Impact of Seed Exudates on Growth and Biofilm Formation of Bacillus amyloliquefaciens ALB629 in Common Bean

We aimed to unravel the events which favor the seed-rhizobacterium strain ALB629 (hereafter ALB629) interaction and which may interfere with the rhizobacterium colonization and growth on the spermosphere of common bean. Seed exudates from common bean were tested for ALB629 biofilm formation and bact...

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Bibliographic Details
Published in:Frontiers in microbiology 2018-01, Vol.8, p.2631-2631
Main Authors: Martins, Samuel J, Medeiros, Flávio H V, Lakshmanan, Venkatachalam, Bais, Harsh P
Format: Article
Language:English
Subjects:
abiotic stress
drought
Microbiology
PGPR
rhizobacteria
seed coating
sporulation
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Summary:We aimed to unravel the events which favor the seed-rhizobacterium strain ALB629 (hereafter ALB629) interaction and which may interfere with the rhizobacterium colonization and growth on the spermosphere of common bean. Seed exudates from common bean were tested for ALB629 biofilm formation and bacterial growth. Furthermore, the performance of ALB629 on plant-related variables under drought stress was checked. Seed exudates (1 and 5% v/v) increased ALB629 biofilm formation. Additionally, the colony forming units for ALB629 increased both in culture and on the bean seed surface. The bean seed exudates up-regulated biofilm operons in ALB629 and by ca. two and sixfold, respectively. The high-performance liquid chromatography (HPLC)-coupled with MS showed that malic acid is present as a major organic acid component in the seed exudates. Seeds treated with ALB629 and amended with malic acid resulted in seedlings with a higher bacterial concentration, induced plant drought tolerance, and promoted plant growth. We showed that seed exudates promote growth of ALB629 and malic acid was identified as a major organic acid component in the bean seed exudates. Our results also show that supplementation of ALB629 induced drought tolerance and growth in plants. The research pertaining to the biological significance of seed exudates in plant-microbe interaction is unexplored field and our work shows the importance of seed exudates in priming both growth and tolerance against abiotic stress.
ISSN:1664-302X
1664-302X
DOI:10.3389/fmicb.2017.02631