Abstract
Micromonospora is a Gram positive bacterium that can be isolated from nitrogen fixing nodules from healthy leguminous plants, where they could be beneficial to the plant. Their plant growth promoting activity in legume and non-legume plants has been previously demonstrated. The present study explores the ability of Micromonospora strains to control fungal pathogens and to stimulate plant immunity. Micromonospora strains isolated from surface sterilized nodules of alfalfa showed in vitro antifungal activity against several pathogenic fungi. Moreover, root inoculation of tomato plants with these Micromonospora strains effectively reduced leaf infection by the fungal pathogen Botrytis cinerea, despite spatial separation between both microorganisms. This induced systemic resistance, confirmed in different tomato cultivars, is long lasting. Gene expression analyses evidenced that Micromonospora stimulates the plant capacity to activate defense mechanisms upon pathogen attack. The defensive response of tomato plants inoculated with Micromonospora spp. differs from that of non-inoculated plants, showing a stronger induction of jasmonate-regulated defenses when the plant is challenged with a pathogen. The hypothesis of jasmonates playing a key role in this defense priming effect was confirmed using defense-impaired tomato mutants, since the JA-deficient line def1 was unable to display a long term induced resistance upon Micromonospora spp. inoculation. In conclusion, nodule isolated Micromonospora strains should be considered excellent candidates as biocontrol agents as they combine both direct antifungal activity against plant pathogens and the ability to prime plant immunity.
Highlights
Most actinobacteria were considered to inhabit environments such as soil, rhizosphere, or lake sediments
Selected Micromonospora isolates were tested for their ability to inhibit the growth of the damaging fungal pathogens F. circinatum, S. sclerotiorum, R. solani, and B. cinerea (Supplementary Figure S1)
Two strains of Micromonospora were capable of inhibiting growth of F. circinatum (ALF4 and ALFb7), five strains (AL4, AL16, AL20, ALFpr18c y ALFr4) inhibited S. sclerotinum, seven strains were inhibitory to R. solani (AL20, ALF1, ALF2, ALFb5, ALFb7, ALFpr18c y ALFpr19a) and 10 strains inhibited B. cinerea (AL4, AL20, ALF1, ALF2, ALF7, ALFb1, ALFb5, ALFpr18c, ALFpr19a y ALFpr4)
Summary
Most actinobacteria were considered to inhabit environments such as soil, rhizosphere, or lake sediments. Actinobacteria have been described to promote plant growth and their beneficial effect has been reported previously in various plant species (El-Tarabily and Sivasithamparam, 2006; Franco et al, 2007). Micromonospora strains have been found in a wide selection of leguminous plants, including Medicago sativa, the plant of choice for the isolation of Micromonospora spp. in our study. Previous studies (Martínez-Hidalgo et al, 2014b) showed that nodule isolated Micromonospora strains excel at plant growth promotion when inoculated in alfalfa. This effect was not due to biological nitrogen fixation the nitrogen content was significantly higher than in control plants (Martínez-Hidalgo et al, 2014a)
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