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Mechanism of urinary excretion of methylmercury in mice (1989)

Yasutake, Akira ; Hirayama, Kimiko ; Inoue, Masayasu

Springer

Archives of toxicology 63 (1989), S. 479-483

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ISSN: 1432-0738

Keywords: Mercury metabolism ; Glutathione ; Detoxication ; Renal transport

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract To elucidate the mechanism by which methylmercury (MeHg) is eliminated from organisms, male C57BL/6N mice were orally administered with MeHg chloride (5 mg/kg) and the chemical forms of its metabolites in plasma, urine and the kidney were determined by column chromatographic analysis. Orally administered MeHg rapidly entered the circulation, accumulated in the kidney and other tissues, and was slowly excreted in the urine. Ultrafiltration and gel filtration analysis revealed that most of plasma MeHg was accounted for by its albumin conjugate. Cell fractionation analysis revealed that about 80% of renal MeHg was recovered from the 15 000 g supernatant fraction of the kidney homogenate. If the kidney was homogenized in the presence of serine-borate complex, a potent inhibitor of γ-glutamyltranspeptidase (γ-GTP), about 50% of the MeHg in the supernatant fraction was recovered as its glutathione S-conjugate while the rest was bound to cytosolic protein(s). The major part of urinary MeHg was accounted for by its cysteine conjugate. However, urinary excretion of its glutathione conjugate increased significantly if animals were pretreated with acivicin, an affinity labeling reagent for γ-GTP. These and other results suggested that MeHg bound to albumin accumulated in the kidney predominantly via some non-filtrating peritubular mechanism, and localized in renal cytosolic compartment as its glutathione- and protein-bound forms. The glutathione S-conjugate of MeHg in the tubule cells might be transferred to the lumenal space, hydrolyzed to the cysteine S-conjugate, and then excreted in urine. These sequential events might constitute an important eliminatory pathway for a hazardous mercurial metabolite in mice.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00316452

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Induction by mercury compounds of brain metallothionein in rats: Hg0 exposure induces long-lived brain metallothionein (1998)

Yasutake, Akira ; Nakano, Atsuhiro ; Hirayama, Kimiko

Springer

Archives of toxicology 72 (1998), S. 187-191

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ISSN: 1432-0738

Keywords: Key words Methylmercury ; Mercury vapor ; Metallothionein ; Brain ; Rat

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract Metallothionein (MT) is one of the stress proteins which can easily be induced by various kind of heavy metals. However, MT in the brain is difficult to induce because of blood-brain barrier impermeability to␣most heavy metals. In this paper, we have attempted to induce brain MT in rats by exposure to methylmercury (MeHg) or metallic mercury vapor, both of which are known to penetrate the blood-brain barrier and cause neurological damage. Rats treated with MeHg (40 μmol/kg per day × 5 days, p.o.) showed brain Hg levels as high as 18 μg/g with slight neurological signs 10␣days after final administration, but brain MT levels remained unchanged. However, rats exposed to Hg vapor for 7 days showed 7–8 μg Hg/g brain tissue 24 h after cessation of exposure. At that time brain MT levels were about twice the control levels. Although brain Hg levels fell gradually with a half-life of 26 days, MT levels induced by Hg exposure remained unchanged for 〉2␣weeks. Gel fractionation revealed that most Hg was in the brain cytosol fraction and thus bound to MT. Hybridization analysis showed that, despite a significant increase in MT-I and -II mRNA in brain, MT-III mRNA was less affected. Although significant Hg accumulation and MT induction were observed also in kidney and liver of Hg vapor-exposed rats, these decreased more quickly than in brain. The long-lived MT in brain might at least partly be accounted for by longer half-life of Hg accumulated there. The present results showed that exposure to Hg vapor might be a suitable procedure to provide an in vivo model with enhanced brain MT.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s002040050486

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