Microbial Community Structure and Carbon-Utilization Diversity in a Mine Tailings Revegetation Study

Restoration of metals‐contaminated environments requires a functional microbial community for successful plant community establishment, soil development, and biogeochemical cycling. Our research measured microbial community structure and carbon‐utilization diversity in treatment plots from a mine wa...

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Bibliographic Details
Published in:Restoration ecology 2002-03, Vol.10 (1), p.77-87
Main Authors: Moynahan, October Seastone, Zabinski, Catherine A., Gannon, James E.
Format: Article
Language:English
Subjects:
Animal, plant and microbial ecology
Applied ecology
arbuscular mycorrhizae
Biological and medical sciences
Conservation, protection and management of environment and wildlife
Environmental degradation: ecosystems survey and restoration
Fundamental and applied biological sciences. Psychology
heavy metals
microbial community
microbial community, soil microbes, arbuscular mycorrhizae, mine waste reclamation, heavy metals
mine waste reclamation
mycorrhizas
soil microbes
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Summary:Restoration of metals‐contaminated environments requires a functional microbial community for successful plant community establishment, soil development, and biogeochemical cycling. Our research measured microbial community structure and carbon‐utilization diversity in treatment plots from a mine waste revegetation project near Butte, Montana. Treatments included two controls (raw tailings) either (1) with or (2) without tilling, (3) shallow‐tilled lime addition, (4) deep‐tilled lime addition, (5) lime slurry injection, (6) topsoil addition, and (7) an undisturbed area near the tailings. Microbial community structural differences were assayed by plate counts of heterotrophic bacteria, actinomycetes, fungi, and bacterial endospores, and quantification of arbuscular mycorrhizae colonization. Metabolic diversity differences were assessed by carbon‐utilization profiles generated with Biolog microtiter plates. Heterotrophic bacteria counts were significantly higher in the limed and topsoil treatment plots than the control plots, and the actinomycete and fungal counts increased in the tilled control plot as well. Endospore counts were significantly higher in the topsoil addition and the undisturbed plots than the other treatment plots. Carbon‐utilization activity was very low in untreated plots, intermediate in lime‐treated plots, and very high in topsoil and undisturbed plots. Arbuscular mycorrhizae (AM) colonization levels of two grass species showed low levels of colonization on control, shallow‐limed, and lime slurry‐injected plots, and high levels on the deep‐limed and topsoil‐addition plots. Plant and soil system components increased across the treatment plots, but individual components responded differently to changing environmental conditions.
ISSN:1061-2971
1526-100X
DOI:10.1046/j.1526-100X.2002.10108.x