, D., & Sinha, S. N. (2020). Production of Hydrogen Cyanide (HCN) by Purple Non-Sulfur Bacterium Isolated from the Rice Field of West Bengal. 15(1 Ser. III), 16-26. . 42. Hafeez, F. Y., S. Asad, T. Ahmad and K. A. Malik. 2005. Host specificity and characterization of fast 43. Harrigan, W.F. (1998). Laboratory Methods in Food Microbiology. 3rd Edition. Gulf Professional Publishing 44. Hazard, B., Trafford, K., Lovegrove, A., Griffiths, S., Uauy, C., & Shewry, P. (2020). Strategies to improve wheat for human health. Nature Food, 1(8), 475-480. . 45. He, D. C., He, M. H., Amalin, D. M., Liu, W., Alvindia, D. G., & Zhan, J. (2021). Biological control of plant diseases: An evolutionary and eco-economic consideration. Pathogens, 10(10), 1311. 46. He, D. C., He, M. H., Amalin, D. M., Liu, W., Alvindia, D. G., & Zhan, J. (2021). Biological control of plant diseases: An evolutionary and eco-economic consideration. Pathogens, 10(10), 1311. 47. Herrera, S. D., Grossi, C., Zawoznik, M., & Groppa, M. D. (2016). Wheat seeds harbour bacterial endophytes with potential as plant growth promoters and biocontrol agents of Fusarium graminearum. Microbiological Research, 186, 37-43. 48. Hugh, R. and Leifson, E. (1953). The taxonomic significance of fermentative versus oxidative metabolism of carbohydrates by various gram negative bacteria. Journal of Bacteriology, 66(1), 24-26 49. Hulot, J.F. and Hiller, N. (2021) ‘Exploring the benefits of biocontrol for sustainable agriculture – A literature review on biocontrol in light of the European Green Deal’, Institute for European Environmental Policy. 50. Igrejas, G., & Branlard, G. (2020). The importance of wheat. Wheat quality for improving processing and human health, 1-7. 51. Jadoon, S., Afzal, A., Asad, S., Sultan, T., Tabassam, T., Umer, M., & Asif, M. (2019). Plant growth promoting traits of rhizobacteria isolated from potato (Solanum tuberosum L.) and their antifungal activity against Fusarium oxysporum. JAPS: Journal of Animal & Plant Sciences, 29 ( 4 ).52. Jamil Shafi, Hui Tian, Mingshan Ji (2017): Bacillus species as versatile weapons for plant pathogens: a review, Biotechnology & Biotechnological Equipment, DOI 53. Jeyanthi, V., & Kanimozhi, S. (2018). Plant growth promoting rhizobacteria (PGPR)-prospective and mechanisms: a review. J Pure Appl Microbiol, 12(2), 733-749. 54. Jha, C. K., Aeron, A., Patel, B. V., Maheshwari, D. K., & Saraf, M. (2011). Enterobacter: role in plant growth promotion. Bacteria in agrobiology: Plant growth responses, 159-182. . 55. Jiao, X., Takishita, Y., Zhou, G., & Smith, D. L. (2021). Plant associated rhizobacteria for biocontrol and plant growth enhancement. Frontiers in plant science, 12, 634796. 56. Kageyama, K., & Nelson, E. B. (2003). Differential inactivation of seed exudate stimulation of Pythium ultimum sporangium germination by Enterobacter cloacae influences biological control efficacy on different plant species. Applied and Environmental Microbiology, 69(2), 1114-1120. 57. Kayim, M., Nawaz, H., & Alsalmo, A. (2022). Fungal diseases of wheat. In Wheat. IntechOpen.. . (2nd ed., pp. 123-145) 58. Kazan, K., & Gardiner, D. M. (2018). Fusarium crown rot caused by Fusarium pseudograminearum in cereal crops: recent progress and future prospects. Molecular plant pathology, 19(7), 1547-1562. 59. Kazan, K., & Gardiner, D. M. (2018). Fusarium crown rot caused by Fusarium pseudograminearum in cereal crops: recent progress and future prospects. Molecular plant pathology, 19(7), 1547-1562. 60. Keet, C. A., Matsui, E. C., Dhillon, G., Lenehan, P., Paterakis, M., & Wood, R. A. (2009). The natural history of wheat allergy. Annals of Allergy, Asthma & Immunology, 102(5), 410-415. 