Your search keyword '"Qu, Guang Bo"' showing total 2 results

1. Mutual detoxification of mercury and selenium in unicellular Tetrahymena.

Author

Liu CB, Zhang L, Wu Q, Qu GB, Yin YG, Hu LG, Shi JB, and Jiang GB

Subjects

Inactivation, Metabolic, Mercury toxicity, Selenium toxicity, Water Pollutants, Chemical toxicity, Mercury metabolism, Selenium metabolism, Tetrahymena metabolism, Water Pollutants, Chemical metabolism

Abstract

Selenium (Se) is commonly recognized as a protective element with an antagonistic effect against mercury (Hg) toxicity. However, the mechanisms of this Hg-Se antagonism are complex and remain controversial. To gain insight into the Hg-Se antagonism, a type of unicellular eukaryotic protozoa (Tetrahymena malaccensis, T. malaccensis) was selected and individually or jointly exposed to two Hg and three Se species. We found that Se species showed different toxic effects on the proliferation of T. malaccensis with the toxicity following the order: selenite (Se(IV))>selenomethionine (SeMeth)>selenate (Se(VI)). The Hg-Se antagonism in Tetrahymena was observed because the joint toxicity significantly decreased under co-exposure to highly toxic dosages of Hg and Se versus individual toxicity. Unlike Se(IV) and Se(VI), non-toxic dosage of SeMeth significantly decreased the Hg toxicity, revealing the influence of the Se species and dosages on the Hg-Se antagonism. Unexpectedly, inorganic divalent Hg (Hg 2+ ) and monomethylmercury (MeHg) also displayed detoxification towards extremely highly toxic dosages of Se, although their detoxifying efficiency was discrepant. These results suggested mutual Hg-Se detoxification in T. malaccensis, which was highly dependent on the dosages and species of both elements. As compared to other species, SeMeth and MeHg promoted the Hg-Se joint effects to a higher degree. Additionally, the Hg contents decreased for all the Hg-Se co-exposed groups, revealing a sequestering effect of Se towards Hg in T. malaccensis., (Copyright © 2017. Published by Elsevier B.V.)

Published

2018

2. Distinct toxicological characteristics and mechanisms of Hg 2+ and MeHg in Tetrahymena under low concentration exposure.

Author

Liu CB, Qu GB, Cao MX, Liang Y, Hu LG, Shi JB, Cai Y, and Jiang GB

Subjects

Animals, Aquatic Organisms, Cations, Divalent, Membrane Potential, Mitochondrial drug effects, Reactive Oxygen Species, Species Specificity, Water Pollutants, Chemical metabolism, Mercury toxicity, Methylmercury Compounds toxicity, Tetrahymena drug effects, Water Pollutants, Chemical toxicity

Abstract

Inorganic divalent mercury complexes (Hg 2+ ) and monomethylmercury complexes (MeHg) are the main mercury species in aquatic systems and their toxicity to aquatic organisms is of great concern. Tetrahymena is a type of unicellular eukaryotic protozoa located at the bottom of food chain that plays a fundamental role in the biomagnification of mercury. In this work, the dynamic accumulation properties, toxicological characteristics and mechanisms of Hg 2+ and MeHg in five Tetrahymena species were evaluated in detail. The results showed that both Hg 2+ and MeHg were ingested and exhibited inhibitory effects on the proliferation or survival of Tetrahymena species. However, the ingestion rate of MeHg was significantly higher than that of Hg 2+ . The mechanisms responsible for the toxicity of MeHg and Hg 2+ were different, although both chemicals altered mitochondrial membrane potential (MMP). MeHg disrupted the integrity of membranes while Hg 2+ had detrimental effects on Tetrahymena as a result of the increased generation of reactive oxygen species (ROS). In addition, the five Tetrahymena species showed different capacities in accumulating Hg 2+ and MeHg, with T. corlissi exhibiting the highest accumulations. The study also found significant growth-promoting effect on T. corlissi under low concentration exposure (0.003 and 0.01μg Hg/mL (15 and 50nM)), suggesting different effect and mechanism that should be more closely examined when assessing the bioaccumulation and toxicity of mercury in aquatic ecosystems., (Copyright © 2017 Elsevier B.V. All rights reserved.)

Published

2017