Metabolic profiling of two maize (Zea mays L.) inbred lines inoculated with the nitrogen fixing plant-interacting bacteria Herbaspirillum seropedicae and Azospirillum brasilense

Brusamarello-Santos, Liziane Cristina Campos; Gilard, Françoise; Brulé, Lénaïg; Quilleré, Isabelle; Gourion, Benjamin; Ratet, Pascal; Souza, Emanuel Maltempi de; Lea, Peter J.; Hirel, Bertrand

doi:10.1371/journal.pone.0174576

Cited by 75 publications

(49 citation statements)

References 75 publications

(78 reference statements)

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“…This research should be carried out before glasshouse or field studies using natural soils, when interaction with the microbiome 9 and the neighboring plants are much more complex. Such investigations could be first conducted using microcosms [34] and well-controlled gnotobiotic systems similar to those recently developed for non-symbiotic N2-fixing associations [35], (Figure 1). These two experimental systems could then be adapted to study the interaction between a mixture of several plant species and multiple fungal partners both at the molecular and physiological levels, thus gradually increasing the complexity of the plant/AMF symbiotic association.…”

Section: The Complexity Of Nutrient Uptake In a Plant-fungal Symbiosismentioning

confidence: 99%

“…Therefore, the type of N fertilization is an important factor that controls both AMF colonization and biological activity in terms of N uptake efficiency [34]. Using the controlled experimental systems described in Figure 1 [34,35], it will be interesting, to study the physiological and regulatory mechanisms that control N uptake by the fungi and its transfer to the host plant when the mineral N is low, or when there are high concentrations of amino acids or carbohydrates present in the growth medium.…”

Section: Interactions Between Arbuscular Mycorrhizal Fungi and Plant mentioning

confidence: 99%

“…Studies need to be first conducted in an appropriate microcosm and well-controlled experimental systems involving one fungal species and one plant partner, such as those presented in section 2 (Fig. 1), [34,35] using increasing N concentrations in order to understand the mechanisms of C/N exchange in AMF [100]. Using such a kind of experimental systems, it will be possible to assess the benefit of a given plant/fungal symbiotic association and then to select and study the best ones by means of holistic, physiological and systems biology approaches including modeling studies [99].…”

mentioning

confidence: 99%

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Agricultural practices to improve nitrogen use efficiency through the use of arbuscular mycorrhizae: Basic and agronomic aspects

Verzeaux¹,

Hirel²,

Dubois³

et al. 2017

Plant Science

Self Cite

104

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Nitrogen cycling in agroecosystems is heavily dependent upon arbuscular mycorrhizal fungi (AMF) present in the soil microbiome. These fungi develop obligate symbioses with various host plant species, thus increasing their ability to acquire nutrients. However, AMF are particularly sensitive to physical, chemical and biological disturbances caused by human actions that limit their establishment. For a more sustainable agriculture, it will be necessary to further investigate which agricultural practices could be favorable to maximize the benefits of AMF to improve crop nitrogen use efficiency (NUE), thus reducing nitrogen (N) fertilizer usage. Direct seeding, mulch-based cropping systems prevent soil mycelium disruption and increase AMF propagule abundance. Such cropping systems lead to more efficient root colonization by AMF and thus a better establishment of the plant/fungal symbiosis. In addition, the use of continuous cover cropping systems can also enhance the formation of more efficient interconnected hyphal networks between mycorrhizae colonized plants. Taking into account both fundamental and agronomic aspects of mineral nutrition by plant/AMF symbioses, we have critically described, how improving fungal colonization through the reduction of soil perturbation and maintenance of an ecological balance could be helpful for increasing crop NUE.

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Section: The Complexity Of Nutrient Uptake In a Plant-fungal Symbiosismentioning

confidence: 99%

Section: Interactions Between Arbuscular Mycorrhizal Fungi and Plant mentioning

confidence: 99%

mentioning

confidence: 99%

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Agricultural practices to improve nitrogen use efficiency through the use of arbuscular mycorrhizae: Basic and agronomic aspects

Verzeaux¹,

Hirel²,

Dubois³

et al. 2017

Plant Science

Self Cite

104

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“…There have been some analyses that explore a maize plant's response to specific environmental conditions such as salinity, heat, and drought (Sun, Li, et al, 2016b;Witt et al, 2012), nitrogen (Amiour et al, 2012;Brusamarello-Santos et al, 2017;Simons et al, 2014) and low phosphorus (Ganie et al, 2015) by monitoring the relationships of these environmental factors to those of metabolites and transcripts. Further examinations have begun to characterize the breadth of diversity of various inbreds and hybrids across typical agronomic environments particularly emphasizing these effectors on grain and forage composition (Asiago, Hazebroek, Harp, & Zhong, 2012;Baniasadi, Vlahakis, Hazebroek, Zhong, & Asiago, 2014;Benevenuto et al, 2017;Hall et al, 2016;Tang et al, 2017;Venkatesh et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Evaluating maize phenotypic variance, heritability, and yield relationships at multiple biological scales across agronomically relevant environments