61. Kenawy, A., Dailin, D. J., Abo-Zaid, G. A., Malek, R. A., Ambehabati, K. K., Zakaria, K. H. N., Sayyed, R., & El Enshasy, H. A. (2019). Biosynthesis of antibiotics by PGPR and their roles in biocontrol of plant diseases. Plant Growth Promoting Rhizobacteria for Sustainable Stress Management: Volume 2: Rhizobacteria in Biotic Stress Management, 1-35. 62. Kerdraon, L., Laval, V., & Suffert, F. (2019). Microbiomes and pathogen survival in crop residues, an ecotone between plant and soil. Phytobiomes Journal, 3(4), 246-255. 63. Khamna, S., Yokota, A. and Lumyong, S. (2010) Indole-3-acetic acid production by Streptomyces sp. isolated from some Thai medicinal plant rhizosphere soils. European Journal of Soil Biology, 46(1), 73-7764. Khan, M.S.; Zaidi, A.; Ahemad, M.; Oves, M.; Wani, P.A. Plant growth promotion by phosphate solubilizing fungi—Current perspective. Arch. Agron. Soil Sci. 2010, 56, 73–98 65. Kirk, J. L., Beaudette, L. A., Hart, M., Moutoglis, P., Klironomos, J. N., Lee, H., & Trevors, J. T. (2004). Methods of studying soil microbial diversity. Journal of microbiological methods, 58(2), 169-188. . 66. Kloepper, J. W., Schroth, M. N. (1981). Plant Growth-Promoting Rhizobacteria and Plant Growth Under Gnotobiotic Conditions. Phytopathology, 71(6), 642-644. . 67. Köhl, J., Kolnaar, R., & Ravensberg, W. J. (2019). Mode of action of microbial biological control agents against plant diseases: relevance beyond efficacy. Frontiers in plant science, 845. 68. Kolomiiets, Y., Grigoryuk, I., Likhanov, A., Butsenko, L., Pasichnyk, L., & Blume, Y. (2020). Induction of Wheat Resistance against the Causative Agent of Basal Bacteriosis with Growth-Promoting Bacteria. Cytology and Genetics, 54, 514-521. . 69. KoTova, G. N. (1979). Effect of crop rotation on the development of root rot of wheat. Khimiya sel’skogo khozyaistva, 17(6), 44-47. 70. Kour, D., Rana, K. L., Kaur, T., Yadav, N., Halder, S. K., Yadav, A. N., Sachan, S. G., & Saxena, A. K. (2020). Potassium solubilizing and mobilizing microbes: biodiversity, mechanisms of solubilization, and biotechnological implication for alleviations of abiotic stress. In New and future developments in microbial biotechnology and bioengineering (pp. 177-202). Elsevier. . 71. Kremer, R. J. (2006). Deleterious rhizobacteria. In Plant-associated bacteria (pp. 335-357). Springer. 72. Kshetri, L., Naseem, F., & Pandey, P. (2019). Role of Serratia sp. as biocontrol agent and plant growth stimulator, with prospects of biotic stress management in plant. Plant Growth Promoting Rhizobacteria for Sustainable Stress Management: Volume 2: Rhizobacteria in Biotic Stress Management, 169-200. 73. Kumar, A., Bennetzen, J. L., Simpson, C. E., & Peterson, D. G. (2002). Genetic mapping of peanut (Arachis hypogaea L.) using fluorescence in situ hybridization (FISH). Theoretical and Applied Genetics, 105(4), 485-490 74. Kumar, J., Schäfer, P., Hückelhoven, R., Langen, G., Baltruschat, H., Stein, E., … & Kogel, K. H. (2017). Bipolaris sorokiniana, a cereal pathogen of global concern: cytological and molecular approaches towards better control. Molecular plant pathology, 18(4), 518-534.75. Kumar, K., Pal, G., Verma, A., & Verma, S. K. (2020). Seed inhabiting bacterial endophytes of finger millet (Eleusine coracana L.) promote seedling growth and development, and protect from fungal disease. South African journal of botany, 134, 91-98. 76. Labuschagne, N., Pretorius, T., Idris, A.H. (2010). Plant Growth Promoting Rhizobacteria as Biocontrol Agents Against Soil-Borne Plant Diseases. In: Maheshwari, D. (eds) Plant Growth and Health Promoting Bacteria. Microbiology Monographs, vol 18. Springer, Berlin, Heidelberg. 