The structure of the Brassica napus seed microbiome is cultivar-dependent and affects the interactions of symbionts and pathogens

Rybakova, Daria; Mancinelli, Riccardo; Wikström, M.; Birch-Jensen, Ann-Sofie; Postma, J.; Ehlers, Ralf‐Udo; Goertz, Simon; Berg, Gabriele

doi:10.1186/s40168-017-0310-6

Cited by 146 publications

(136 citation statements)

References 43 publications

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“…Among the host‐specific factors, the genetic background of seeds may be the most important. Species‐specific, cultivar‐specific, and even genotype‐specific components have been found within the plant microbiome (Andreote & Pereira E Silva, ; Berg & Smalla, ; Cardinale, Grube, Erlacher, Quehenberger, & Berg, ; Lundberg et al., ; Rybakova et al., ; Smalla et al., ), suggesting that the genetic background of plants plays a key role in modulating the composition and structure of the seed mycobiota (Oren, Ezrati, Cohen, & Sharon, ; Peiffer et al., ). Our multi‐year seed stocks were all the same maize variety (Zheng58) and thus shared the same host genetic background.…”

Section: Discussionmentioning

confidence: 99%

“…A vast diversity of microorganisms colonize all organs of plants; these microorganisms constitute the plant microbiome and play an integral role in plant growth and health (Berg, Rybakova, Grube, & Koberl, ; Mendes et al., ; Rybakova et al., ; Sánchez‐Cañizares, Jorrín, Poole, & Tkacz, ). Recently, great efforts have been made to understand the plant microbiome, and the microbiota diversity of different tissues and developmental stages has been described for many plants, including major crops such as rice (Edwards et al., ), maize (Peiffer et al., ), barley (Bulgarelli et al., ), and soybean (Han et al., ; Liu et al., ; Sugiyama, Ueda, Takase, & Yazaki, ).…”

Section: Introductionmentioning

confidence: 99%

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Mycobiota of maize seeds revealed by rDNA‐ITS sequence analysis of samples with varying storage times

Hui-qin

Ma²,

et al. 2018

MicrobiologyOpen

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Fungi are an integral component of the plant microbiome. However, the composition and variation in the fungal communities (mycobiota) associated with seeds are poorly understood. In this study, we investigated the mycobiota of 11 maize seed samples with storage times ranging from 6 months to 12 years. Mycobiota were characterized by a culture-based approach, and fungal species were identified through rDNA-ITS sequence analyses. From a total of 169 pure fungal isolates obtained from both the seed surface and internal tissues, we identified 16 distinct species (belonging to 10 genera) associated with maize seeds, all but one of which were ascomycetes. Among these species, seven were exclusively isolated from internal tissues, two species were isolated only from the seed surface, and another six species were isolated from both the surface and internal tissues. Aspergillus niger was consistently found under all storage conditions and dominated fungal communities with a relative abundance of 36%-100%. Species of Fusarium (9%-40%) and Penicillium (9%-20%) were also frequently isolated, but other species appeared sporadically and were isolated from fewer than three seed stocks. According to our results, while the overall incidence of fungal infection generally declined with storage time, there was no consistent association between seed storage time and fungal species richness or relative abundance; furthermore, the composition of the mycobiota associated with maize seeds was highly variable among the samples. The detection of the four major mycotoxigenic fungal genera, specifically Aspergillus, Fusarium, Penicillium, and Alternaria, was alarming, and the isolation of a potential controlling agent as well as information about their temporal occurrence will contribute to the management of mycotoxins in the future.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Mycobiota of maize seeds revealed by rDNA‐ITS sequence analysis of samples with varying storage times

Hui-qin

Ma²,

et al. 2018

MicrobiologyOpen

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“…However, the underlying mechanism is unclear. Recent studies confirm that some endophytic bacterial genera such as Enterobacter, Pantoea, Pseudomonas, and Citrobacter present in seeds are derived from the rhizosphere microbial community of plant hosts (Johnston-Monje and Raizada, 2011; Adam et al, 2018;Rybakova et al, 2017). Enterobacter asburiae from seeds of different maize (Zea mays) cultivars was established in the rhizosphere after seeding (Johnston-Monje and Raizada, 2011).…”