Tucker

Dohleman

Flagel

et al. 2020

Plant Cell & Environment

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A challenge to improve an integrative phenotype, like yield, is the interaction between the broad range of possible molecular and physiological traits that contribute to yield and the multitude of potential environmental conditions in which they are expressed. This study collected data on 31 phenotypic traits, 83 annotated metabolites, and nearly 22,000 transcripts from a set of 57 diverse, commercially relevant maize hybrids across three years in central U.S. Corn Belt environments. Although variability in characteristics created a complex picture of how traits interact produce yield, phenotypic traits and gene expression were more consistent across environments, while metabolite levels showed low repeatability. Phenology traits, such as green leaf number and grain moisture and whole plant nitrogen content showed the most consistent correlation with yield. A machine learning predictive analysis of phenotypic traits revealed that ear traits, phenology, and root traits were most important to predicting yield. Analysis suggested little correlation between biomass traits and yield, suggesting there is more of a sink limitation to yield under the conditions studied here. This work suggests that continued improvement of maize yields requires a strong understanding of baseline variation of plant characteristics across commercially‐relevant germplasm to drive strategies for consistently improving yield.

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“…The comprehensive high‐throughput analysis technologies, such as ultra‐high performance liquid chromatography–quadrupole time‐of‐flight mass spectrometry (UPLC‐QTOF‐MS) and gas chromatography–mass spectrometry (GC‐MS), allow us to accurately measure vast metabolite profiles (the metabolome), which in turn facilitates the study of complex trait regulation via the ‘gene–metabolism–phenotype’ research model. In the case of Zea mays (maize), metabolomics has been used for the characterization of responses to abiotic stress and inoculation with nitrogen‐fixing plant‐interacting bacteria (Ganie et al ., ; Obata et al ., ; Brusamarello‐Santos et al ., ), the association of leaf physiology with kernel yield, the complex metabolism of the maize kernel (Wen et al ., , ; Cañas et al ., ) and the mechanism for the induction of genotype‐dependent embryonic callus (Ge et al ., ). Additionally, previous studies on the metabolic variations under low‐Pi conditions have been conducted in Arabidopsis and white lupin (Müller et al ., ; Pant et al ., ).…”

Section: Introductionmentioning

confidence: 99%

Metabolite profiling and genome‐wide association studies reveal response mechanisms of phosphorus deficiency in maize seedling

Luo

Nie

et al. 2019

The Plant Journal

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SUMMARYInorganic phosphorus (Pi) is an essential element in numerous metabolic reactions and signaling pathways, but the molecular details of these pathways remain largely unknown. In this study, metabolite profiles of maize (Zea mays L.) leaves and roots were compared between six low‐Pi‐sensitive lines and six low‐Pi‐tolerant lines under Pi‐sufficient and Pi‐deficient conditions to identify pathways and genes associated with the low‐Pi stress response. Results showed that under Pi deprivation the concentrations of nucleic acids, organic acids and sugars were increased, but that the concentrations of phosphorylated metabolites, certain amino acids, lipid metabolites and nitrogenous compounds were decreased. The levels of secondary metabolites involved in plant immune reactions, including benzoxazinoids and flavonoids, were significantly different in plants grown under Pi‐deficient conditions. Among them, the 11 most stable metabolites showed significant differences under low‐ and normal‐Pi conditions based on the coefficient of variation (CV). Isoleucine and alanine were the most stable metabolites for the identification of Pi‐sensitive and Pi‐resistant maize inbred lines. With the significant correlation between morphological traits and metabolites, five low‐Pi‐responding consensus genes associated with morphological traits and simultaneously involved in metabolic pathways were mined by combining metabolites profiles and genome‐wide association study (GWAS). The consensus genes induced by Pi deficiency in maize seedlings were also validated by reverse‐transcription quantitative polymerase chain reaction (RT‐qPCR). Moreover, these genes were further validated in a recombinant inbred line (RIL) population, in which the glucose‐6‐phosphate‐1‐epimerase encoding gene mediated yield and correlated traits to phosphorus availability. Together, our results provide a framework for understanding the metabolic processes underlying Pi‐deficient responses and give multiple insights into improving the efficiency of Pi use in maize.

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Metabolic profiling of two maize (Zea mays L.) inbred lines inoculated with the nitrogen fixing plant-interacting bacteria Herbaspirillum seropedicae and Azospirillum brasilense

Cited by 75 publications

References 75 publications

Agricultural practices to improve nitrogen use efficiency through the use of arbuscular mycorrhizae: Basic and agronomic aspects

Agricultural practices to improve nitrogen use efficiency through the use of arbuscular mycorrhizae: Basic and agronomic aspects

Evaluating maize phenotypic variance, heritability, and yield relationships at multiple biological scales across agronomically relevant environments

Metabolite profiling and genome‐wide association studies reveal response mechanisms of phosphorus deficiency in maize seedling

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