3. 77. Lane DJ (1991) 16S/23S rRNA sequencing. In: Stackebrandt E, Goodfellow M (eds) Nucleic acid techniques in bacterial systematics. Wiley, New York, pp 115–175. 78. Larsen, J., Jaramillo-López, P., Nájera-Rincon, M., & González-Esquivel, C. E. (2015). Biotic interactions in the rhizosphere in relation to plant and soil nutrient dynamics. Journal of soil science and plant nutrition, 15(2), 449-463. 79. Latha, P., Karthikeyan, M., & Rajeswari, E. (2019). Endophytic bacteria: prospects and applications for the plant disease management. Plant Health Under Biotic Stress: Volume 2: Microbial Interactions, 1-50. 80. Lebrazi, S., Niehaus, K., Bednarz, H., Fadil, M., Chraibi, M., & Fikri-Benbrahim, K. (2020). Screening and optimization of indole-3-acetic acid production and phosphate solubilization by rhizobacterial strains isolated from Acacia cyanophylla root nodules and their effects on its plant growth. Journal of Genetic Engineering and Biotechnology, 18, 1-12. 81. Leite, M. C. D. B. S., Pereira, A. P. D. A., Souza, A. J. D., Andreote, F. D., Freire, F. J., & Sobral, J. K. (2018). Bioprospection and genetic diversity of endophytic bacteria associated with cassava plant. Revista Caatinga, 31, 315-325. 82. Lemmens, M., Haim, K., Lew, H., & Ruckenbauer, P. (2004). The effect of nitrogen fertilization on Fusarium head blight development and deoxynivalenol contamination in wheat. Journal of Phytopathology, 152(1), 1-8. 83. Leontidou, K., Genitsaris, S., Papadopoulou, A., Kamou, N., Bosmali, I., Matsi, T., Madesis, P., Vokou, D., Karamanoli, K., & Mellidou, I. (2020). Plant growth promoting rhizobacteria isolated from halophytes and drought-tolerant plants: Genomic characterisa111ubterranean111iontion of phyto-beneficial traits. Scientific reports, 10(1), 1-15.84. Leslie, J. F., & Summerell, B. A. (2006). The Fusarium laboratory manual. John Wiley & Sons. 85. Liu, J., Elad, Y., Ziv, O., & Peretz-Alon, I. (2012). Effect of postharvest temperature and duration of storage on development of strawberry fruit rot caused by Rhizoctonia Spp. and Fusarium spp. Postharvest Biology and Technology, 64(1), 40-47. 86. Lucena, J. J., & Hernandez-Apaolaza, L . ( 2017 ). Iron nutrition in plants: an overview . Plant and Soil, 418, 1-4. 87. Macedo-Raygoza, G. M., Valdez-Salas, B., Prado, F. M., Prieto, K. R., Yamaguchi, L. F., Kato, M. J., Canto-Canché, B. B., Carrillo-Beltrán, M., Di Mascio, P., & White, J. F. (2019). Enterobacter cloacae, an endophyte that establishes a nutrient-transfer symbiosis with banana plants and protects against the black Sigatoka pathogen. Frontiers in microbiology, 10, 804. 88. Mahdi, I.; Fahsi, N.; Hafidi, M.; Allaoui, A.; Biskri, L. Plant Growth Enhancement using Rhizospheric Halotolerant Phosphate Solubilizing Bacterium Bacillus licheniformis QA1 and Enterobacter asburiae QF11 Isolated from Chenopodium quinoa Willd. Microorganisms 2020, 8, 948. 89. Maksimov I.V., Abizgil’dina R.R., Pusenkova L.I. (2011): Plant growth promoting rhizobacteria as alternative to chemical crop protectors from pathogens (review). Applied Biochemistry and Microbiology, 47: 333–345 90. Manib, M., Blagodyr, R.N., Ilev, I.P. (1986) Liberation of phosphoric acid from apatite by silicate bacteria. Mikrobiolohichnyi Zhurnal (Kiev), 29(2), 111-114 91. Martinez-Viveros, O., Jorquera, M.A., Crowley, D.E., Gajardo, G., Mora, M.L. 2010. Mechanisms and practical considerations involved in plant growth promotion by rhizobacteria. J. Soil Sci. Plant Nutr. 10: 293-319. 