Abstract
The root-colonization ability of Streptomyces griseoviridis Anderson et al. was tested on turnip rape (Brassica rapa subsp. oleifera DC.) and carrot (Daucus carota L.) by the sand-tube method. Nonsterile sand was sprayed with a microbial suspension immediately or 7 days after the seed had been sown. Results expressed as population frequencies and densities indicated that S. griseoviridis effectively colonizes the rhizosphere when the microbe is applied immediately after sowing but less effectively when it is applied 7 days later. Detection values of S. griseoviridis were higher for turnip rape than for carrot. In sterile sand, S. griseoviridis invaribly colonized the rhizosphere of turnip rape after each of the two applications. These findings indicate that S. griseoviridis can compete with indigenous soil microbes in the rhizosphere if it is sufficiently abundant in the soil before the seed emerges. If applied later, however, it competes rather poorly. In root-free nonsterile sand, S. griseoviridis dispersed and survived well.
Highlights
The root-colonization ability of Streptomyces griseoviridis Anderson et al was tested on turnip rape (Brassica rapa subsp. oleifera DC.) and carrot ( Daucus carota L.) by the sand-tube method
These findings indicate that S. griseoviridis can compete with indigenous soil microbes in the rhizosphere if it is sufficiently abundant in the soil before the seed emerges
Root colonization was more effective when S. griseoviridis was applied to nonsterile sand immediately after sowing than when it was applied 7 days later, probably because during those days the rhizosphere was colonized by other soil microbes with which S. griseoviridis was unable to compete
Summary
The root-colonization ability of Streptomyces griseoviridis Anderson et al was tested on turnip rape (Brassica rapa subsp. oleifera DC.) and carrot ( Daucus carota L.) by the sand-tube method. Nonsterile sand was sprayed with a microbial suspension immediately or 7 days after the seed had been sown. S. griseoviridis invaribly colonized the rhizosphere of turnip rape after each of the two applications. These findings indicate that S. griseoviridis can compete with indigenous soil microbes in the rhizosphere if it is sufficiently abundant in the soil before the seed emerges. S. griseoviridis, a biocontrol agent used against some seed-borneand soil-borne plant pathogens (Tahvonen 1988), produces the auxin indole-3-. Mycostop (Kemira Oy, Finland) is a biofungicide produced by fermentation of the spores and Kortemaa, H. et al Effect ofsoil-spraying time on Streptomyces griseoviridis mycelium of a S. griseoviridis strain isolated from peat by Tahvonen (1982). Several isolates ofStreptomyces spp., including the S. griseoviridis isolated from peat, produce polyene antibiotics. According to Sivan and Chet (1989), the inhibition of germination of chlamydospores might be due to competition between Trichoderma harzianum Rifai and Fusarium oxysporum Schlecht.: Fr. Rothrock and Gottlieb (1984), on the other hand, showed that the antagonism of S. hygroscopicus var. geldanus was due to the antibiotic production, not to competition for nutrients
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