Exogenous glucosinolate produced by <i>Arabidopsis thaliana</i> has an impact on microbes in the rhizosphere and plant roots

Bressan, Mélanie; Roncato, Marie‐Anne; Bellvert, Floriant; Comte, Gilles; Haichar, Feth el Zahar; Achouak, Wafa; Berge, Odile

doi:10.1038/ismej.2009.68

Cited by 232 publications

(137 citation statements)

References 80 publications

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“…living and dead plant material and root exudates) we still found no differences in the microorganism community between the cultivars or a response of the microorganisms to the glucosinolate profiles. This contrasts with previous studies recording that B. napus and A. thaliana chemotypes with different glucosinolate profiles influenced the microorganism community (Bressan et al 2009;Rumberger and Marschner 2003). Using identical bacterial primers as used in our study, Rumberger and Marschner (2003) found that 2-phenylethyl-isothiocyanate, the breakdown product of gluconasturtiin, influenced the bacterial community in roots and rhizosphere of B. napus.…”

Section: Higher Trophic Levels and Microorganismscontrasting

confidence: 99%

“…Upon tissue damage, glucosinolates are degraded by the enzyme myrosinase, thereby forming toxic breakdown products such as (iso)thiocyanates (Wang et al 2009). Belowground, glucosinolates and their breakdown products are known to reduce the abundance of phytophagous organisms such as rootfeeding nematodes (Lazzeri et al 2004;Potter et al 1998;Potter et al 2000), fungi (Bressan et al 2009;Rumberger and Marschner 2003;Snapp et al 2007), and bacteria (Aires et al 2009;Bressan et al 2009;Rumberger and Marschner 2003). Aromatic glucosinolates, particularly gluconasturtiin and its breakdown product 2-phenylethyl isothiocyanate, are generally considered as the most toxic glucosinolates in plant roots (Potter et al 1998;Potter et al 2000;Rumberger and Marschner 2003;van Dam et al 2009;Vierheilig et al 2000).…”

Section: Introductionmentioning

confidence: 99%

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Effects of intraspecific variation in white cabbage (Brassica oleracea var. capitata) on soil organisms

et al. 2010

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Intraspecific variation in plants can affect soil organisms. However, little is known about whether the magnitude of the effect depends on the degree of interaction with the roots. We analyzed effects of plant intraspecific variation on root herbivores and other soil organisms that interact directly with living plant roots, as well as on decomposer organisms that interact more indirectly with roots. We used four different white cabbage (Brassica oleracea var. capitata) cultivars exhibiting a high degree of intraspecific variation in root glucosinolate profiles. Intraspecific variation affected root-feeding nematodes, whereas decomposer organisms such as earthworms and Collembola were not affected. Root-feeding nematodes were most abundant in one of the cultivars, Badger Shipper, which lacked the glucosinolate gluconasturtiin. The effect of the intraspecific variation in glucosinolate composition may have been restricted to root-feeding nematodes due to the rapid degradation of glucosinolates and their breakdown products in the soil. Additionally, the low biomass of root-feeding nematodes, relative to other soil organisms, limits the possibility to affect higher trophic level organisms. Our results show that variation in root chemistry predominantly affects belowground herbivores and that these effects do not extend into the soil food web.

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Section: Higher Trophic Levels and Microorganismscontrasting

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Effects of intraspecific variation in white cabbage (Brassica oleracea var. capitata) on soil organisms

et al. 2010

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“…Some microbial root colonists are saprophytes, which also colonise splinters of wood inserted into soil (Bulgarelli et al, 2012), but others are selected by exudation of nutrient sources and phytoalexins, such as glucosinolates and avenacins (Sonderby et al, 2007;Bressan et al, 2009;Turner et al, 2013b). Furthermore, by altering the rhizosphere microbiota, plants induce formation of suppressive soil where growth of plant pathogens is inhibited (Lebreton et al, 2007;Kinkel et al, 2011;Mendes et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

Stability and succession of the rhizosphere microbiota depends upon plant type and soil composition

et al. 2015

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We examined succession of the rhizosphere microbiota of three model plants (Arabidopsis, Medicago and Brachypodium) in compost and sand and three crops (Brassica, Pisum and Triticum) in compost alone. We used serial inoculation of 24 independent replicate microcosms over three plant generations for each plant/soil combination. Stochastic variation between replicates was surprisingly weak and by the third generation, replicate microcosms for each plant had communities that were very similar to each other but different to those of other plants or unplanted soil. Microbiota diversity remained high in compost, but declined drastically in sand, with bacterial opportunists and putative autotrophs becoming dominant. These dramatic differences indicate that many microbes cannot thrive on plant exudates alone and presumably also require carbon sources and/or nutrients from soil. Arabidopsis had the weakest influence on its microbiota and in compost replicate microcosms converged on three alternative community compositions rather than a single distinctive community. Organisms selected in rhizospheres can have positive or negative effects. Two abundant bacteria are shown to promote plant growth, but in Brassica the pathogen Olpidium brassicae came to dominate the fungal community. So plants exert strong selection on the rhizosphere microbiota but soil composition is critical to its stability. microbial succession/ plant-microbe interactions/rhizosphere microbiota/selection.

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“…In the absence of herbivory, do the selective advantages of various plant defenses persist or disappear? How do antiherbivore defenses such as glucosinolates respond to selective pressures imposed by other agents, such as pathogens (Sanchez-Vallet et al, 2010) and microbial mutualists (Bressan et al, 2009)? More generally, what role do different abiotic and biotic agents of selection play in the evolution of complex traits?…”

Section: Agents Of Selection: the Importance Of Ecology For Quantitatmentioning

confidence: 99%

The evolution of quantitative traits in complex environments

et al. 2013

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Species inhabit complex environments and respond to selection imposed by numerous abiotic and biotic conditions that vary in both space and time. Environmental heterogeneity strongly influences trait evolution and patterns of adaptive population differentiation. For example, heterogeneity can favor local adaptation, or can promote the evolution of plastic genotypes that alter their phenotypes based on the conditions they encounter. Different abiotic and biotic agents of selection can act synergistically to either accelerate or constrain trait evolution. The environmental context has profound effects on quantitative genetic parameters. For instance, heritabilities measured in controlled conditions often exceed those measured in the field; thus, laboratory experiments could overestimate the potential for a population to respond to selection. Nevertheless, most studies of the genetic basis of ecologically relevant traits are conducted in simplified laboratory environments, which do not reflect the complexity of nature. Here, we advocate for manipulative field experiments in the native ranges of plant species that differ in mating system, life-history strategy and growth form. Field studies are vital to evaluate the roles of disparate agents of selection, to elucidate the targets of selection and to develop a nuanced perspective on the evolution of quantitative traits. Quantitative genetics field studies will also shed light on the potential for natural populations to adapt to novel climates in highly fragmented landscapes. Drawing from our experience with the ecological model system Boechera (Brassicaceae), we discuss advancements possible through dedicated field studies, highlight future research directions and examine the challenges associated with field studies.

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Exogenous glucosinolate produced by Arabidopsis thaliana has an impact on microbes in the rhizosphere and plant roots

Cited by 232 publications

References 80 publications

Effects of intraspecific variation in white cabbage (Brassica oleracea var. capitata) on soil organisms

Effects of intraspecific variation in white cabbage (Brassica oleracea var. capitata) on soil organisms

Stability and succession of the rhizosphere microbiota depends upon plant type and soil composition

The evolution of quantitative traits in complex environments

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