Arbuscular mycorrhizal fungi alter microbiome structure of rhizosphere soil to enhance maize tolerance to La

Rhizosphere microbes are essential partners for plant stress tolerance. Recent studies indicate that arbuscular mycorrhizal fungi (AMF) can facilitate the revegetation of soils contaminated by heavy metals though interacting with rhizosphere microbiome. However, it is unclear how AMF affect rhizosph...

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Published in:Ecotoxicology and environmental safety 2021-04, Vol.212, p.111996, Article 111996
Main Authors: Hao, Lijun, Zhang, Zhechao, Hao, Baihui, Diao, Fengwei, Zhang, Jingxia, Bao, Zhihua, Guo, Wei
Format: Article
Language:English
Subjects:
Arbuscular mycorrhizal fungi (AMF)
Bacteria - growth & development
Biodegradation, Environmental
Biomass
Fungi - growth & development
Glomeromycota - growth & development
Lanthanum (La)
Lanthanum - analysis
Lanthanum - toxicity
Microbiota
Mycorrhizae - physiology
Plant Roots - chemistry
Plant Roots - microbiology
Rhizosphere
Rhizosphere bacterial community
Rhizosphere fungal community
Soil - chemistry
Soil Microbiology
Soil Pollutants - analysis
Soil Pollutants - toxicity
Zea mays - drug effects
Zea mays - growth & development
Zea mays - microbiology
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Summary:Rhizosphere microbes are essential partners for plant stress tolerance. Recent studies indicate that arbuscular mycorrhizal fungi (AMF) can facilitate the revegetation of soils contaminated by heavy metals though interacting with rhizosphere microbiome. However, it is unclear how AMF affect rhizosphere microbiome to improve the growth of plant under rare earth elements (REEs) stress. AMF (Claroideoglomus etunicatum) was inoculated to maize grown in soils spiked with Lanthanum (0 mg kg−1, La0; 10 mg kg−1, La10; 100 mg kg−1, La100; 500 mg kg−1, La500). Plant biomass, nutrient uptake, REE uptake and rhizosphere bacterial and fungal community were evaluated. The results indicated that La100 and La500 decreased significantly root colonization rates and nutrition uptake (K, P, Ca and Mg content). La500 decreased significantly α-diversity indexes of bacterial and fungal community. AMF enhanced significantly the shoot and root fresh and dry weight of maize in all La treatments (except for the root fresh and dry weight of La0 and La10 treatment). For La100 and La500 treatments, AMF increased significantly nutrition uptake (K, P, Ca and Mg content) in shoot of maize by 27.40–441.77%. For La500 treatment, AMF decreased significantly shoot La concentration by 51.53% in maize, but increased significantly root La concentration by 30.45%. In addition, AMF decreased bacterial and fungal Shannon index in La0 treatment, but increased bacterial Shannon index in La500 treatment. Both AMF and La500 affected significantly the bacterial and fungal community composition, and AMF led to more influence than La. AMF promoted the enrichment of bacteria, including Planomicrobium, Lysobacter, Saccharothrix, Agrococcus, Microbacterium, Streptomyces, Penicillium and other unclassified genus, and fungi (Penicillium) in La500, which showed the function for promoting plant growth and tolerance of heavy metal. The study revealed that AMF can regulate the rhizosphere bacterial and fungal composition and foster certain beneficial microbes to enhance the tolerance of maize under La stress. Phytoremediation assisted by AMF is an attractive approach to ameliorate REEs-contaminated soils. [Display omitted] •La100 and La500 decreased root colonization rates and nutrition uptake of maize.•AMF promoted growth and nutrition uptake of maize in different La-stressed soil.•AMF and La500 significantly altered α-diversity indexes and rhizosphere microbiome.•Microbial community structure was mainly influenc
ISSN:0147-6513
1090-2414
DOI:10.1016/j.ecoenv.2021.111996