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NTIS 바로가기Research in plant disease = 식물병연구, v.29 no.2, 2023년, pp.174 - 183
김다란 (경상국립대학교 생명과학연구원) , 곽연식 (경상국립대학교 생명과학연구원)
The limited effectiveness of current plant disease management treatments necessitates the development of new methods for controlling diseases using beneficial microbes. Demanding sustainable agriculture is increasingly highlighted as a biocontrol approach, particularly Streptomyces species known to ...
Andleeb, S., Shafique, I., Naseer, A., Abbasi, W. A., Ejaz, S., Liaqat, I. et?al. 2022. Molecular characterization of plant growth-promoting?vermi-bacteria associated with Eisenia fetida gastrointestinal?tract. PLoS ONE 17: e0269946.
Bentley, S. D., Chater, K. F., Cerdeno-Tarraga, A.-M., Challis, G. L.,?Thomson, N. R., James, K. D. et al. 2002. Complete genome?sequence of the model actinomycete Streptomyces coelicolor?A3(2).?Nature 417: 141-147.
Berkelmann, D., Schneider, D., Hennings, N., Meryandini, A. and?Daniel, R. 2020. Soil bacterial community structures in relation?to different oil palm management practices.?Sci. Data?7: 421.
Bintarti, A. F., Sulesky-Grieb, A., Stopnisek, N. and Shade, A. 2022.?Endophytic microbiome variation among single plant seeds.?Phytobiomes J. 6: 45-55.
Bokhari, A., Essack, M., Lafi, F. F., Andres-Barrao, C., Jalal, R., Alamoudi, S. et al. 2019. Bioprospecting desert plant Bacillus endophytic strains for their potential to enhance plant stress tolerance. Sci. Rep. 9: 18154.
Cha, J.-Y., Han, S., Hong, H.-J., Cho, H., Kim, D., Kwon, Y., et al. 2016.?Microbial and biochemical basis of a Fusarium wilt-suppressive?soil.?ISME J.?10: 119-129.
Chen, S., Chen, X. and Xu, J. 2016. Impacts of climate change on?agriculture: evidence from China. J. Environ. Econ. Manage. 76:?105-124.
Costa, E., Teixido, N., Usall, J., Atares, E. and Vinas, I. 2002. The effect?of nitrogen and carbon sources on growth of the biocontrol?agent Pantoea agglomerans strain CPA-2.?Lett. Appl. Microbiol.?35:117-120.
Deshpande, B. S., Ambedkar, S. S. and Shewale, J. G. 1988. Biologically active secondary metabolites from Streptomyces.?Enzyme?Microb. Technol.?10: 455-473.
Ducray, H. A. G., Globa, L., Pustovyy, O., Morrison, E., Vodyanoy, V.?and Sorokulova, I. 2019. Yeast fermentate prebiotic improves?intestinal barrier integrity during heat stress by modulation of?the gut microbiota in rats.?J. Appl. Microbiol.?127: 1192-1206.
Du, J., Li, Y., Ur-Rehman, S., Mukhtar, I., Yin, Z., Dong, H. et al. 2021.?Synergistically promoting plant health by harnessing synthetic?microbial communities and prebiotics. iScience 24: 102918.
Fidan, O. and Zhan, J. 2019. Discovery and engineering of an endophytic Pseudomonas strain from Taxus chinensis for efficient?production of zeaxanthin diglucoside. J. Biol. Eng. 13: 66.
Harir, M., Bendif, H., Bellahcene, M., Fortas, Z. and Pogni, R. 2018.?Streptomyces secondary metabolites.?In: Basic Biology and Applications of Actinobacteria, ed. by?S. Enany, pp. 99-122. IntechOpen, London, UK.
Hannula, S. E., Zhu, F., Heinen, R. and Bezemer, T. M. 2019. Foliarfeeding insects acquire microbiomes from the soil rather than?the host plant. Nat. Commun. 10: 1254.
Herrera-Quiterio, A., Toledo-Hernandez, E., Aguirre-Noyola, J. L.,?Romero, Y., Ramos, J., Palemon-Alberto, F. et al. 2020. Antagonic?and plant growth-promoting effects of bacteria isolated from?mine tailings at El Fraile, Mexico.?Rev. Argent. Microbiol.?52: 231-239.
Jagermeyr, J., Robock, A., Elliott, J., Muller, C., Xia, L., Khabarov, N., et?al. 2020. A regional nuclear conflict would compromise global?food security. Proc. Natl. Acad. Sci. U. S. A. 117: 7071-7081.
Jeon, C.-W., Kim, D.-R. and Kwak, Y.-S. 2019. Valinomycin, produced?by Streptomyces sp. S8, a key antifungal metabolite in large?patch disease suppressiveness. World J. Microbiol. Biotechnol. 35: 128.
Jung, Y.-J., Joung, Y. and Ahn, T.-S. 2011. Characterization of Actinomyces isolated from freshwater sponges in lake Baikal.?Korean J.?Microbiol.?47: 130-136.
Kalaiyarasi, M., Ahmad, P. and Vijayaraghavan, P. 2020. Enhanced?production antibiotics using green gram husk medium by?Streptomyces sp. SD1 using response surface methodology.?J.?King Saud Univ. Sci.?32: 2134-2141.
Kim, D.-R., Cho, G., Jeon, C.-W., Weller, D. M., Thomashow, L. S., Paulitz, T. C., et al. 2019a. A mutualistic interaction between Streptomyces bacteria, strawberry plants and pollinating bees. Nat. Commun. 10: 4802.
Kim, D.-R., Jeon, C.-W., Cho, G., Thomashow, L. S., Weller, D. M., Paik,?M.-J. et al. 2021. Glutamic acid reshapes the plant microbiota to?protect plants against pathogens. Microbiome 9: 244.
