Ippei Nakagawa

INVOLVEMENT OF OXIDATIVE STRESS IN PARAQUAT-INDUCED METALLOTHIONEIN SYNTHESIS UNDER GLUTATHIONE DEPLETION

The inhibition of glutathione (GSH) synthesis by L-buthionine-SR-sulfoximine (BSO) causes aggravation of hepatotoxicity of paraquat (PQ), an oxidative-stress inducing substance, in mice. On the other hand, synthesis of metallothionein (MT), a cysteine-rich protein having radical scavenging activity, is induced by PQ, and the induction by PQ is significantly enhanced by pretreatment of mice with BSO. The purpose of present study is to examine whether generation of reactive oxygens is involved in the induction of MT synthesis by PQ under inhibition of GSH synthesis. Administration of PQ to BSO-pretreated mice increased hepatic lipid peroxidation and frequency of DNA single strand breakage followed by manifestation of the liver injury and induction of MT synthesis. Both vitamin E and deferoxamine prevented MT induction as well as lipid peroxidation in the liver of mice caused by administration of BSO and PQ. In cultured colon 26 cells, both cytotoxicity and the increase in MT mRNA level caused by PQ were significantly enhanced by pretreatment with BSO. Facilitation of PQ-induced reactive oxygen generation was also observed by BSO treatment. These results suggest that reactive oxygens generated by PQ under inhibition of GSH synthesis may stimulate MT synthesis. GSH depletion markedly increased reactive oxygen generation induced by PQ, probably due to the reduced cellular capability to remove the radical species produced.

Quantitative assessment of the metabolic activation of alicyclic amines via aldehyde.

INTRODUCTION Recently it has been reported that some drugs that produce reactive intermediates may cause clinical adverse effects following covalent binding to biomacromolecules. For example, Schiff base production mediated by aldehyde is a possible mechanism of drug-protein adducts. However, because thiols do not trap aliphatic aldehydes via hemiacetal or hemiaminal, the glutathione-trapping method cannot be used to determine the covalent bindings of the Schiff base. METHODS We established a quantitative method to determine covalent binding mediated by aldehydes via hemiaminal or hemiacetal using non-radiolabeled compound and [(14)C]semicarbazide as a hard-trap agent with unique post-incubation. RESULTS The trapped aldehyde obtained from the post-incubation was almost equivalent to the covalent binding of the radiolabeled tool compound. Our novel method showed its usefulness in quantitative detection of aldehydes covalent binding ability by several reagents with alicyclic amine and launched drugs as control. DISCUSSION The post-incubation method is useful for screening newly synthesized compounds to quantitatively assess the bioactivation of aldehydes descending from alicyclic amines.

Induction of renal metallothionein synthesis bycis-diamminedichloroplatinum (II) in glutathione-depleted mice

Effects of glutathione (GSH) depletion on nephrotoxicity of cis-diamminedichloroplatinum(II) (cis-DDP) and induction of renal metallothionein (MT) synthesis elicited by cis-DDP treatment has been studied using mice. Pretreatment with L-buthionine-SR-sulfoximine (BSO) reduced the GSH level in the kidneys to 20% of the control level at the time of cis-DDP administration. Administration of 45 μmol/kg cis-DDP did not change the blood urea nitrogen (BUN) level, determined as an indicator of nephrotoxicity, until 96 h after administration, whereas BSO pretreatment raised the BUN level as early as 48 h after cis-DDP (45 μmol/kg) treatment. The level of renal MT was also increased in the GSH-depleted mice and was changed in parallel with the BUN level after cis-DDP treatment. Level of plasma fibrinogen, one of acute phase proteins, increased by cis-DDP in GSH-depleted mice. The increase was reduced by dexamethasone pretreatment, although the renal MT level increased by BSO and cis-DDP was not changed by dexamethasone pretreatment. These results suggest that the induction of renal MT synthesis by cis-DDP in BSO-pretreated mice was not related with the acute phase responses such as cytokines induction. Although the mechanism of the induction of MT synthesis by cis-DDP in GSH-depleted mice is unclear, it is possible that MT is induced as an antidote against oxidative stress, which may be a major cause for nephrotoxicity of cis-DDP enhanced by GSH depletion.