92. Mavrodi, O. V., Walter, N., Elateek, S., Taylor, C. G., & Okubara, P. A. (2012). Suppression of Rhizoctonia and Pythium root rot of wheat by new strains of Pseudomonas. Biological Control, 62(2), 93-102. 93. Mazzola, M., Zhao, X., Sackett, K., & Liu, Y. (2019). Genetic variation in the response of wheat to soil infestation with the fungal pathogen Rhizoctonia solani AG8. Plant and Soil, 437(1-2), 1-14 94. Mehrabi, F., Sepaskhah, A. R., & Ahmadi, S. H. (2021). Winter wheat root distribution with irrigation, planting methods, and nitrogen application. Nutrient Cycling in Agroecosystems, 119, 231-245.95. Mehta, R. D., & Gaudencio, C. A. (1990). Effect of crop rotation on the incidence of Fusarium root rot in wheat and barley in Saskatchewan. Canadian Journal of Plant Pathology, 12(3), 237-242. 96. Mittal, V.; Singh, O.; Nayyar, H.; Kaur, J.; Tewari, R. Stimulatory effect of phosphate-solubilizing fungal strains (Aspergillus awamori and Penicillium citrinum) on the yield of chickpea (Cicer arietinum L. cv. GPF2). Soil Biol. Biochem. 2008, 40, 718–727. 97. Mohamed, A. E., Nessim, M. G., Abou-el-seoud, I. I., Darwish, K. M., & Shamseldin, A. (2019). Isolation and selection of highly effective phosphate solubilizing bacterial strains to promote wheat growth in Egyptian calcareous soils. Bulletin of the National Research Centre, 43(1), 1-13. . 98. Mohan, A., Schillinger, W. F., & Gill, K. S. (2013). Wheat seedling emergence from deep planting depths and its relationship with coleoptile length. PLos One, 8(9), e73314. 99. Monjezi, F., Vazin, F., & Hassanzadehdelouei, M. (2012). Effects of iron and zinc spray on yield and yield components of wheat (Triticum aestivum L.) in drought stress. 29: 109-117. 100. Mousa, W. K., Shearer, C., Limay-Rios, V., Ettinger, C. L., Eisen, J. A., & Raizada, M. N. (2016). Root-hair endophyte stacking in finger millet creates a physicochemical barrier to trap the fungal pathogen Fusarium graminearum. Nature microbiology, 1(12), 1-12. . 101. Mulk, S., Wahab, A., Yasmin, H., Mumtaz, S., El-Serehy, H., Khan, N., & Hassan, M. (2021). Prevalence of wheat associated Bacillus Spp. and their bio-control efficacy against fusarium root rot. Front Microbiol 12: 798619. 102. Murray, G. M., & Brennan, J. P. (2009). Estimating disease losses to the Australian wheat industry. Australasian Plant Pathology, 38(6), 558-570 103. Nandi, M., Selin, C., Brawerman, G., Fernando, W. D., & de Kievit, T. (2017). Hydrogen cyanide, which contributes to Pseudomonas chlororaphis strain PA23 biocontrol, is upregulated in the presence of glycine. Biological Control, 108, 47-54. 104. Navarro, M. O., Simionato, A. S., Barazetti, A. R., dos Santos, I. M., Cely, M. V., Chryssafidis, A. L., & Andrade, G. (2017). Disease-induced resistance and plant immunization using microbes. Plant-Microbe Interactions in Agro-Ecological Perspectives: Volume 1: Fundamental Mechanisms, Methods and Functions, 447-465. . 105. O’Brien, P. A. (2017). Biological control of plant diseases. Australasian Plant Pathology, 46, 293-304. 106. OECD/FAO. (2020). OECD-FAO agricultural outlook 2020–2029. Oecd. .107. Oklahoma State University. (2020). Root rots on wheat. Plant Disease and Insect Diagnostic Laboratory, https://extension.okstate.edu/programs/digital-diagnostics/plant-diseases/root-rots-on-wheat.html. 108. Ovsyankina, A., Savchenko, I., Sanin, S., Semigonov, A., Kornyukov, D., & Gerner, A. (2019). Diagnosis of soil fungi that cause root rot. IOP Conference Series: Earth and Environmental Science, , 109. Özer, G., Erper, İ., Yıldız, Ş., Bozoğlu, T., Zholdoshbekova, S., Alkan, M., Tekin, F., Uulu, T. E., İmren, M., & Dababat, A. A. (2023). Fungal Pathogens Associated with Crown and Root Rot in Wheat-Growing Areas of Northern Kyrgyzstan. Journal of Fungi, 9(1), 124. 