Kim, D.-R., Jeon, C.-W., Shin, J.-H., Weller, D. M., Thomashow, L. and?Kwak, Y. S. 2019b. Function and distribution of a lantipeptide in?strawberry Fusarium wilt disease-suppressive soils.?Mol. Plant-Microbe Interact.?32: 306-312.
Kim, M.-J., Chae, D.-H., Cho, G., Kim, D.-R. and Kwak, Y.-S. 2019c.?Characterization of antibacterial strains against kiwifruit bacterial canker pathogen.?Plant Pathol. J.?35: 473-485.
Lau, J. A., Lennon, J. T. and Heath, K. D. 2017. Trees harness the power of microbes to survive climate change. Proc. Natl. Acad. Sci. U.?S. A. 114: 11009-11011.
Lee, J. H., Lee, Y. S. and Kim, Y. C. 2021. Effect of temperature and?culture media composition on sporulation, mycelial growth,?and antifungal activity of Isaria javanica pf185. Res. Plant Dis. 27:?99-106.
Lee, N., Hwang, S., Kim, J., Cho, S., Palsson, B. and Cho, B.-K. 2020.?Mini review: genome mining approaches for the identification?of secondary metabolite biosynthetic gene clusters in Streptomyces.?Comput. Struct. Biotechnol. J. 18: 1548-1556.
Lindow, S. E. and Brandl, M. T. 2003. Microbiology of the phyllosphere.?Appl. Environ. Microbiol.?69: 1875-1883.
Lu, T., Ke, M., Lavoie, M., Jin, Y., Fan, X., Zhang, Z., et al. 2018. Rhizosphere microorganisms can influence the timing of plant flowering. Microbiome 6: 231.
Mostafa, S. A. 1979. Activity of L-asparaginase in cells of Streptomyces karnatakensis.?Zentralbl. Bakteriol. Natuwiss.?134: 343-351.
Oviedo-Pereira, D. G., Lopez-Meyer, M., Evangelista-Lozano, S.,?Sarmiento-Lopez, L. G., Sepulveda-Jimenez, G. and Rodriguez-Monroy, M. 2022. Enhanced specialized metabolite, trichome?density, and biosynthetic gene expression in Stevia rebaudiana?(Bertoni) Bertoni plants inoculated with endophytic bacteria?Enterobacter hormaechei. PeerJ 10: e13675.
Padilla, G., Hindle, Z., Callis, R., Corner, A., Ludovice, M., Liras, P. et al.?1991. The relationship between primary and secondary metabolism in Streptomycetes. In: Genetics and Product Formation in?Streptomyces, eds. by S. Baumberg, H. Krugel and D. Noack, pp.?35-45. Federation of European Microbiological Societies Symposium Series, Vol. 55. Springer, Boston, MA.
Park, J.-K., Kim, J., Lee, C.-W., Song, J., Seo, S.-I., Bong, K.-M. et al.?2019. Mass cultivation and characterization of multifunctional?Bacillus velezensis GH1-13.?Korean J. Org. Agric.?27: 65-76.
Park, J.-K., Seo, S.-I., Han, G. H., Kim, K.-M., Kim, D.-H., Song, J. et al.?2018. Development of practical media and fermentative technique for mass cultivation from agricultural and livestock microorganism.?Trends Agric. Life Sci.?56: 23-33.
Patel, D. and Parmar, P. 2013. Isolation and screening of phosphate?solubilizing bacteria from sunflower rhizosphere. Glob. J. Biosci.?Biotechnol. 2: 438-441.
Redford, A. J., Bowers, R. M., Knight, R., Linhart, Y. and Fierer, N. 2010.?The ecology of the phyllosphere: geographic and phylogenetic?variability in the distribution of bacteria on tree leaves.?Environ.?Microbiol.?12: 2885-2893.
Reese, A. T., Pereira, F. C., Schintlmeister, A., Berry, D., Wagner, M.,?Hale, L. P. et al. 2018. Microbial nitrogen limitation in the mammalian large intestine.?Nat. Microbiol.?3: 1441-1450.
Rico, A. and Preston, G. M. 2008. Pseudomonas syringae pv. tomato?DC3000 uses constitutive and apoplast-induced nutrient assimilation pathways to catabolize nutrients that are abundant?in the tomato apoplast.?Mol. Plant-Microbe Interact.?21: 269-282.
Ripa, E. A., Nikkon, K., Zaman, S. and Khondkar, P. 2009. Optimal?conditions for antimicrobial metabolites production from a?new Streptomyces sp. RUPA-08PR isolated from Bangladeshi?soil.?Mycobiology?37: 211-214.
Rodriguez, P. A., Rothballer, M., Chowdhury, S. P., Nussbaumer, T.,?Gutjahr, C. and Falter-Braun, P. 2019.?Systems biology of plant-microbiome interactions.?Mol. Plant 12: 804-821.
Voelker, F. and Altaba, S. 2001. Nitrogen source governs the patterns of growth and pristinamycin production in 'Streptomyces?pristinaespiralis'.?Microbiology?147: 2447-2459.
Xiong, C., Singh, B. K., He, J.-Z., Han, Y.-L., Li, P.-P., Wan, L.-H., et al.?2021. Plant developmental stage drives the differentiation in?ecological role of the maize microbiome. Microbiome 9: 171.
Yague, P., Lopez-Garcia, M. T., Rioseras, B., Sanchez, J. and Manteca,?A. 2012. New insights on the development of Streptomyces and?their relationships with secondary metabolite production.?Curr.?Trends Microbial.?8: 65-73.
Xu, Y., Ge, Y., Song, J. and Rensing, C. 2019. Assembly of root-associated microbial community of typical rice cultivars in different?soil types. Biol. Fertil. Soils 56: 249-260.
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