Coal mining can be deleterious to the soil physical and chemical makeup, but also to the soil microbial community. Effectively, the removal of nearly all organic matter from the upper soil horizons reduces the effectiveness of any soil to support vegetation, and up until recently, microbial community parameters were not considered in the successful reclamation of overburden. Thus, our study proposes to measure the uncultivated bacterial community using 16S ribosomal RNA (rRNA) high-throughput sequencing in a chronosequence of reclaimed overburden in Mississippi. The study sites comprised samplings of pasture and wooded reclamation sites consisting of 1 to 13 yr post reclamation time, as well as reference sites. Overall, the primary driver of bacterial community dynamics was vegetative cover, although time also influenced dynamics. Richness estimations for operational taxonomic units (OTUs) showed that recently reclaimed (∼1 yr) and Pasture sites were more OTU rich with levels of >1400 compared with reference site levels of ∼1000. Diversity levels also followed a similar trend. Community structure typically differed between time points and vegetative cover; however, membership was similar between sites and reference, indicating that new communities still shared some membership from the previous community. Overall, physicochemical properties trended toward more positive for soil health as time progressed, but bacterial community recovery was still not structurally recovered, although richness and diversity values exceeded reference. Overall, this study demonstrated that mine reclamation using pasture and/or wood restoration can reestablish the bacterial community to approximate reference conditions, but vegetation is still the dominating environmental factor dictating microbial community.
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