110. Özer, G., Paulitz, T. C., Imren, M., Alkan, M., Muminjanov, H., & Dababat, A. A. (2020). Identity and pathogenicity of fungi associated with crown and root rot of dryland winter wheat in Azerbaijan. Plant Disease, 104(8), 2149-2157. 111. Pal, K. K., & Gardener, B. M. (2006). Biological control of plant pathogens. 4-5 112. Pathania, P., Rajta, A., Singh, P. C., & Bhatia, R. (2020). Role of plant growth-promoting bacteria in sustainable agriculture. Biocatalysis and Agricultural Biotechnology, 30, 101842. 113. Pérez-Flores, P.; Valencia-Cantero, E.; Altamirano-Hernández, J.; Pelagio-Flores, R.; López-Bucio, J.; García-Juárez, P.; Macías-Rodríguez, L. Bacillus methylotrophicus M4-96 isolated from maize (Zea mays) rhizoplane increases growth and auxin content in Arabidopsis thaliana via emission of volatiles. Protoplasma 2017, 254, 2201–2213 114. Pérez-Montaño, F.; Alías-Villegas, C.; Bellogín, R.; del Cerro, P.; Espuny, M.; Jiménez-Guerrero, I.; López-Baena, F.; Ollero, F.; Cubo, T. Plant growth promotion in cereal and leguminous agricultural important plants: From microorganism capacities to crop production. Microbiol. Res. 2014, 169, 325–336 115. Peris-Peris, C., Serra-Cardona, A., Sánchez-Sanuy, F., Campo, S., Ariño, J., & San Segundo, B. (2017). Two NRAMP6 isoforms function as iron and manganese transporters and contribute to disease resistance in rice. Molecular Plant-Microbe Interactions, 30(5), 385-398. 116. Petersen, L.M., Tisa, L.S. 2013. Friend or foe? A review of the mechanisms that drive Serratia towards diverse lifestyles. Can. J. Microbiol. 59: 627-640. 117. Pikovskaya, R. (1948). Mobilization of phosphorus in soil in connection with the vital activity of some microbial species. Microbiologiya, 17, 362-370118. Preece, C., & Penuelas, J. (2016). Rhizodeposition under drought and consequences for soil communities and ecosystem resilience. Plant and Soil, 409, 1-17. 119. Prins, T. W., Wagemakers, L., Schouten, A., & van Kan, J. A. (2000). Cloning and characterization of a glutathione S-transferase homologue from the plant pathogenic fungus Alternaria alternata. Molecular plant-microbe interactions, 13(7), 769-780. 120. Qu, X., & Christ, B. J. (2006). The host range of Spongospora subterr115ubterranean115ubterraneanerranea 115ubterraneaned States and its potential for biological control using a fungal antagonist or a plant decoy. Australasian Plant Pathology, 35(4), 419-427. 121. Raaijmakers J.M., De Bruijn I., Nybroe O., Ongena M. (2010): Natural functions of lipopeptides from Bacillus and Pseudomonas: more than surfactants and antibiotics. FEMS Microbiology Reviews, 34: 1037–1062 122. Rajput, M. A., Pathan, M. A., Lodhi, A. M., Shah, G. S., & Khanzada, K. A. (2005). Studies on seed-borne fungi of wheat in Sindh Province and their effect on seed germination. Pakistan Journal of Botany, 37(1), 181-185. 123. Ranawat, B., Mishra, S., & Singh, A. (2021). Enterobacter hormaechei (MF957335) enhanced yield, disease and salinity tolerance in tomato. Archives of microbiology, 203, 2659-2667. 124. Rawat, P., Das, S., Shankhdhar, D., & Shankhdhar, S. (2021). Phosphate-solubilizing microorganisms: mechanism and their role in phosphate solubilization and uptake. Journal of Soil Science and Plant Nutrition, 21, 49-68. 125. Root Rots on Wheat | Oklahoma State University - –SU E–tens–on. (2021). Root Rots on Wheat. OSU Extension. https://extension.okstate.edu/programs/digital-diagnostics/plant-diseases/root-rots-on-wheat.html 126. Saad, A., Macdonald, B., Martin, A., Knight, N. L., & Percy, C. (2021). Comparison of disease severity caused by four soil-borne pathogens in winter cereal seedlings. Crop and Pasture Science, 72(5), 325-334. 