Soil amoebae rapidly change bacterial community composition in the rhizosphere of <i>Arabidopsis thaliana</i>

Rosenberg, Katja; Bertaux, Joanne; Krome, Kristin; Hartmann, Anton; Scheu, Stefan; Bonkowski, Michael

doi:10.1038/ismej.2009.11

Cited by 210 publications

(195 citation statements)

References 54 publications

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“…The F113 strain was originally isolated from sugar beet rhizospheres in Ireland (158) and can inhibit the growth of plant-pathogenic bacteria, oomycetes, fungi, and a wide range of nematodes (159)(160)(161). Predation against protozoa in both terrestrial and aquatic environments is an important factor influencing bacterial community makeup and behavior (37,38,162). In F113, the SPI-I T3SS hilA promoter shows increased expression during close contact with the amoeba Acanthamoeba castellanii, suggesting that this T3SS is directly involved in protecting the bacterium from amoeba predation.…”

Section: Type III Secretion Systemsmentioning

confidence: 99%

“…1), including soil, the rhizospheres and surfaces of plants, nonsterile pharmaceuticals, showerheads, and even indoor wall surfaces (23,24). P. fluorescens has been studied most widely as an environmental microbe, most notably for its role in promoting plant health via a number of encoded antimicrobial mechanisms (25)(26)(27)(28)(29)(30)(31)(32)(33)(34)(35)(36)(37)(38). However, P. fluorescens also possesses a number of functional traits that provide it with the capability to grow and thrive in mammalian hosts, including production of bioactive secondary metabolites (26-30, 33, 39-42), siderophores (43)(44)(45), and a type III secretion system (46)(47)(48)(49)(50)(51), the ability to form biofilms (20,(52)(53)(54)(55)(56), and the plasticity of some strains to adapt to growth at higher temperature (53,(57)(58)(59).…”

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confidence: 99%

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Microbiology, Genomics, and Clinical Significance of the Pseudomonas fluorescens Species Complex, an Unappreciated Colonizer of Humans

et al. 2014

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SUMMARY Pseudomonas fluorescens is not generally considered a bacterial pathogen in humans; however, multiple culture-based and culture-independent studies have identified it at low levels in the indigenous microbiota of various body sites. With recent advances in comparative genomics, many isolates originally identified as the “species” P. fluorescens are now being reclassified as novel Pseudomonas species within the P. fluorescens “species complex.” Although most widely studied for its role in the soil and the rhizosphere, P. fluorescens possesses a number of functional traits that provide it with the capability to grow and thrive in mammalian hosts. While significantly less virulent than P. aeruginosa , P. fluorescens can cause bacteremia in humans, with most reported cases being attributable either to transfusion of contaminated blood products or to use of contaminated equipment associated with intravenous infusions. Although not suspected of being an etiologic agent of pulmonary disease, there are a number of reports identifying it in respiratory samples. There is also an intriguing association between P. fluorescens and human disease, in that approximately 50% of Crohn's disease patients develop serum antibodies to P. fluorescens . Altogether, these reports are beginning to highlight a far more common, intriguing, and potentially complex association between humans and P. fluorescens during health and disease.

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Section: Type III Secretion Systemsmentioning

confidence: 99%

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confidence: 99%

Microbiology, Genomics, and Clinical Significance of the Pseudomonas fluorescens Species Complex, an Unappreciated Colonizer of Humans

et al. 2014

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“…Bacteria are the main drivers of many biogeochemical cycles, nutrient recycling and trophic transfer of organic carbon and nitrogen (Falkowski et al, 2008). Similar to food web modules composed of larger organisms, topdown control by protistan predators regulates bacterial abundance, community composition and, consequently, has an influence on many microbial ecosystem processes (Simek et al, 1997;Pernthaler, 2005;Corno and Jü rgens, 2008;Rosenberg et al, 2009;Bell et al, 2010;Glü cksman et al, 2010). Although direct influences of top-down control of bacterial communities by protists have been studied earlier (for example, Bell et al, 2010;Roberts et al, 2011;Martinez-Garcia et al, 2012), relatively little is known about direct mutual effects of species richness on community structures and performances of the prey or predator communities, respectively.…”