Section: Genesis Of 'Microbiota-induced Soil Inheritance' (Misi)mentioning

confidence: 97%

Inheritance of seed and rhizosphere microbial communities through plant–soil feedback and soil memory

Kong

Song

Ryu

2019

Environ Microbiol Rep

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Summary Since the discovery of the role of microbes in the phytobiome, microbial communities (microbiota) have been identified and characterized based on host species, development, distribution, and condition. The microbiota in the plant rhizosphere is believed to have been established prior to seed germination and innate immune development. However, the microbiota in seeds has received little attention. Although our knowledge of the distribution of microbiota in plant seeds and rhizosphere is currently limited, the impact of these microbiota is likely to be greater than expected. This minireview suggests a new function of microbial inheritance from the seed to root and from the first generation of plants to the next. Surprisingly, recruitment and accumulation of microbiota by biotic and abiotic stresses affect plant immunity in the next generation through plant–soil feedback and soil memory. To illustrate this process, we propose a new term called ‘microbiota‐induced soil inheritance (MISI).’ A comprehensive understanding of MISI will provide novel insights into plant–microbe interactions and plant immunity inheritance.

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“…Furthermore, host genetics has been shown to influence the plant and root microbiome strongly (Rybakova et al, 2017;Sapkota et al, 2015;Wagner et al, 2016), mostly because the cultivars considered differ for other traits in addition to resistance to a plant pathogen. The use of nearisogenic lines differing only by the presence or absence of a specific resistance gene was therefore expected to limit the 'genotype' effect (Newton et al, 2010) and appeared to be the best technical solution in this case.…”

Section: Discussionmentioning

confidence: 99%

Impact of a resistance gene against a fungal pathogen on the plant host residue microbiome: the case of theLeptosphaeria maculans-Brassica napuspathosystem

Kerdraon

Barret

Balesdent

et al. 2020

Preprint

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Oilseed rape residues are a crucial determinant of stem canker epidemiology, as they support the sexual reproduction of the fungal pathogen Leptosphaeria maculans. The aim of this study was to characterise the impact of a resistance gene against L. maculans infection on residue microbial communities and to identify micro-organisms interacting with this pathogen during residue degradation. We used near-isogenic lines to obtain healthy and infected host plants. The microbiome associated with the two types of plant residues was characterised by metabarcoding. A combination of linear discriminant analysis and ecological network analysis was used to compare the microbial communities and to identify micro-organisms interacting with L. maculans. Fungal community structure differed between the two lines at harvest, but not subsequently, suggesting that the presence/absence of the resistance gene influences the microbiome at the base of the stem whilst the plant is alive, but that this does not necessarily lead to differential colonisation of the residues by fungi. Direct interactions with other members of the community involved many fungal and bacterial ASVs (amplicon sequence variants). L. maculans appeared to play a minor role in networks, whereas one ASV affiliated to Plenodomus biglobosus (synonym Leptosphaeria biglobosa) from the Leptosphaeria species complex was considered a keystone taxon in the networks at harvest. This approach could be used to identify and promote micro-organisms with beneficial effects against residue-borne pathogens, and more broadly, to decipher the complex interactions between multi-species pathosystems and other microbial components in crop residues.

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The structure of the Brassica napus seed microbiome is cultivar-dependent and affects the interactions of symbionts and pathogens

Cited by 146 publications

References 43 publications

Mycobiota of maize seeds revealed by rDNA‐ITS sequence analysis of samples with varying storage times

Mycobiota of maize seeds revealed by rDNA‐ITS sequence analysis of samples with varying storage times

Inheritance of seed and rhizosphere microbial communities through plant–soil feedback and soil memory

Impact of a resistance gene against a fungal pathogen on the plant host residue microbiome: the case of theLeptosphaeria maculans-Brassica napuspathosystem

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