Diversity and Composition of Soil Bacteria Between Abandoned and Selective-farming Farmlands in an Antimony Mining Area

Overview

Journal Front Microbiol

Specialty Microbiology

Date 2022 Aug 8

PMID 35935219

Authors

Renyan Duan

Yihuan Du

Zhiwei Chen

Yaqi Zhang

Wei Hu

Li Yang

Guohong Xiang

Yucai Luo

Affiliations

Soon will be listed here.

Abstract

Background And Aims: Land abandonment and selective farming are two common management methods to restore the soil conditions of low-pollution farmland in mining areas. The soil bacterial community plays an important role in farmland soil restoration; however, few studies have compared the composition and diversity of soil bacteria between the abandoned farmlands (AFS) and selective-farming farmlands (FFS). Here, the effects of AFS and FFS on soil properties and bacterial diversity were evaluated in an antimony (Sb) mining area in southern China. This study aimed to identify effective land management methods in terms of positive or negative changes in soil environment and bacterial diversity.

Methods: 16S rRNA high-throughput sequencing was used to compare the diversity and composition of soil bacteria between AFS and FFS in the Xikuangshan (the largest Sb mine in the world).

Results: Compared to AFS, FFS had higher Sb concentration and nutritional properties (e.g., available N, P, and K) and lower Zn concentration ( < 0.05). The bacterial alpha diversity including Chao1 index, Simpson index, Shannon index and Pieloue index in FFS was higher than AFS ( < 0.05). At the phylum level, FFS had higher relative abundances of , , , and , and lower relative abundances of , , and . At the genus level, FFS had higher relative abundances of , , and , and lower relative abundances of , , , and . Redundancy analysis indicated that soil heavy metal content and soil fertility were closely correlated with the soil bacterial community. Altogether, selective farming of low-pollution farmland in the mining area can improve soil properties and soil bacterial diversity.

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