Interaction of methylmercury and selenium on the bioaccumulation and histopathology in medaka (<i>Oryzias latipes</i>)

Liao, Chunyang; Zhou, Qunfang; Fu, Jianjie; Shi, Jianbo; Yuan, Chun-Gang; Jiang, Guibin

doi:10.1002/tox.20236

Cited by 22 publications

(17 citation statements)

References 24 publications

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“…However, it seems that a threshold concentration of selenium in fish body parts must be reached before a clear protective role of selenium against mercury assimilation becomes noticeable [150]. Also, concurrent exposure to methylmercury chloride and selenite led to increased selenium accumulation in medaka fish [151]. The influence of mercury on endogenous selenium after lifelong or acute exposure to mercury vapour (Hg 0 ) has also been studied in man and animals [132].…”

Section: Traffickingmentioning

confidence: 99%

“…Later, studies with human malignant melanoma cells demonstrated that arsenite-induced apoptosis is prevented by selenite [32]. A Human cells As-induced apoptosis is prevented by Se [32] A Mice As prevents carcinogenic effect of Se [30] A Rats As prevents carcinogenic effect of Se [31] A Rats As protects against the toxicity of Se (growth, mortality rate, pathological condition of the liver) [20,33,186] A Rats As induces mucosal glutathione synthesis, explaining its protective effect against Se [187] A Dogs As antagonizes Se-induced subnormal growth and restricted food intake [35] A Cattle As protects against Se toxicity [36] A Hogs As protects against Se toxicity [ Se prolongs the half-lives of Hg-exposed animals [190] A Rats Se changes the subcellular Hg distribution [191] S Oysters High levels of Se increase Hg toxicity [192] SeO 3 2− /MeHg + A Chickens Se changes the subcellular and pattern distribution of Hg [193] A Medaka fish Se protects against Hg-induced histopathological changes [151] SeO 2 /Hg 2+ A Chicks Se toxicity is decreased by Hg [194] SeO 4 2− /MeHg + A Mice Se protects against Hg-induced neurotoxicity [63] Protective effects of arsenic in rats [19,20,23,33,34], dogs [35], cattle [36], mice [37], hogs [38], steers [39], mallards [40] and poultry [41][42][43] have been observed/proposed. Several studies apparently suggest that the same interaction can occur in humans [44][45][46]…”

Section: Arsenic and Seleniummentioning

confidence: 99%

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Biological responses related to agonistic, antagonistic and synergistic interactions of chemical species

et al. 2012

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The fact that the essential or toxic character of elements is species specific has encouraged the development of analytical strategies for chemical speciation over the last twenty years; indeed, there are now a great number of them that provide very good performance. However, biological systems are exposed to a complex environment in which species of elements can interact in a synergistic/antagonistic fashion. Thus, the metabolism of trace elements cannot be considered in isolation. On the other hand, biological systems are dynamic, so it is necessary to study the trafficking of species of elements between organs, tissues or cell compartments in order to decipher the biochemical processes of the interactions in which they are involved. Although the application of liquid chromatography-inductively coupled plasma-based "metallomics" methods in combination with organic mass spectrometry can provide much-needed insight, new analytical strategies are required to really understand the role of species of elements in biological systems and the mechanisms of their interactions. In the present paper, the interactions of the most widely studied elements in this context (Se, Hg and As) are discussed, as well as other important interactions between different elements.

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Section: Traffickingmentioning

confidence: 99%

Section: Arsenic and Seleniummentioning

confidence: 99%

Biological responses related to agonistic, antagonistic and synergistic interactions of chemical species

et al. 2012

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“…For example, tributyltin exposure could induce cellular pathological alterations including vacuoles with increasing number and size, swelling of mitochondria, abnormal nuclei and decreases of rough endoplasmic reticulum cisternaes in the liver of the Chinese rare minnow (Gobiocypris rarus) [106]. Histopathological changes, such as oedema, vacuolization, pyknotic nucleus, telangiectasis and degenerative sperm were found in the liver, gill and gonad slices from medaka (Oryzias latipes) exposed to methylmercury [107]. The interaction between mercury and selenium was debated previously [108][109][110][111].…”

Section: Morphological Observation-imposex As a Typical Examplementioning

confidence: 99%

“…The interaction between mercury and selenium was debated previously [108][109][110][111]. The histopathological observations helped to find that the interaction between MeHg and selenium at molar ration of 1:1 offered a limited protection against of both MMC and Na 2 SeO 3 to medaka [112]. Accordingly, histopathological techniques can be obviously used to evaluate the toxicological effects of both individual pollutant and the complex chemicals.…”

Section: Morphological Observation-imposex As a Typical Examplementioning

confidence: 99%

Biomonitoring: An appealing tool for assessment of metal pollution in the aquatic ecosystem

Zhou

Zhang

et al. 2008

Analytica Chimica Acta

764

348

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“…Many estuarine and marine species are able to absorb and accumulate metals from water or feed. In context of heavy metal uptake, there are many studies on several fish, oyster and large crustacean species [16][17][18][19][20][21][22][23], but little information is available regarding metal uptake capacity in planktonic crustaceans [24][25][26]. Artemia urmiana is an endemic species of Artemia in Iran [27] and in spite of high economic and ecological importance, there is no information about its toxicological aspects.…”

mentioning

confidence: 99%

Toxicity and Bioconcentration of Cadmium and Copper in Artemia Urmiana Nauplii

Mohiseni¹,

Farhangi

Agh

et al. 2017

IJT

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Background: Artemia urmiana are small crustaceans that because of its non-selective filter feeder pattern potentially may absorb high level of heavy metals through their living environment. In this study, the effects of different levels of cadmium and copper on survival, catalase activity and metals bioconcentration rates in A. urmiana nauplii have been investigated. Methods:The research was carried out in February 2012 at University of Tehran, Tehran, Iran.First experiment was conducted in nine concentrations with six replication, then LC 50 and probable interactions between experimental metals were evaluated. In the second experiment, concentrations of metals absorbed by Artemia and catalase activity were measured based on the acute toxicity indices, including NOEC, LOEC and LC 50 at individual and mixed concentrations. Results:The toxicity of copper sulphate (LC 50 = 29.87) was 2.5 times greater than cadmium chloride (LC 50 =79.08) and the toxicity interaction between cadmium and copper was synergistic. The rate of copper uptake in Artemia was higher than cadmium and increased concentration of heavy metals significantly decreased the bioconcentration factor. Comparison of mixed and individual concentrations showed that cadmium significantly decreased copper uptake, while it seems that cadmium bioconcentration was improved consequently. Biochemical analysis showed that the catalase activity was affected undesirably in different individual and mixed concentrations; however, these changes were not significant. Conclusion:A. urmiana nauplia seems to be highly resistant toward cadmium and copper in their culture medium and demonstrated excessive potential for uptake of heavy metals from their rearing environment.

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Interaction of methylmercury and selenium on the bioaccumulation and histopathology in medaka (Oryzias latipes)

Cited by 22 publications

References 24 publications

Biological responses related to agonistic, antagonistic and synergistic interactions of chemical species

Biological responses related to agonistic, antagonistic and synergistic interactions of chemical species

Biomonitoring: An appealing tool for assessment of metal pollution in the aquatic ecosystem

Toxicity and Bioconcentration of Cadmium and Copper in Artemia Urmiana Nauplii

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