Section: Introductionmentioning

confidence: 99%

Diversity of protists and bacteria determines predation performance and stability

et al. 2013

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Predation influences prey diversity and productivity while it effectuates the flux and reallocation of organic nutrients into biomass at higher trophic levels. However, it is unknown how bacterivorous protists are influenced by the diversity of their bacterial prey. Using 456 microcosms, in which different bacterial mixtures with equal initial cell numbers were exposed to single or multiple predators (Tetrahymena sp., Poterioochromonas sp. and Acanthamoeba sp.), we showed that increasing prey richness enhanced production of single predators. The extent of the response depended, however, on predator identity. Bacterial prey richness had a stabilizing effect on predator performance in that it reduced variability in predator production. Further, prey richness tended to enhance predator evenness in the predation experiment including all three protists predators (multiple predation experiment). However, we also observed a negative relationship between prey richness and predator production in multiple predation experiments. Mathematical analysis of potential ecological mechanisms of positive predator diversity-functioning relationships revealed predator complementarity as a factor responsible for both enhanced predator production and prey reduction. We suggest that the diversity at both trophic levels interactively determines protistan performance and might have implications in microbial ecosystem processes and services.

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“…Bacterial communities are heavily consumed by protozoan predators (30), and predation is a major force shaping the structure of microbial communities in both aquatic and terrestrial ecosystems (34,35). The competitiveness of bacteria strongly depends on their ability to avoid predation (9,22), and many species have developed defense mechanisms such as the production of toxins, which reduces mortality by repelling or killing predators (21,24).…”

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confidence: 99%

Predator-Prey Chemical Warfare Determines the Expression of Biocontrol Genes by Rhizosphere-Associated Pseudomonas fluorescens

Jousset

Rochat

Scheu

et al. 2010

Appl Environ Microbiol

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Soil bacteria are heavily consumed by protozoan predators, and many bacteria have evolved defense strategies such as the production of toxic exometabolites. However, the production of toxins is energetically costly and therefore is likely to be adjusted according to the predation risk to balance the costs and benefits of predator defense. We investigated the response of the biocontrol bacterium Pseudomonas fluorescens CHA0 to a common predator, the free-living amoeba Acanthamoeba castellanii. We monitored the effect of the exposure to predator cues or direct contact with the predators on the expression of the phlA, prnA, hcnA, and pltA genes, which are involved in the synthesis of the toxins, 2,4-diacetylphloroglucinol (DAPG), pyrrolnitrin, hydrogen cyanide, and pyoluteorin, respectively. Predator chemical cues led to 2.2-, 2.0-, and 1.2-fold increases in prnA, phlA, and hcnA expression, respectively, and to a 25% increase in bacterial toxicity. The upregulation of the tested genes was related to the antiprotozoan toxicity of the corresponding toxins. Pyrrolnitrin and DAPG had the highest toxicity, suggesting that bacteria secrete a predator-specific toxin cocktail. The response of the bacteria was elicited by supernatants of amoeba cultures, indicating that water-soluble chemical compounds were responsible for induction of the bacterial defense response. In contrast, direct contact of bacteria with living amoebae reduced the expression of the four bacterial toxin genes by up to 50%, suggesting that protozoa can repress bacterial toxicity. The results indicate that predator-prey interactions are a determinant of toxin production by rhizosphere P. fluorescens and may have an impact on its biocontrol potential.

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Soil amoebae rapidly change bacterial community composition in the rhizosphere of Arabidopsis thaliana

Cited by 210 publications

References 54 publications

Microbiology, Genomics, and Clinical Significance of the Pseudomonas fluorescens Species Complex, an Unappreciated Colonizer of Humans

Microbiology, Genomics, and Clinical Significance of the Pseudomonas fluorescens Species Complex, an Unappreciated Colonizer of Humans

Diversity of protists and bacteria determines predation performance and stability

Predator-Prey Chemical Warfare Determines the Expression of Biocontrol Genes by Rhizosphere-Associated Pseudomonas fluorescens

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