Identification of Heterotrophic Zinc Mobilization Processes among Bacterial Strains Isolated from Wheat Rhizosphere (Triticum aestivum L.).

Costerousse, Benjamin; Schönholzer-Mauclaire, Laurie; Frossard, Emmanuel; Thonar, Cécile

doi:10.1128/AEM.01715-17

Article (Scientific journals)

Identification of Heterotrophic Zinc Mobilization Processes among Bacterial Strains Isolated from Wheat Rhizosphere (Triticum aestivum L.).

Costerousse, Benjamin; Schönholzer-Mauclaire, Laurie; Frossard, Emmanuel et al.

2018 • In Applied and Environmental Microbiology, 84 (1)

Peer Reviewed verified by ORBi

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https://hdl.handle.net/2268/290283

DOI
10.1128/AEM.01715-17

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29079619

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Keywords :

MALDI-TOF MS; biofortification; bioremediation; metal solubilization; organic acids; proton extrusion; siderophores; wheat; zinc-solubilizing bacteria; Zinc; Bacteria/isolation & purification; Bacteria/metabolism; Triticum/metabolism; Triticum/microbiology; Zinc/metabolism; Rhizosphere; Soil Microbiology; MALDI TOF MS; Bacteria; Triticum; Biotechnology; Food Science; Applied Microbiology and Biotechnology; Ecology

Abstract :

[en] Soil and plant inoculation with heterotrophic zinc-solubilizing bacteria (ZSB) is considered a promising approach for increasing zinc (Zn) phytoavailability and enhancing crop growth and nutritional quality. Nevertheless, it is necessary to understand the underlying bacterial solubilization processes to predict their repeatability in inoculation strategies. Acidification via gluconic acid production remains the most reported process. In this study, wheat rhizosphere soil serial dilutions were plated on several solid microbiological media supplemented with scarcely soluble Zn oxide (ZnO), and 115 putative Zn-solubilizing isolates were directly detected based on the formation of solubilization halos around the colonies. Eight strains were selected based on their Zn solubilization efficiency and siderophore production capacity. These included one strain of Curtobacterium, two of Plantibacter, three strains of Pseudomonas, one of Stenotrophomonas, and one strain of Streptomyces In ZnO liquid solubilization assays, the presence of glucose clearly stimulated organic acid production, leading to medium acidification and ZnO solubilization. While solubilization by Streptomyces and Curtobacterium was attributed to the accumulated production of six and seven different organic acids, respectively, the other strains solubilized Zn via gluconic, malonic, and oxalic acids exclusively. In contrast, in the absence of glucose, ZnO dissolution resulted from proton extrusion (e.g., via ammonia consumption by Plantibacter strains) and complexation processes (i.e., complexation with glutamic acid in cultures of Curtobacterium). Therefore, while gluconic acid production was described as a major Zn solubilization mechanism in the literature, this study goes beyond and shows that solubilization mechanisms vary among ZSB and are strongly affected by growth conditions.IMPORTANCE Barriers toward a better understanding of the mechanisms underlying zinc (Zn) solubilization by bacteria include the lack of methodological tools for isolation, discrimination, and identification of such organisms. Our study proposes a direct bacterial isolation procedure, which prevents the need to screen numerous bacterial candidates (for which the ability to solubilize Zn is unknown) for recovering Zn-solubilizing bacteria (ZSB). Moreover, we confirm the potential of matrix-assisted laser desorption ionization-time of flight mass spectrometry (MALDI-TOF MS) as a quick and accurate tool for the identification and discrimination of environmental bacterial isolates. This work also describes various Zn solubilization processes used by wheat rhizosphere bacteria, including proton extrusion and the production of different organic acids among bacterial strains. These processes were also clearly affected by growth conditions (i.e., solid versus liquid cultures and the presence and absence of glucose). Although highlighted mechanisms may have significant effects at the soil-plant interface, these should only be transposed cautiously to real ecological situations.

Disciplines :

Microbiology

Author, co-author :

Costerousse, Benjamin ; Group of Plant Nutrition, Institute of Agricultural Sciences (IAS), ETH Zurich, Lindau, Switzerland benjamin.costerousse@usys.ethz.ch cecile.thonar@ulg.ac.be

Schönholzer-Mauclaire, Laurie; Group of Plant Nutrition, Institute of Agricultural Sciences (IAS), ETH Zurich, Lindau, Switzerland

Frossard, Emmanuel; Group of Plant Nutrition, Institute of Agricultural Sciences (IAS), ETH Zurich, Lindau, Switzerland

Thonar, Cécile ; Université de Liège - ULiège > Agronomie, Bio-ingénierie et Chimie (AgroBioChem) > Plant Sciences

Language :

English

Title :

Identification of Heterotrophic Zinc Mobilization Processes among Bacterial Strains Isolated from Wheat Rhizosphere (Triticum aestivum L.).

Publication date :

01 January 2018

Journal title :

Applied and Environmental Microbiology

ISSN :

0099-2240

eISSN :

1098-5336

Publisher :

American Society for Microbiology, United States

Volume :

Issue :

Peer reviewed :

Peer Reviewed verified by ORBi

Additional URL :

https://journals.asm.org/doi/pdf/10.1128/AEM.01715-17

Funding text :

WFSC Mercator Research Program

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