Influences of lithium on soil microbial biomass, bacterial community structure, diversity, and function potential

Zhinan Xu, Ziqi Zhang, Si Peng, Yuan Yuan, Xiangrong Wang
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Abstract

Lithium is an emerging contaminant, but there is little knowledge about its influences on soil microbial ecosystem. In this work, soils were treated with 10 to 1280 mg/kg lithium (Li10 to Li1280), and then microbial biomass assay and bacterial 16S rRNA high-throughput sequencing analysis were conducted to investigate the influences of lithium on soil microbial biomass, bacterial community structure and diversity, and predicted function potential. The results showed that lithium generally decreased microbial biomass carbon and the count of culturable microbe colony, reflecting the reduction in microbial biomass. However, microbial biomass nitrogen increased. Meanwhile, lithium altered bacterial community composition, structure, and dominance. The abundance of phylum such as Proteobacteria and Acidobacteria respectively increased and reduced under lithium stress, while genus such as Adhaeribacter dominated in control group to Li320, and genus such as Lysobacter dominated in Li640, Li960, and Li1280. Then, higher lithium treatments consistently inhibited the bacterial richness, evenness, and diversity, and caused community dissimilarity between groups and significant down-regulation of predicted pathways. Finally, the LEfSe cladogram distinguished several indicator bacteria for different lithium levels. Overall, the influences of lithium on soil microbial community depended on its content, and microbial biomass and richness were sensitive to lower lithium, while higher lithium varied bacterial community and predicted function potential more significantly. This study will provide microbial insights into understanding lithium contamination.
锂对土壤微生物生物量、细菌群落结构、多样性和功能潜力的影响
锂是一种新兴的污染物,但对其对土壤微生物生态系统的影响知之甚少。本研究采用10 ~ 1280 mg/kg锂(Li10 ~ Li1280)处理土壤,通过微生物量测定和细菌16S rRNA高通量测序分析,探讨锂对土壤微生物量、细菌群落结构和多样性的影响,并预测其功能潜力。结果表明,锂普遍降低了微生物生物量碳和可培养微生物菌落数,反映了微生物生物量的减少。微生物量氮增加。同时,锂改变了细菌群落的组成、结构和优势。在锂胁迫下,变形菌门(Proteobacteria)和酸杆菌门(Acidobacteria)的丰度分别增加和减少,而Li320在对照组中以Adhaeribacter属为主,Li640、Li960和Li1280中以Lysobacter属为主。然后,高锂处理持续抑制细菌丰富度、均匀度和多样性,并导致组间群落差异和预测途径显著下调。最后,利用LEfSe枝状图区分了几种不同锂水平的指示菌。总体而言,锂对土壤微生物群落的影响取决于其含量,微生物生物量和丰富度对低锂敏感,而高锂对细菌群落的影响和预测功能潜力更显著。这项研究将为理解锂污染提供微生物见解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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