127. Saad, M., Alshehri, Y., Alnazzawi, N., Alsibiani, S., & Alsobhi, S. (2023). NIST and University Researchers Offer Future 6G Network Concept. NIST News 128. Saeed, S., Ahmad, R., Ali, A., Khan, M. A., & Iqbal, M. (2021). Pseudomonas Spp. inhibit Rhizoctonia solani and improve wheat yield. Journal of Plant Protection Research, 61(1), 3-11129. Saitou N. and Nei M. (1987). The neighbor-joining method: A new method for reconstructing phylogenetic trees. Molecular Biology and Evolution 4:406-425. 130. Saleemi, M., Kiani, M. Z., Sultan, T., Khalid, A., & Mahmood, S. (2017). Integrated effect of plant growth-promoting rhizobacteria and phosphate-solubilizing microorganisms on growth of wheat (Triticum aestivum L.) under rainfed condition. Agriculture & Food Security, 6(1), 1-8. 131. Savary, S., Willocquet, L., Pethybridge, S. J., Esker, P., McRoberts, N., & Nelson, A. (2019). The global burden of pathogens and pests on major food crops. Nature ecology & evolution, 3(3), 430-439. 132. Scardaci, S. C., & Webster, R. K. (1982). Root rot of wheat caused by Fusarium culmorum in California. Plant Disease, 66(1), 12-14 133. Scherm, B., Balmas, V., Spanu, F., Pani, G., Delogu, G., Pasquali, M., & Migheli, Q. (2013). F usarium culmorum: Causal agent of foot and root rot and head blight on wheat. Molecular plant pathology, 14(4), 323-341. . 134. Sehrawat, A., Sindhu, S. S., & Glick, B. R. (2022). Hydrogen cyanide production by soil bacteria: Biological control of pests and promotion of plant growth in sustainable agriculture. Pedosphere, 32(1), 15-38. . 135. Selvakumar, G.; Mohan, M.; Kundu, S.; Gupta, A.; Joshi, P.; Nazim, S.; Gupta, H. Cold tolerance and plant growth promotion potential of Serratia marcescens strain SRM (MTCC 8708) isolated from flowers of summer squash (Cucurbita pepo). Lett. Appl. Microbiol. 2007, 46, 171–175. 136. Shabbir, I., Abd Samad, M. Y., Othman, R., Wong, M.-Y., Sulaiman, Z., Jaafar, N. M., & Bukhari, S. A. H. (2021). Evaluation of bioformulation of Enterobacter sp. UPMSSB7 and mycorrhizae with silicon for white root rot disease suppression and growth promotion of rubber seedlings inoculated with Rigidoporus microporus. Biological Control, 152, 104467. 137. Shah, A., Nazari, M., Antar, M., Msimbira, L. A., Naamala, J., Lyu, D., Rabileh, M., Zajonc, J., & Smith, D. L. (2021). PGPR in agriculture: A sustainable approach to increasing climate change resilience. Frontiers in Sustainable Food Systems, 5, 667546. 138. Sharma, I. P., & Sharma, A. K. (2019). Trichoderma–Fusarium interactions: A biocontrol strategy to manage wilt diseases in plants. In Rhizosphere Biology (pp. 165-184).139. Sharma, S., Pahwa, S., Bhati, S., & Kudeshia, P. (2020). Spanlastics: A modern approach for nanovesicular drug delivery system. International Journal of Pharmaceutical Sciences and Research, 11(3), 1057-1065 140. Sharma-Poudyal, D., Schlatter, D., Yin, C., Hulbert, S., & Paulitz, T. C. (2018). Mechanisms of seedling resistance to Rhizoctonia solani AG-8 in wheat. Frontiers in plant science, 9, 1116. 141. Shewry, P. R. (2009). Wheat. Journal of Experimental Botany, 60(6), 1537-1553. 142. Shikur Gebremariam, E., Sharma-Poudyal, D., Paulitz, T., Erginbas-Orakci, G., Karakaya, A., & Dababat, A. (2018). Identity and pathogenicity of Fusarium species associated with crown rot on wheat (Triticum spp.) in Turkey. 143. Singh, D. (2015). Plant nutrition in the management of plant diseases with particular reference to wheat. Recent advances in the diagnosis and management of plant diseases, 273-284. 