Relation analysis of bacterial community in soils of coal mines with potential ecological risk from heavy metals

Abstract

Coal consumption increases consistently, and heavy metal contamination in soils surrounding coal mines has been a severe environmental issue. Investigation of the relations of the bacterial community in soils of coal mines with potential ecological risk from heavy metals is essential for better understanding the impact of coal production on ecosystem health. In this study, soils surrounding two coal mines in a typical coal industry city of China were sampled, and heavy metals (Cd, Cr, Ni, Cu, Zn, As, and Pb) were quantified together with an in-depth evaluation of bacterial community based on high-throughput sequencing. The individual and overall ecological risk from heavy metals were estimated, and their relations with the identified seven core bacteria were analyzed. For soils surrounding both coal mines, in phylum level, five dominant bacterial taxa (Proteobacteria, Acidobacteriota, Actinobacteria, Firmicutes, and Bacteroidota) were identified, and their differences in relative abundance were clearly revealed, even if the differences between the two mines were not significant. When evaluated in genus level, apparent differences in bacterial community structure and complexity were found. The soils with higher potential ecological risk showed relatively lower complexity for the bacterial community. Seven core bacteria were identified, and negative relations of their relative abundance with the individual and overall ecological risk from heavy metals were revealed. Two families (Halomonadaceae and Aeromonadaceae) and two genera (Oceanisphaera and Ignatzschineria) were found more sensitive to both the individual risk from arsenic and the overall risk from all heavy metals, suggesting their possibility as indicators of soil contamination by these metal elements. Different from these, Rhizobiaceae revealed a positive relation with the overall risk value, implying their strong tolerance to heavy metals and, therefore, possible effect in bioremediation and phytoremediation of heavy metal contaminated soils. These findings have great reference value for better understanding the impacts of heavy metal contamination induced by coal production.