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. 2013 Nov;79(22):6862-7.
doi: 10.1128/AEM.01393-13. Epub 2013 Aug 30.

Gains of bacterial flagellar motility in a fungal world

Martin Pion  1 Redouan BsharySaskia BindschedlerSevasti FilippidouLukas Y WickDaniel JobPilar Junier
Affiliations

Gains of bacterial flagellar motility in a fungal world

VSports - Martin Pion et al. Appl Environ Microbiol. 2013 Nov.

Abstract

The maintenance of energetically costly flagella by bacteria in non-water-saturated media, such as soil, still presents an evolutionary conundrum. Potential explanations have focused on rare flooding events allowing dispersal. Such scenarios, however, overlook bacterial dispersal along mycelia as a possible transport mechanism in soils. The hypothesis tested in this study is that dispersal along fungal hyphae may lead to an increase in the fitness of flagellated bacteria and thus offer an alternative explanation for the maintenance of flagella even in unsaturated soils. Dispersal along fungal hyphae was shown for a diverse array of motile bacteria. To measure the fitness effect of dispersal, additional experiments were conducted in a model system mimicking limited dispersal, using Pseudomonas putida KT2440 and its nonflagellated (ΔfliM) isogenic mutant in the absence or presence of Morchella crassipes mycelia. In the absence of the fungus, flagellar motility was beneficial solely under conditions of water saturation allowing dispersal, while under conditions limiting dispersal, the nonflagellated mutant exhibited a higher level of fitness than the wild-type strain. In contrast, in the presence of a mycelial network under conditions limiting dispersal, the flagellated strain was able to disperse using the mycelial network and had a higher level of fitness than the mutant VSports手机版. On the basis of these results, we propose that the benefit of mycelium-associated dispersal helps explain the persistence of flagellar motility in non-water-saturated environments. .

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Figures

Fig 1
Fig 1
Description of the experimental design. (A) Changes in the agar concentration added to the culture medium modify the liquid film formed over the solid agar, allowing (<0.5%) or restricting (>0.5%) bacterial dispersal. (B) Dispersal was estimated by using a flagellated wild-type strain labeled with GFP versus a nonflagellated mutant (ΔfliM mutant) labeled with the fluorescent protein DsRed. The strains were inoculated in media with variable concentrations of agar and in the absence or presence of a fungal dispersal network.
Fig 2
Fig 2
Dispersal of Pseudomonas putida on agar medium. (A) Image of the swimming test in malt agar medium. (Left) Wild-type strain; (right) ΔfliM mutant. (B) Colony diameters (image overlap) of the wild-type and mutant strains growing with 0.5% agar. The image in the lower panel is colored according to the fluorescent labels. Bar, 5 mm. (C) Colony diameters (image overlap) of the wild-type and mutant strains growing with 1.5% agar. Bar, 5 mm.
Fig 3
Fig 3
Dispersal of Pseudomonas putida on Morchella crassipes hyphae. (A) Colonization by wild type P. putida of M. crassipes hyphae. Bacteria are shown in a confocal fluorescent green channel, and hyphae are shown in a nonconfocal transmission channel. (B) Colonization by P. putida ΔfliM of M. crassipens hyphae. Bacteria are shown in a confocal fluorescent red channel, and hyphae are shown in a nonconfocal transmission channel.
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