Abstract

The effects of rare earth mining on rice biomass, rare earth element (REE) content and bacterial community structure was studied through pot experiment. The research shows that the REE content in rice roots, shoots and grains was significantly positive correlated with that in soil, and the dry weight of rice roots, shoots and grains was highly correlated with soil physical and chemical properties, nutrient elements and REE contents; The exploitation of rare earth minerals inhibited a-diversity of endophytic bacteria in rhizosphere, root, phyllosphere and leaf of rice, significantly reduced the abundance index, OTU number, Chao, Ace index and also significantly reduced the diversity index–Shannon index, and also reduced uniformity index: Pielou’s evenness index, which caused β-diversity of bacteria to be quite different. The exploitation of rare earth minerals reduces the diversity of bacteria, but forms dominant bacteria, such as Burkholderia, Bacillus, Buttiauxella, Acinetobacter, Bradyrhizobium, Candida koribacter, which can degrade the pollutants formed by exploitation of rare earth minerals, alleviate the compound pollution of rare earth and ammonia nitrogen, and also has the function of fixing nitrogen and resisting rare earth stress; The content of soil available phosphorus in no-mining area is lower, and the dominant bacteria of Pantoea formed in such soil, which has the function of improving soil phosphorus availability. Rare earth elements and physical and chemical properties of soil affect the community structure of bacteria in rhizosphere and phyllosphere of rice, promote the parallel movement of some bacteria in rhizosphere, root, phyllosphere and leaf of rice, promote the construction of community structure of bacteria in rhizosphere and phyllosphere of rice, give full play to the growth promoting function of Endophytes, and promote the growth of rice. The results showed that the exploitation of rare earth minerals has formed the dominant endophytic bacteria of rice and ensured the yield of rice in the mining area, however, the mining of mineral resources causes the compound pollution of rare earth and ammonia nitrogen, which makes REE content of rice in mining area significantly higher than that in non-mining area, and the excessive rare earth element may enter the human body through the food chain and affect human health, so the food security in the REE mining area deserves more attention.

Highlights

  • The effects of rare earth mining on rice biomass, rare earth element (REE) content and bacterial community structure was studied through pot experiment

  • It is reported that the REE content in soil of rare earth mining area in South China is 396–2314 mg/kg[8], which is much higher than the average REE content in soil of China

  • The results show that the mining of rare earth minerals can improve the REE content in soil and affect the physical and chemical properties of soil

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Summary

Introduction

The effects of rare earth mining on rice biomass, rare earth element (REE) content and bacterial community structure was studied through pot experiment. The results showed that the exploitation of rare earth minerals has formed the dominant endophytic bacteria of rice and ensured the yield of rice in the mining area, the mining of mineral resources causes the compound pollution of rare earth and ammonia nitrogen, which makes REE content of rice in mining area significantly higher than that in non-mining area, and the excessive rare earth element may enter the human body through the food chain and affect human health, so the food security in the REE mining area deserves more attention. The illegal and disorderly exploitation of rare earth resources caused large amount of rare earth elements to enter the soil and water environment, which affects the growth of plants, animals and microorganisms in the environment, changes the ecological environment and affects human health through the food c­ hain[3,4]. Endophytic bacteria can help plants polluted by heavy metals obtain bioremediation, e.g. Zhou et al.[29] found that endophytic bacteria Stenotrophomonas maltophilia R5-5 significantly reduced the Cd content in rice plants by down regulating the gene expression of cadmium absorption and transport proteins in rice and changing the community structure of endophytic bacteria, and endophytic bacteria can effectively protect plants from the toxicity of many heavy metals (Cd, Cu, Cr, Mn, Ni, Pb and Zn)[30]

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