144. Singh, D., Singh, S. K., Singh, V. K., Ghosh, S., Verma, H., & Kumar, A. (2021). Plant growth promoting bacteria as biocontrol agents against diseases of cereal crops. In Food Security and Plant Disease Management (pp. 221-239). Elsevier. . 145. Singh, J., Chhabra, B., Raza, A., Yang, S. H., & Sandhu, K. S. (2022). Important wheat diseases in the US and their management in the 21st century. Frontiers in Plant Science, 13. . 146. Singh, P., Chauhan, P. K., Upadhyay, S. K., Singh, R. K., Dwivedi, P., Wang, J., Jain, D., & Jiang, M. (2022). Mechanistic insights and potential use of siderophores producing microbes in rhizosphere for mitigation of stress in plants grown in degraded land. Frontiers in Microbiology, 13, 898979. 147. Singh, R.P., Jha, P.N. 2016. The multifarious PGPR Serratia marcescens CDP-13 augments induced systemic resistance and enhanced salinity tolerance of wheat (Triticum aestivum L.). PLoS ONE 11 148. Simpfendorfer, S., McKay, A., & Ophel-Keller, K. (2020). New approaches to crop disease management in conservation agriculture. Australian agriculture in, 173-188. 149. Smiley, R. W., Gourlie, J. A., Easley, S. A., Patterson, L. M., & Whittaker, R. G. (2005). Crop damage estimates for crown rot of wheat and barley in the Pacific Northwest. Plant Disease, 89(6), 595-604. 150. Soul-kifouly, G. M., Muriithi, B. W., Affognon, H. D., Macharia, I., & Le Ru, B. P. (2021). Economic impact of biological control. Biological Control: Global Impacts, Challenges and Future Directions of Pest Management, 1928.151. Stack Exchange Chemistry. (2015, November 16). Preparation of picric acid. Retrieved from [https://chemistry.stackexchange.com/questions/44090/preparation-of-picric-acid]. 152. Stack, R. W. (1994). Fusarium head blight of wheat and barley: losses and control costs in the United States. In Proceedings of the 3rd International Wheat Scab Symposium (pp. 1-4) 153. Stenberg, J. A., Sundh, I., Becher, P. G., Björkman, C., Dubey, M., Egan, P. A., Friberg, H., Gil, J. F., Jensen, D. F., & Jonsson, M. (2021). When is it biological control? A framework of definitions, mechanisms, and classifications. Journal of Pest Science, 94(3), 665-676. 154. Su, J., Zhao, J., Zhao, S., Li, M., Pang, S., Kang, Z., Zhen, W., Chen, S., Chen, F., & Wang, X. (2021). Genetics of resistance to common root rot (spot blotch), Fusarium crown rot, and sharp eyespot in wheat. Frontiers in Genetics, 12, 699342. 155. Sun, Z., Yue, Z., Liu, H., Ma, K., & Li, C. (2021). Microbial-assisted wheat iron biofortification using endophytic Bacillus altitudinis WR10. Frontiers in Nutrition, 8, 704030. 156. Suslow, T.V., Schroth, M.N. and Isaka, M. (1982) Application of a Rapid Method for Gram Differentiation of Plant Pathogenic and Saprophytic Bacteria without Staining. Phytopathology, 72, 917-918 157. Tamura, K., Stecher, G., & Kumar, S. (2021). MEGA11: molecular evolutionary genetics analysis version 11. Molecular biology and evolution, 38(7), 3022-3027. . 158. Tupenevich, V. A., & Volchova, L. A. (1977). Effect of crop rotation on the development of root rot of wheat and barley. Zashchita Rastenii, 22(11), 37-38. 159. Ullah, H., Yasmin, H., Mumtaz, S., Jabeen, Z., Naz, R., Nosheen, A., & Hassan, M. N. (2020). Multitrait Pseudomonas Spp. isolated from monocropped wheat (Triticum aestivum) suppress Fusarium root and crown rot. Phytopathology, 110(3), 582-592. 160. van Lenteren, J. C., Bueno, V., & Klapwijk, J. N. (2021). Augmentative biological control. Biological Control: Global Impacts, Challenges and Future Directions of Pest Management; Mason, PG, Ed, 90-109. . 