{"title":"Effect of pretreatment with dichloroacetate or trichloroacetate on the metabolism of bromodichloroacetate.","authors":"E W Austin, R J Bull","doi":"10.1080/00984109708984071","DOIUrl":null,"url":null,"abstract":"<p><p>Haloacetates are a common class of water chlorination by-products. Depending on the amount of bromide in the source water, varying amounts of chlorinated, brominated, and mixed bromochloro haloacetates are produced. When administered to rodents, haloacetates have been shown to increase formation of thiobarbituric acid-reactive substances and 8-hydroxydeoxyguanosine levels in the liver. These responses appear to be modified by prior treatment. To examine potential mechanisms that account for these modifications in oxidative stress, the ability of trichloroacetate (TCA) or dichloroacetate (DCA) pretreatment to alter the metabolism of bromodichloroacetate (BDCA) and the disposition of its metabolites was examined in male B6C3F1 mice. Two-week pretreatment with 1 g/L DCA and TCA in the drinking water of mice alters the initial hepatic metabolism of BDCA and the further metabolism of its metabolite DCA. DCA pretreatment inhibits cytosolic metabolism of both 1 mM DCA or BDCA up to 70%. In contrast, DCA pretreatment stimulates hepatic microsomal BDCA metabolism 1.3-fold but has little effect on microsomal metabolism of DCA. Increased microsomal metabolism of BDCA appears to be attributable to the induction of a metabolic pathway that produces CO2 and bromodichloromethane (BDCM) as metabolites. TCA pretreatment inhibits BDCA metabolism up to 70% in the cytosol and 30% in microsomes but has little effect on DCA metabolism. These results indicate that the hepatic metabolism of the haloacetate becomes quite complex at the high doses that have been employed in cancer bioassays. BDCA serves as a good example, because it is metabolized to at least two carcinogenic metabolites that have different modes of action, BDCM and DCA. As doses approach those that induce cancer in mice, the proportion of and amounts of these metabolites as a fraction of the dose administered will change substantially. This article demonstrates that those interactions will occur from mixed treatment with haloacetates as well.</p>","PeriodicalId":17524,"journal":{"name":"Journal of toxicology and environmental health","volume":"52 4","pages":"367-83"},"PeriodicalIF":0.0000,"publicationDate":"1997-11-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://sci-hub-pdf.com/10.1080/00984109708984071","citationCount":"12","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Journal of toxicology and environmental health","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1080/00984109708984071","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 12
Abstract
Haloacetates are a common class of water chlorination by-products. Depending on the amount of bromide in the source water, varying amounts of chlorinated, brominated, and mixed bromochloro haloacetates are produced. When administered to rodents, haloacetates have been shown to increase formation of thiobarbituric acid-reactive substances and 8-hydroxydeoxyguanosine levels in the liver. These responses appear to be modified by prior treatment. To examine potential mechanisms that account for these modifications in oxidative stress, the ability of trichloroacetate (TCA) or dichloroacetate (DCA) pretreatment to alter the metabolism of bromodichloroacetate (BDCA) and the disposition of its metabolites was examined in male B6C3F1 mice. Two-week pretreatment with 1 g/L DCA and TCA in the drinking water of mice alters the initial hepatic metabolism of BDCA and the further metabolism of its metabolite DCA. DCA pretreatment inhibits cytosolic metabolism of both 1 mM DCA or BDCA up to 70%. In contrast, DCA pretreatment stimulates hepatic microsomal BDCA metabolism 1.3-fold but has little effect on microsomal metabolism of DCA. Increased microsomal metabolism of BDCA appears to be attributable to the induction of a metabolic pathway that produces CO2 and bromodichloromethane (BDCM) as metabolites. TCA pretreatment inhibits BDCA metabolism up to 70% in the cytosol and 30% in microsomes but has little effect on DCA metabolism. These results indicate that the hepatic metabolism of the haloacetate becomes quite complex at the high doses that have been employed in cancer bioassays. BDCA serves as a good example, because it is metabolized to at least two carcinogenic metabolites that have different modes of action, BDCM and DCA. As doses approach those that induce cancer in mice, the proportion of and amounts of these metabolites as a fraction of the dose administered will change substantially. This article demonstrates that those interactions will occur from mixed treatment with haloacetates as well.
卤醋酸盐是一类常见的水氯化副产物。根据源水中溴化物的含量,会产生不同数量的氯化、溴化和混合卤代溴盐。当给啮齿动物服用时,卤代乙酸盐已被证明可以增加肝脏中硫代巴比妥酸反应物质和8-羟基脱氧鸟苷水平的形成。这些反应似乎被先前的治疗所改变。为了研究氧化应激中这些变化的潜在机制,在雄性B6C3F1小鼠中研究了三氯乙酸(TCA)或二氯乙酸(DCA)预处理改变溴二氯乙酸(BDCA)代谢及其代谢物处置的能力。在小鼠饮用水中加入1 g/L DCA和TCA预处理两周,改变了BDCA的初始肝脏代谢及其代谢物DCA的进一步代谢。DCA预处理对1 mM DCA或BDCA的胞质代谢抑制高达70%。相比之下,DCA预处理对肝微粒体BDCA代谢的刺激达到1.3倍,但对DCA微粒体代谢的影响不大。BDCA微粒体代谢增加似乎是由于诱导代谢途径产生二氧化碳和溴二氯甲烷(BDCM)作为代谢物。TCA预处理抑制细胞质中BDCA代谢高达70%,微粒体中BDCA代谢高达30%,但对DCA代谢影响不大。这些结果表明,在用于癌症生物测定的高剂量下,卤乙酸盐的肝脏代谢变得相当复杂。BDCA就是一个很好的例子,因为它被代谢成至少两种具有不同作用方式的致癌代谢物,BDCM和DCA。当剂量接近在小鼠中诱发癌症的剂量时,这些代谢物的比例和数量作为给药剂量的一部分将发生实质性变化。本文表明,这些相互作用也会发生在与卤代乙酸盐混合处理时。
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