Anaerobic RSH-dependent tellurite reduction contributes to Escherichia coli tolerance against tellurite

Tellurium is a rare metalloid that exerts high toxicity on cells, especially on bacteria, partly due to reactive oxygen species (ROS) generation. Moreover, it has also been observed that tellurite can target free cell thiols groups (RSH) (i.e. reduced glutathione (GSH)), enhancing the cellular redox...

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Published in:Biological research 2022-03, Vol.55 (1), p.13-13, Article 13
Main Authors: Muñoz-Diaz, P, Jiménez, K, Luraschi, R, Cornejo, F, Figueroa, M, Vera, C, Rivas-Pardo, A, Sandoval, J M, Vásquez, C, Arenas, F
Format: Article
Language:English
Subjects:
Anaerobic conditions
Anaerobiosis
Bacteria
Bioavailability
Drug resistance in microorganisms
E coli
Enzymes
Escherichia coli
Glutathione
Homeostasis
Intracellular
Metabolism
Oxidation-Reduction
Proteins
Reactive oxygen species
RSH
Streptococcus infections
Tellurite
Tellurite reduction
Tellurium
Thiols
Toxicity
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Summary:Tellurium is a rare metalloid that exerts high toxicity on cells, especially on bacteria, partly due to reactive oxygen species (ROS) generation. Moreover, it has also been observed that tellurite can target free cell thiols groups (RSH) (i.e. reduced glutathione (GSH)), enhancing the cellular redox imbalance. Additionally, in vitro experiments have suggested that several enzymes can reduce tellurite (IV) to its elemental form (0); where RSH present on their active sites may be responsible for the process. Nevertheless, the mechanisms implemented by bacteria for tellurite reduction and its role in resistance have not been evaluated in vivo. This work shows that tellurite reduction to elemental tellurium is increased under anaerobic conditions in E. coli cells. The in vivo tellurite reduction is related to the intracellular concentration of total RSH, in the presence and absence of oxygen. This metabolization of tellurite directly contributes to the resistance of the bacteria to the oxyanion. We demonstrated that in vivo tellurite reduction is related to the intracellular thiol concentration, i.e. large availability of cellular RSH groups, results in a more significant reduction of tellurite. Furthermore, we observed that, when the bacterium exhibits less resistance to the oxyanion, a decreased tellurite reduction was seen, affecting the growth fitness. Together, these results let us propose that tellurite reduction and the intracellular RSH content are related to the oxyanion bacterial resistance, this tripartite mechanism in an oxygen-independent anaerobic process.
ISSN:0717-6287
0716-9760
0717-6287
DOI:10.1186/s40659-022-00383-5