Abstract
Pyrite bio-oxidation by chemolithotrophic acidophile bacteria has been applied in the mining industry to bioleach metals or to remove pyritic sulfur from coal. In this process, it is desirable to use autochthonous and already adapted bacteria isolated directly from the mining sites where biomining will be applied. Bacteria present in the remnant solution from a mining company were identified through cloning techniques. For that purpose, we extracted total RNA and performed reverse transcription using a novel pair of primers designed from a small region of the 16S gene (V1–V3) that contains the greatest intraspecies diversity. After cloning, a high proportion of individuals of the strains ATCC-23270 (NR_074193.1 and NR_041888.1) and DQ321746.1 of the well-known species Acidithiobacillus ferrooxidans were found, as well as two new wild strains of A. ferrooxidans. This result showed that the acidic remnant solution comprises a metapopulation. We assayed these strains to produce bioferric flocculant to enhance the subsequent pyrite bio-oxidation, applying two-stage chemical–bacterial oxidation. It was shown that the strains were already adapted to a high concentration of endogenous Fe2+ (up to 20 g·L−1), increasing the volumetric productivity of the bioferric flocculant. Thus, no preadaptation of the community was required. We detected Au and Ag particles originally occluded in the old pyritic flotation tailings assayed, but the extraction of Au and Ag by cyanidation resulted in ca. 30.5% Au and 57.9% Ag.
Highlights
Accepted: 17 November 2021At this point in time, metal recovery mining is facing its greatest challenge: to find new extractive methods for occluded or refractory metals, due to the current difficulty of locating high-grade ores
Strains of A. ferrooxidans Identified in the Remnant Solution T6
The results showed that the T6 solution contained a metapopulation composed of at least four strains of A. ferrooxidans (Figure 1), since (a) the 16S rRNA gene sequences obtained from three T6 samples and three sequences from the adapted cultures (T6-AC1, T6-AC3, and T6-AC4) showed 100% identity with A. ferrooxidans ATCC-23270 NR_074193.1 [40] and NR_041888.1 [28] and (b) T6-OC3
Summary
At this point in time, metal recovery mining is facing its greatest challenge: to find new extractive methods for occluded or refractory metals, due to the current difficulty of locating high-grade ores. In addition to this issue, there are new concerns about environmental protection and conservation, and the need to reduce costs and energy consumption in mining companies. Biohydrometallurgy is based on microbially catalyzed processes or bio-oxidation to extract metals by dissolving ores into acidic aqueous solutions (bioleaching) [3,4,5]. The microorganisms used in biohydrometallurgy procedures must be able to grow autotrophically at low pH, assimilate inorganic carbon, and resist soluble metals [7]
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