Plant secondary metabolite-dependent plant-soil feedbacks can improve crop yield in the field

Gfeller, Valentin; Waelchli, Jan; Pfister, Stephanie; Deslandes‐Hérold, Gabriel; Mascher, Fabio; Glauser, Gaëtan; Aeby, Yvo; Mestrot, Adrien; Robert, Christelle; Schlaeppi, Klaus; Erb, Matthias

doi:10.1101/2022.11.09.515047

Cited by 10 publications

(22 citation statements)

References 61 publications

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“…We had originally discovered benzoxazinoid-dependent and microbe-driven feedbacks on plant performance in controlled conditions 11 and recently, we show that they also operate in field conditions increasing wheat yield in certain soils 38 . The latter suggest that microbial feedbacks are agriculturally relevant and highlights that plant specialised metabolites present a strong tool for leveraging microbiome functions.…”

Section: Discussionmentioning

confidence: 88%

The lactonase BxdA mediates metabolic adaptation of maize root bacteria to benzoxazinoids

Thoenen,

Kreuzer,

Florean

et al. 2023

Preprint

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Root exudates contain secondary metabolites that affect the plant's root microbiome. How microbes cope with these bioactive compounds, and how this ability shapes root microbiomes remain largely unknown. We investigated how maize root bacteria metabolise benzoxazinoids, the main specialised metabolites of maize. Diverse and abundant bacteria metabolised the major compound (6-methoxy-benzoxazolin-2-one, MBOA) in the maize rhizosphere to 2-amino-7-methoxyphenoxazin-3-one (AMPO). By contrast, bacteria isolated from Arabidopsis, which does not produce benzoxazinoids, were unable to metabolise MBOA. Among Microbacteria strains, this differential metabolisation allowed to identify a conserved gene cluster containing the lactonase bxdA. BxdA converts MBOA to AMPO in vitro and we show that this capacity provided bacteria a growth benefit under carbon-limiting conditions. Together these results reveal that maize root bacteria - through BxdA - are metabolically adapted to the benzoxazinoids of their host. We propose that metabolic adaptation to plant-specialised compounds shapes root bacterial communities across the plant kingdom.

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Section: Discussionmentioning

confidence: 88%

The lactonase BxdA mediates metabolic adaptation of maize root bacteria to benzoxazinoids

Thoenen,

Kreuzer,

Florean

et al. 2023

Preprint

Self Cite

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“…In our work, we find that one single group of secondary metabolites controlled by one single gene (Bx1) determines the resistance of maize against negative plant-soil feedbacks. Given that the same metabolites can increase agricultural productivity of the following crop (Gfeller et al, 2022), this makes the genes involved in biosynthesis and exudation of such metabolites a potential breeding target for superior crop rotations. Many maize lines already produce substantial amounts of benzoxazinoids in their roots, but substantial genetic variation is commonly observed (Handrick et al, 2016).…”

Section: Discussionmentioning

confidence: 99%

“…Benzoxazinoids extracted from soils and the purified benzoxazinoid mixture from germinated maize kernels were analysis as described before (Gfeller et al, 2022). In short, an Acquity UHPLC system coupled to a G2-XS QTOF mass spectrometer equipped with an electrospray source and piloted by the software MassLynx 4.1 (Waters AG, Baden-Dättwil, Switzerland) was used.…”

Section: Analysis Of Benzoxazinoidsmentioning

confidence: 99%

“…For benzoxazinoids and flavones these changes were linked to the performance of succeeding conspecific plants (Hu et al, 2018b;Yu et al, 2021). Through plant-soil feedbacks, the trait of benzoxazinoid exudation in maize also affects wheat performance under controlled conditions and improves wheat yield under field conditions (Cadot et al, 2021a;Gfeller et al, 2022). Considering that benzoxazinoids can structure the rhizosphere microbiome of maize already at the seedling stage (Cotton et al, 2019;Kudjordjie et al, 2019), that benzoxazinoids can act fungistatic against soil pathogens (Wilkes et al, 1999;Martyniuk et al, 2006), and that benzoxazinoids can attract a Pseudomonas putida strain that potentially induces plant resistance (Neal et al, 2012;Neal & Ton, 2013), we hypothesize that they could also increase crop rotation stability by alleviating negative plant-soil feedbacks.…”

