Bioremediation is the use of microorganisms for the degradation or removal of contaminants. Most bioremediation research has focused on processes performed by the domain Bacteria; however, Archaea are known to play important roles in many situations. In extreme conditions, such as halophilic or acidophilic environments, Archaea are well suited for bioremediation. In other conditions, Archaea collaboratively work alongside Bacteria during biodegradation. In this review, the various roles that Archaea have in bioremediation is covered, including halophilic hydrocarbon degradation, acidophilic hydrocarbon degradation, hydrocarbon degradation in nonextreme environments such as soils and oceans, metal remediation, acid mine drainage, and dehalogenation. Research needs are addressed in these areas. Beyond bioremediation, these processes are important for wastewater treatment (particularly industrial wastewater treatment) and help in the understanding of the natural microbial ecology of several Archaea genera.
3-Nitro-1,2,4-triazol-5-one (NTO)
is one of the main ingredients
of many insensitive munitions, which are being used as replacements
for conventional explosives. As its use becomes widespread, more research
is needed to assess its environmental fate. Previous studies have
shown that NTO is biologically reduced to 3-amino-1,2,4-triazol-5-one
(ATO). However, the final degradation products of ATO are still unknown.
We have studied the aerobic degradation of ATO by enrichment cultures
derived from the soil. After multiple transfers, ATO degradation was
monitored in closed bottles through measurements of inorganic carbon
and nitrogen species. The results indicate that the members of the
enrichment culture utilize ATO as the sole source of carbon and nitrogen.
As ATO was mineralized to CO2, N2, and NH4
+, microbial growth was observed in the culture.
Co-substrates addition did not increase the ATO degradation rate.
Quantitative polymerase chain reaction analysis revealed that the
organisms that enriched using ATO as carbon and nitrogen source were Terrimonas spp., Ramlibacter-related spp., Mesorhizobium spp., Hydrogenophaga spp., Ralstonia spp., Pseudomonas spp., Ectothiorhodospiraceae, and Sphingopyxis. This is the first study to report the complete mineralization of
ATO by soil microorganisms, expanding our understanding of natural
attenuation and bioremediation of the explosive NTO.
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