Abstract
Nitrogen cycle microorganisms are essential in agricultural soils and may be affected by mercury pollution. The aims of this study are to evaluate the bioremediation of mercury-polluted agricultural soil using Cupriavidus metallidurans MSR33 in a rotary drum bioreactor (RDB) and to characterize the effects of mercury pollution and bioremediation on nitrogen cycle microorganisms. An agricultural soil was contaminated with mercury (II) (20–30 ppm) and subjected to bioremediation using strain MSR33 in a custom-made RDB. The effects of mercury and bioremediation on nitrogen cycle microorganisms were studied by qPCR. Bioremediation in the RDB removed 82% mercury. MSR33 cell concentrations, thioglycolate, and mercury concentrations influence mercury removal. Mercury pollution strongly decreased nitrogen-fixing and nitrifying bacterial communities in agricultural soils. Notably, after soil bioremediation process nitrogen-fixing and nitrifying bacteria significantly increased. Diverse mercury-tolerant strains were isolated from the bioremediated soil. The isolates Glutamicibacter sp. SB1a, Brevundimonas sp. SB3b, and Ochrobactrum sp. SB4b possessed the merG gene associated with the plasmid pTP6, suggesting the horizontal transfer of this plasmid to native gram-positive and gram-negative bacteria. Bioremediation by strain MSR33 in an RDB is an attractive and innovative technology for the clean-up of mercury-polluted agricultural soils and the recovery of nitrogen cycle microbial communities.
Highlights
Lands for agriculture are degraded due to pollution and other anthropogenic activities [1]
The aims of this study are to evaluate the bioremediation of mercury-polluted agricultural soil using Cupriavidus metallidurans MSR33 in a rotary drum bioreactor (RDB) and to characterize the effects of mercury pollution and bioremediation on nitrogen cycle microorganisms
Bioremediation performed with a high concentration of MSR33 cells (6 g cells kg−1 dry soil) showed a higher mercury removal after 48 h (70% mercury removal) than with 3 g cells kg−1 dry soil
Summary
Lands for agriculture are degraded due to pollution and other anthropogenic activities [1]. Anthropogenic activities have significantly perturbed the soil nitrogen cycle [2,3,4,5]. Nitrogen-fixing bacteria is an indicator of soil quality [7,9]. Nitrification is performed by bacteria and archaea, which oxidize ammonia to nitrite and nitrate [2,8]. These conversions could affect agricultural soil, due to losses generated by the high solubility of nitrate that may cause groundwater eutrophication. Denitrification is a process in which nitrate is reduced successively to NO, N2O, and N2 gases, and may affect agricultural soil due to nitrogen release into the atmosphere [5,8,12]
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