Search for cell culture systems with diverse xenobiotic-metabolizing activities and their use in toxicological studies.

Molecular toxicology Pub Date : 1987-09-01
H Glatt, I Gemperlein, G Turchi, H Heinritz, J Doehmer, F Oesch
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Abstract

Many toxic effects are not caused by the administered compound itself, but are due to metabolites. All cell types express some xenobiotic-metabolizing enzymes, but levels and patterns are very variable. Critical metabolic steps may occur within the target cell and/or at other sites. This complex situation is difficult to mimic in vitro. The further problem is that cells that are taken into culture tend to rapidly cease the expression of important xenobiotic-metabolizing enzymes. Part of the problem may be solved by the addition of exogenous metabolizing systems, for example, in the form of freshly isolated hepatocytes, crude subcellular preparations, or purified enzymes. In these systems, the plasma membrane of the target cell may act as a barrier for the active metabolite and thereby lead to false negative results. The alternative is the use of metabolically active target cells. We therefore screened 18 cell lines for monooxygenase, cytochrome P-450 reductase, epoxide hydrolase, glutathione transferase, and UDP-glucuronosyl transferase activities. In further studies, IEC-17, IEC-18, and HuFoe-15 cells showed their capabilities of activating a broad spectrum of structurally heterogenous promutagens, as indicated by the induction of micronuclei. These cells, however, were not suited for the study of a more relevant genetic end point, the induction of hereditary functional changes (gene mutations), implying that a compromise had to be made on the level of the toxicodynamics. In the second approach, cDNAs encoding the rat cytochromes P-450IA1 and P-450IIB1, set under the control of a constitutive promoter, were transfected into V79 Chinese hamster cells, which do not express cytochromes P-450 but are ideal target cells for gene mutation assays. The resulting substrains (XEM1, XEM2, XEM3; SD1) stably expressed cytochromes P-450IA1 and P-450IIB1, respectively, and showed the corresponding monooxygenase activities. Aflatoxin B1, cyclophosphamide, dibutylnitrosamine, and benzo[a]pyrene mutated SD1 and/or XEM1 and XEM2 cells, but were inactive in parental V79 cells. The mutagenicity of benzo[a]pyrene 7,8-trans-dihydrodiol was about 1000 times more potent in XEM1 and XEM2 cells than in SD1 and V79 cells. Other promutagens were inactive in V79 as well as in the genetically engineered daughter lines. This system therefore is not yet optimal in general screening for the detection of new mutagens, but appears ideal in the identification of critical xenobiotic-metabolizing enzymes for a given mutagen.

寻找具有多种异种代谢活性的细胞培养系统及其在毒理学研究中的应用。
许多毒性作用不是由所施用的化合物本身引起的,而是由代谢物引起的。所有细胞类型都表达一些外源代谢酶,但水平和模式是非常不同的。关键的代谢步骤可能发生在靶细胞和/或其他部位。这种复杂的情况很难在体外模拟。进一步的问题是,培养的细胞往往会迅速停止重要的外源代谢酶的表达。部分问题可以通过添加外源性代谢系统来解决,例如,以新鲜分离的肝细胞、粗亚细胞制剂或纯化酶的形式。在这些系统中,靶细胞的质膜可能作为活性代谢物的屏障,从而导致假阴性结果。另一种选择是使用代谢活跃的靶细胞。因此,我们对18个细胞系进行了单加氧酶、细胞色素P-450还原酶、环氧化物水解酶、谷胱甘肽转移酶和udp -葡萄糖醛基转移酶活性的筛选。在进一步的研究中,IEC-17、IEC-18和hufe -15细胞显示出通过诱导微核激活广谱结构异质促生因子的能力。然而,这些细胞不适合研究更相关的遗传终点,即遗传功能变化的诱导(基因突变),这意味着必须在毒理学水平上做出妥协。在第二种方法中,编码大鼠细胞色素P-450IA1和P-450IIB1的cdna在组成启动子的控制下被转染到不表达细胞色素P-450的V79中国仓鼠细胞中,这些细胞是基因突变试验的理想靶细胞。得到的子菌株(XEM1, XEM2, XEM3;SD1)分别稳定表达细胞色素P-450IA1和P-450IIB1,并表现出相应的单加氧酶活性。黄曲霉毒素B1、环磷酰胺、二丁基亚硝胺和苯并[a]芘使SD1和/或XEM1和XEM2细胞发生突变,但在亲本V79细胞中无活性。苯并[a]芘7,8-反式二氢二醇对XEM1和XEM2细胞的致突变性是SD1和V79细胞的1000倍左右。其他促生剂在V79和转基因子代中都没有活性。因此,该系统在检测新诱变剂的一般筛选中还不是最佳的,但在鉴定特定诱变剂的关键外源代谢酶方面似乎是理想的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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