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. 1986 Nov;168(2):821–827. doi: 10.1128/jb.168.2.821-827.1986

Correlation between extracellular fibrils and attachment of Rhizobium leguminosarum to pea root hair tips.

G Smit, J W Kijne, B J Lugtenberg
PMCID: PMC213558  PMID: 3782027

Abstract

As part of a project meant to characterize molecules involved in nodulation, a semiquantitative microscopic assay was developed for measuring attachment of Rhizobium leguminosarum cells to pea root hair tips, i.e., the site at which R. leguminosarum initiates nodulation. This form of attachment, designated as cap formation, was dependent on the incubation pH and growth phase, with optimal attachment at pH 7.5 and with bacteria in the early stationary phase of growth. Addition of glucose to the growth medium delayed the initiation of the stationary phase and cap formation, suggesting a correlation between cap formation and carbon limitation. Attachment of R. leguminosarum was not inhibited by pea lectin haptens which makes it unlikely that lectins are involved under the tested conditions. Moreover, heterologous fast-growing rhizobia adhered equally well to pea root hair tips. Since the attachment characteristics of a Sym plasmid-cured derivative were indistinguishable from those of the wild-type strain, the Sym plasmidborne nodulation genes are not necessary for attachment. Sodium chloride and various other salts abolished attachment when present during the attachment assay in final concentrations of 100 mM. R. leguminosarum produced extracellular fibrils. A positive correlation between the percentage of fibrillated cells and the ability of the bacteria to form caps and to adhere to glass and erythrocytes was observed under various conditions, suggesting that these fibrils play a role in attachment of the bacteria to pea root hair tips, to glass, and to erythrocytes.

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Selected References

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