style="font-size:15px;"> 19 19 Amadou, M., Duponnois, R., and Marseille, T. (1999). Beneficial effects of Enterobacter cloacae and Pseudomonas mendocina for biocontrol of Meloidogyne incognita with the endospore-forming bacterium Pasteuria penetrans. Nematology Jan 1 1 (1): 95–101.20 20 Haas, D. and Keel, C. (2003). Regulation of antibiotic production in root-colonizing Pseudomonas spp. and relevance for biological control of plant disease. Annual Review of Phytopathology Sep 41 (1): 117–153.
21 21 Tsuge, K., Akiyama, T., and Shoda, M. (2001). Cloning, sequencing, and characterization of the iturin A operon. Journal of Bacteriology Nov 1 183 (21): 6265–6273.
22 22 Steller, S., Vollenbroich, D., Leenders, F., Stein, T., Conrad, B., Hofemeister, J., Jacques, P., Thonart, P., and Vater, J. (1999). Structural and functional organization of the fengycin synthetase multienzyme system from Bacillus subtilis b213 and A1/3. Chemistry & Biology Jan 1 6 (1): 31–41.
23 23 Raaijmakers, J.M., Paulitz, T.C., Steinberg, C., Alabouvette, C., and Moënne-Loccoz, Y. (2009). The rhizosphere: A playground and battlefield for soilborne pathogens and beneficial microorganisms. Plant and Soil Aug 321 (1): 341–361.
24 24 Asaka, O. and Shoda, M. (1996). Biocontrol of Rhizoctonia solani damping-off of tomato with Bacillus subtilis RB14. Applied and Environmental Microbiology Nov 1 62 (11): 4081–4085.
25 25 Couillerot, O., Prigent-Combaret, C., Caballero-Mellado, J., and Moënne-Loccoz, Y. (2009). Pseudomonas fluorescens and closely-related fluorescent Pseudomonads as biocontrol agents of soilborne phytopathogens. Letters in Applied Microbiology May 48 (5): 505–512.
26 26 Guo, Q., Shi, M., Chen, L., Zhou, J., Zhang, L., Li, Y., Xue, Q., and Lai, H. (2020). The biocontrol agent Streptomyces pactum increases Pseudomonas koreensis populations in the rhizosphere by enhancing chemotaxis and biofilm formation. Soil Biology & Biochemistry May 1 144: 107755.
27 27 Rezzonico, F., Binder, C., Défago, G., and Moënne-Loccoz, Y. (2005). The type III secretion system of biocontrol Pseudomonas fluorescens KD targets the phytopathogenic Chromista Pythium ultimum and promotes cucumber protection. Molecular Plant–Microbe Interactions Sep 18 (9): 991–1001.
28 28 Vacheron, J., Moënne-Loccoz, Y., Dubost, A., Gonçalves-Martins, M., Müller, D., and Fluorescent, P.-C.-C. (2016). Pseudomonas strains with only few plant-beneficial properties are favored in the maize rhizosphere. Frontiers in Plant Science Aug 25 7: 1212.
29 29 Pieterse, C.M., Zamioudis, C., Berendsen, R.L., Weller, D.M., Van Wees, S.C., and Bakker, P.A. (2014). Induced systemic resistance by beneficial microbes. Annual Review of Phytopathology Aug 4 52.
30 30 Pascale, A., Proietti, S., Pantelides, I.S., and Stringlis, I.A. (2020). Modulation of the root microbiome by plant molecules: The basis for targeted disease suppression and plant growth promotion. Frontiers in Plant Science Jan 24 (10): 1741.
31 31 Harman, G.E., Björkman, T., Ondik, K., and Shoresh, M. (2008). Changing paradigms on the mode of action and uses of Trichoderma spp. for biocontrol. Outlooks on Pest Management Feb 1 19 (1): 24.
32 32 Weller, D.M., Raaijmakers, J.M., Gardener, B.B., and Thomashow, L.S. (2002). Microbial populations responsible for specific soil suppressiveness to plant pathogens. Annual Review of Phytopathology Sep 40 (1): 309–348.
33 33 Kwak, M.J., Kong, H.G., Choi, K., Kwon, S.K., Song, J.Y., Lee, J., Lee, P.A., Choi, S.Y., Seo, M., Lee, H.J., and Jung, E.J. (2018). Author correction: Rhizosphere microbiome structure alters to enable wilt resistance in tomato (Nat. Biotechnology 36 (11): (1100–1116). 10.1038/nbt. 4232). Nature Biotechnology 2018 Nov 9 36 (11): 1117.
34 34 Shi, W., Li, M., Wei, G., Tian, R., Li, C., Wang, B., Lin, R., Shi, C., Chi, X., Zhou, B., and Gao, Z. (2019). The occurrence of potato common scab correlates with the community composition and function of the geocaulosphere soil microbiome. Microbiome Dec 7 (1): 1–8.
35 35 Minuto, A., Spadaro, D., Garibaldi, A., and Gullino, M.L. (2006). Control of soilborne pathogens of tomato using a commercial formulation of Streptomyces griseoviridis and solarization. Crop Protection May 1 25 (5): 468–475.
36 36 Sindhu, S.S., Rakshiya, Y.S., and Sahu, G. (2009). Biological control of soilborne plant pathogens with rhizosphere bacteria. Pest Technology 3 (1): 10–21.
37 37 Palmieri, D., Vitullo, D., De Curtis, F., and Lima, G. (2017). A microbial consortium in the rhizosphere as a new biocontrol approach against fusarium decline of chickpea. Plant and Soil Mar 1 412 (1-2): 425–439.
38 38 Wu, H., Lin, M., Rensing, C., Qin, X., Zhang, S., Chen, J., Wu, L., Zhao, Y., Lin, S., and Lin, W. (2020). Plant-mediated rhizospheric interactions in intraspecific intercropping alleviate the replanting disease of Radix pseudostellariae. Plant and Soil Sep 454 (1): 411–430.
39 39 Li, X., De Boer, W., Ding, C., Zhang, T., and Wang, X. (2018). Suppression of soilborne Fusarium pathogens of peanut by intercropping with the medicinal herb Atractylodes lancea. Soil Biology & Biochemistry Jan 1 116: 120–130.
40 40 Ren, L., Su, S., Yang, X., Xu, Y., Huang, Q., and Shen, Q. (2008). Intercropping with aerobic rice suppressed Fusarium wilt in watermelon. Soil Biology & Biochemistry Mar 1 40 (3): 834–844.
41 41 Zhang, H., Yang, Y., Mei, X., Li, Y., Wu, J., Li, Y., Wang, H., Huang, H., Yang, M., He, X., and Zhu, S. (2020). Phenolic acids released in maize rhizosphere during maize-soybean intercropping inhibit Phytophthora blight of soybean. Frontiers in Plant Science Jul 28 (11): 886.
42 42 Bailey, K.L. and Lazarovits, G. (2003). Suppressing soilborne diseases with residue management and organic amendments. Soil and Tillage Research Aug 1 72 (2): 169–180.
43 43 Pane, C., Spadaccini, R., Piccolo, A., Scala, F., and Bonanomi, G. (2011). Compost amendments enhance peat suppressiveness to Pythium ultimum, Rhizoctonia solani and Sclerotinia minor. Biological
