Variations métaboliques du maïs lors de l’association coopérative avec la bactérie phytostimulatrice Azospirillum lipoferum CRT1 / Maize metabolome variations after inoculation with the Plant Growth-Promoting Rhizobacterium Azospirillum lipoferum CRT1

Rozier, Camille

14 December 2017

Les bactéries rhizosphériques stimulatrices de croissance (PGPR) du genre Azospirillum sont utilisées commercialement pour leur capacité à stimuler la croissance et à augmenter le rendement des céréales via une relation associative complexe et peu comprise. L'objectif de cette étude a été d'utiliser les outils modernes de la métabolomique pour caractériser les mécanismes biochimiques activés par la souche A. lipoferum CRT1 chez son hôte, le maïs.L'analyse des contenus phytochimiques des racines, feuilles et sève ascendante a suggéré pour la première fois l'importance de la communication racine-feuille et des sucres simples dans l’augmentation de croissance et du potentiel de conversion photochimique de jeunes plantules par A. lipoferum CRT1. Une analyse transcriptomique a révélé un impact modéré au niveau des racines et des modifications de nombreux nœuds régulateurs des processus biologiques cellulaires des feuilles, dont ceux contrôlés par les auxines et l’acide abscissique. Des essais agronomiques conduits deux années consécutives sur quatre sites ont indiqué que l'augmentation de rendement par A. lipoferum CRT1 dérivait d’une sécurisation de la germination lors de stress environnementaux précoces et non de modifications des métabolomes (dont ceux liés à la nutrition azotée et phosphorée), de la croissance et du potentiel photosynthétique des plantules, des modifications qui étaient par contre liées aux contextes pédo-climatiques. La sécurisation de la germination était due à une accélération de la sortie de la radicule et de la consommation des sucres simples, et molécules apparentées, de la graine / Plant growth-promoting rhizobacteria (PGPR) of the genus Azospirillum are used commercially for their capacity to stimulate the growth and enhance the yield of cereal crops via an intricate, complex and poorly understood associative relationship. The aim of this study was to use modern metabolomics tools to decipher the biochemical mechanisms activated by A. lipoferum CRT1 in its maize host.The analysis of the phytochemical contents of roots, leaves and ascending sap revealed for the first time the importance of root-to-shoot communication and of simple sugars in the enhancement of growth and photochemical conversion potential of young plantlets by A. lipoferum CRT1. A transcriptomic analysis showed moderate impact on roots and a coordinate modulation of several regulatory nodes of cellular biological processes, including some mediated by auxins and abscissic acid. Agronomic field trials conducted two consecutive years in four sites correlated yield enhancement by A. lipoferum CRT1 to the securing of seed germination during environmental stresses. No correlation was found with modifications of plantlets metabolomes (including those linked to nitrogen and phosphorus nutrition), growth and photochemical conversion potential which were found to depend on additional soil and climate cues. Germination securing was due to a speeding of radicule emergence and of seed simple sugars consumption

Acide abscissique

Acide jasmonique

Architecture racinaire

Auxines

Azospirillum lipoferum

Germination

Maïs

Métabolomique

Abscissic acid

Jasmonic acid

Ascending sap

Auxins

Azospirillum lipoferum

Germination

Host specificity

Maize

571.62

Impact of free-living diazotrophs, Azospirillum lipoferum and Gluconacetobacter azotocaptans, on growth and nitrogen utilization by wheat (Triticum aestivum cv. Lillian)

2013 April 1900

Nitrogen (N) is an essential plant nutrient, widely applied as N-fertilizer to improve yields of agriculturally important crops. An alternative to fertilizer use could be the exploitation of plant growth-promoting bacteria, capable of enhancing growth and yield of many plant species. Azospirillum and Gluconacetobacter are root colonizing, free-living, N2-fixing bacteria (diazotrophs) with the potential to transfer fixed N to associated plants. The purpose of this study was to evaluate the agronomic efficiency of two diazotrophs, Azospirillum lipoferum and Gluconacetobacter azotocaptans, inoculated onto wheat. Physiological parameters and yield components were evaluated. The objectives of this study were to: 1) determine the survival of each diazotroph species on wheat seeds over time; 2) determine the survival of A. lipoferum and G. azotocaptans inoculated on wheat seed treated with a fungicide seed treatment, Dividend® XL RTA®; 3) determine if inoculation of wheat with the diazotrophs under controlled conditions causes an increase in dry matter, N2-fixation and N uptake; 4) determine if fertilizer N applied at three levels influences atmospheric N2-fixation by A. lipoferum or G. azotocaptans; 5) determine if inoculation of wheat with A. lipoferum or G. azotocaptans under field conditions causes any increase in dry matter, N2-fixation and N uptake; 6) determine if N-fertilization levels under field conditions influenced N2-fixation by A. lipoferum or G. azotocaptans. In order to meet these objectives lab, growth chamber, and field studies were completed. Laboratory investigations revealed that the decline in recovery of colony forming units (CFU) of G. azotocaptans was not significantly different (P<0.05) for any seed treatment. There was a general decrease in CFU over time regardless of seed treatment. Analysis of the recovered CFU of A. lipoferum over time showed that there was a significant difference (P<0.05) between both the non-sterilized seed and the Dividend® XL RTA® treated seed when compared sterilized seed. Recovery of CFU on sterilized seed declined at a more rapid rate compared to the other two seed treatments. Gluconacetobacter azotocaptans and A. lipoferum were not negatively influenced by the Dividend® XL RTA® seed treatment. Also, both diazotrophs were able to compete with other microorganisms that may have been on the seed coat of unsterilized seeds. Azospirillum lipoferum and G. azotocaptans were able to fix atmospheric N, but, there were no significant (P<0.05) differences between the diazotroph species. Additions of fertilizer N enhanced N2-fixation, in both the growth chamber and field studies. As the amount of fertilizer N increased, so did the %Ndfa and N uptake. In the growth chamber study, inoculated wheat, and fertilized with 12.2 and 24.5 µg N g-1 had the highest %Ndfa of 25.5%, and wheat fertilized with 24 µg N g-1 had the highest N uptake (1.3 g pot-1) at maturity. In the field study, inoculated wheat fertilized with of 80 kg N ha-1 had significantly higher (P<0.05) %Ndfa (10.5%) compared to wheat grown with the other fertilizer levels, which also corresponded to the highest N uptake in wheat plants (47 kg ha-1). The diazotrophs also affected the partitioning of N in the wheat plants differently. Wheat inoculated with A. lipoferum had significantly higher (P<0.05) amounts of N accumulated in heads of plants, and wheat inoculated with G. azotocaptans had significantly higher (P<0.05) amounts of N accumulated in stems of plants. However, this trend was not evident in the field study.

diazotrophs

Azospirillum lipoferum

Gluconacetobacter azotocaptans

nitrogen fixation

dry matter

%Ndfa

growth chamber

field experiment

fertilizer application