Section: Introductionmentioning

confidence: 99%

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Root-exuded secondary metabolites can alleviate negative plant-soil feedbacks

Gfeller

Thönen

Erb

2023

Preprint

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Plants can suppress the growth of other plants by modifying soil properties. These negative plant-soil feedbacks are often species-specific, suggesting that some plants possess resistance strategies. However, the underlying mechanisms remain largely unknown. Here, we investigated if and how benzoxazinoids, a class of dominant secondary metabolites that are exuded into the soil by maize and other cereals, help plants to resist negative plant-soil feedbacks. We find that three out of five tested crop species suppress maize performance relative to the mean across species. This effect is partially alleviated by the plant's capacity to produce benzoxazinoids. Soil complementation of benzoxazinoid-deficient mutants with purified benzoxazinoids is sufficient to restore the protective effect. Sterilization and reinoculation experiments suggest that benzoxazinoid-mediated protection acts via changes in soil microbes. Substantial variation of the protective effect between experiments and soil types illustrates that the magnitude of the protective effect of benzoxazinoids against negative plant-soil feedbacks is context dependent. In summary, our study demonstrates that plant secondary metabolites can confer resistance to negative plant-soil feedbacks. These findings expand the functional repertoire of plant secondary metabolites, reveal a mechanism by which plants can resist suppressive soils, and may represent a promising avenue to stabilize plant performance in crop rotations in the future.

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“…diurnal and seasonal variations in plant and microbial activities). Beyond a few specific examples of allelopathic soil chemical legacies on plant growth (Hierro & Callaway, 2021; Zhang et al ., 2021), our knowledge of the persistence and role of nontoxic legacies in regulating plant growth, foraging and life history traits is limited (Renne et al ., 2014; Semchenko et al ., 2014; Delory et al ., 2021; Gfeller et al ., 2023b). Soil metabolites can also have indirect effects on plants by affecting the structure and functioning of soil microbial communities, as well as soil nutrient availability (Inderjit & Weiner, 2001; Hu et al ., 2018).…”

Section: Definition and Mechanisms Of Soil Chemical Legaciesmentioning

confidence: 99%

A trait‐based framework linking the soil metabolome to plant–soil feedbacks

Delory,

Callaway,

Semchenko

2023

New Phytologist

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SummaryBy modifying the biotic and abiotic properties of the soil, plants create soil legacies that can affect vegetation dynamics through plant–soil feedbacks (PSF). PSF are generally attributed to reciprocal effects of plants and soil biota, but these interactions can also drive changes in the identity, diversity and abundance of soil metabolites, leading to more or less persistent soil chemical legacies whose role in mediating PSF has rarely been considered. These chemical legacies may interact with microbial or nutrient legacies to affect species coexistence. Given the ecological importance of chemical interactions between plants and other organisms, a better understanding of soil chemical legacies is needed in community ecology. In this Viewpoint, we aim to: highlight the importance of belowground chemical interactions for PSF; define and integrate soil chemical legacies into PSF research by clarifying how the soil metabolome can contribute to PSF; discuss how functional traits can help predict these plant–soil interactions; propose an experimental approach to quantify plant responses to the soil solution metabolome; and describe a testable framework relying on root economics and seed dispersal traits to predict how plant species affect the soil metabolome and how they could respond to soil chemical legacies.

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Plant secondary metabolite-dependent plant-soil feedbacks can improve crop yield in the field

Cited by 10 publications

References 61 publications

The lactonase BxdA mediates metabolic adaptation of maize root bacteria to benzoxazinoids

The lactonase BxdA mediates metabolic adaptation of maize root bacteria to benzoxazinoids

Root-exuded secondary metabolites can alleviate negative plant-soil feedbacks

A trait‐based framework linking the soil metabolome to plant–soil feedbacks

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