Abstract
BACKGROUND: Tellurite (TeO(3)(2-)) is recognized as a toxic oxyanion to living organisms. However, mainly anaerobic or facultative-anaerobic microorganisms are able to tolerate and convert TeO(3)(2-) into the less toxic and available form of elemental Tellurium (Te(0)), producing Te-deposits or Te-nanostructures. The use of TeO(3)(2-)-reducing bacteria can lead to the decontamination of polluted environments and the development of "green-synthesis" methods for the production of nanomaterials. In this study, the tolerance and the consumption of TeO(3)(2-) have been investigated, along with the production and characterization of Te-nanorods by Rhodococcus aetherivorans BCP1 grown under aerobic conditions. RESULTS: Aerobically grown BCP1 cells showed high tolerance towards TeO(3)(2-) with a minimal inhibitory concentration (MIC) of 2800 μg/mL (11.2 mM). TeO(3)(2-) consumption has been evaluated exposing the BCP1 strain to either 100 or 500 μg/mL of K(2)TeO(3) (unconditioned growth) or after re-inoculation in fresh medium with new addition of K(2)TeO(3) (conditioned growth). A complete consumption of TeO(3)(2-) at 100 μg/mL was observed under both growth conditions, although conditioned cells showed higher consumption rate. Unconditioned and conditioned BCP1 cells partially consumed TeO(3)(2-) at 500 μg/mL. However, a greater TeO(3)(2-) consumption was observed with conditioned cells. The production of intracellular, not aggregated and rod-shaped Te-nanostructures (TeNRs) was observed as a consequence of TeO(3)(2-) reduction. Extracted TeNRs appear to be embedded in an organic surrounding material, as suggested by the chemical-physical characterization. Moreover, we observed longer TeNRs depending on either the concentration of precursor (100 or 500 μg/mL of K(2)TeO(3)) or the growth conditions (unconditioned or conditioned grown cells). CONCLUSIONS: Rhodococcus aetherivorans BCP1 is able to tolerate high concentrations of TeO(3)(2-) during its growth under aerobic conditions. Moreover, compared to unconditioned BCP1 cells, TeO(3)(2-) conditioned cells showed a higher oxyanion consumption rate (for 100 μg/mL of K(2)TeO(3)) or to consume greater amount of TeO(3)(2-) (for 500 μg/mL of K(2)TeO(3)). TeO(3)(2-) consumption by BCP1 cells led to the production of intracellular and not aggregated TeNRs embedded in an organic surrounding material. The high resistance of BCP1 to TeO(3)(2-) along with its ability to produce Te-nanostructures supports the application of this microorganism as a possible eco-friendly nanofactory.