161. Verma S, Varma A, Rexer K, Hassel A, Kost G, Sarbhoy A, Bisen P, Bütehorn B, Franken P. Piriformospora indica, gen. et sp. nov, a New root-colonizing fungus. Mycologia 1998; 90:896 – 903 162. Wahyudi A.T., Astuti R.P., Widyawati A., Meryandini A., Nawangsih A.A. (2011): Characterization of Bacillus sp. strains isolated from rhizosphere of soybean plants for theiruse as potential plant growth for promoting rhizobacteria. Journal of Microbiology and Antimicrobials, 3: 34–40 163. Waller F, Achatz B, Baltruschat H, Fodor J, Becker K, Fischer M, Heier T, Hückelhoven R, Neumann C, von Wettstein D, et al. The endophytic fungus Piriformospora indica reprograms barley to salt-stress tolerance, disease resistance, and higher yield. Proc Natl Acad Sci U S A 2005; 102:13386 - –1 164. Wang, W., Zhao, J., & Zhang, Z. (2022). Bacillus Metabolites: Compounds, Identification and Anti-Candida albicans Mechanisms. Microbiology Research, 13(4), 972-984. 165. Wang, Z., Zhang, H., Liu, L., Li, S., Xie, J., Xue, X., & Jiang, Y. (2022). Screening of phosphate-solubilizing bacteria and their abilities of phosphorus solubilization and wheat growth promotion. BMC microbiology, 22(1), 296. 166. Wei, X., Xu, Z., Zhang, N., Yang, W., Liu, D., & Ma, L. (2021). Synergistic action of commercially available fungicides for protecting wheat from common root rot caused by Bipolaris sorokiniana in China. Plant Disease, 105(3), 667-674. 167. Wildermuth, G., & McNamara, R. (1994). Testing wheat seedlings for resistance to crown rot caused by Fusarium graminearum Group 1. . 168. Wilkins, N. (1952). The assimilation of iron by bacteria. Australian Journal of Scientific Research B Biological Sciences, 5(4), 449-468 169. Williamson-Benavides, B. A., & Dhingra, A. (2021). Understanding root rot disease in agricultural crops. Horticulturae, 7(2), 33. . 170. Winter, M., Samuels, P. L., Otto-Hanson, L. K., Dill-Macky, R., & Kinkel, L. L. (2019). Biological control of Fusarium crown and root rot of wheat by Streptomyces isolates–it’s complicated. Phytobiomes Journal, 3(1), 52-60. . 171. Wu, Y., Zhang, Z., Li, Y., & Li, Y. (2022). The regulation of integrated stress response signaling pathway on viral infection and viral antagonism. Frontiers in Microbiology, 12, 814635. 172. Xiao, K., Chen, X., & Shaner, G. (1998). Occurrence of Fusarium crown rot of wheat in China and its effects on yield and quality of grain. Plant Disease, 82(9), 1017-1020. 173. Yin, C., Hagerty, C. H., & Paulitz, T. C. (2022). Synthetic microbial consortia derived from rhizosphere soil protect wheat against a soilborne fungal pathogen. Frontiers in Microbiology, 13, 908981. 174. Zablotowicz, R. M., Tipping, E. M., Lifshitz, R., & Kloepper, J. W. (1991). Plant growth promotion mediated by bacterial rhizosphere colonizers. The Rhizosphere and PlantGrowth: Papers presented at a Symposium held May 8 –11, 1989, at the Beltsville Agricultural Research Center (BARC), Beltsville, Maryland. . 175. Zaharieva, M., & Monneveux, P. (2014). Cultivated einkorn wheat (Triticum monococcum L. subsp. monococcum): the long life of a founder crop of agriculture. Genetic resources and crop evolution, 61, 677-706. 176. Zahir, Z. A., Ghani, U., Naveed, M., Nadeem, S. M., & Asghar, H. N. (2009). Comparative effectiveness of Pseudomonas and Serratia sp. containing AcC-deaminase for improving growth and yield of wheat (Triticum aestivum L.) under salt-stressed conditions. Archives of Microbiology, 191, 415-424. 177. Zhang, Y., Wang, J., Li, X., Liu, Y., & Zhao, K. (2022). Effect of fungicides and biocontrol agents on root and crown rot of wheat caused by Rhizoctonia solani and Fusarium graminearum in China. Plant Disease, 106(1), 123-130.