Department of Health Risk Analysis and Toxicology, Maastricht University, Universiteitssingel 50, 6229 ER Maastricht, The Netherlands.
Mutagenesis. 2010 Nov;25(6):561-8. doi: 10.1093/mutage/geq040. Epub 2010 Jul 21.
Well-established in vitro methods for testing the genotoxic potency of chemicals--such as the Ames/Salmonella test, the mouse lymphoma assay, the micronucleus test and the chromosomal aberration test--show a high false-positive rate for predicting in vivo genotoxicity and carcinogenicity. Thus, there is a need for more reliable in vitro assays. We investigated whether gene expression profiling in metabolically competent primary mouse hepatocytes is capable of discriminating true genotoxic (GTX) compounds from false-positive genotoxic (FP-GTX) compounds. Sandwich-cultured primary hepatocytes from male C57Bl6 mice were treated for 24 and 48 h with five true GTX and five FP-GTX compounds. Whole genome gene expression modifications were analysed by means of Affymetrix mouse genome 430 2.0 microarrays. Filtered genes were used for hierarchical clustering and class prediction methods. Classifiers were generated by prediction analysis of microarray using a leave-one-compound-out method and selecting the genes that were common to the 10 training sets. For the training compounds, all but one were correctly classified. Validation of the classification model with five new compounds resulted in a 100% correct classification at 24 h and 80% at 48 h. The generated classifiers were mostly involved in metabolic and biosynthetic processes, immune responses and apoptosis. Applying genes whose expression change correlates with γH2AX foci, a measure for DNA damage, did not improve the classification. The present study shows that gene expression profiling in primary mouse hepatocytes is capable of discriminating between true GTX and FP-GTX compounds.
化学物质遗传毒性潜力的体外检测方法(如艾姆斯/沙门氏菌试验、小鼠淋巴瘤试验、微核试验和染色体畸变试验)已经得到充分确立,但这些方法预测体内遗传毒性和致癌性的假阳性率较高。因此,需要更可靠的体外检测方法。我们研究了代谢功能健全的原代小鼠肝细胞中的基因表达谱是否能够区分真正的遗传毒性(GTX)化合物和假阳性遗传毒性(FP-GTX)化合物。用雄性 C57Bl6 小鼠的夹心培养原代肝细胞,用 5 种真正的 GTX 化合物和 5 种 FP-GTX 化合物处理 24 和 48 小时。采用 Affymetrix 小鼠基因组 430 2.0 微阵列分析全基因组基因表达的改变。通过层次聚类和分类预测方法分析过滤后的基因。使用预测分析微阵列的方法,通过使用一种留一化合物法选择常见于 10 个训练集的基因,生成分类器。对于训练化合物,除一个外,所有化合物均正确分类。用 5 种新化合物对分类模型进行验证,结果显示 24 小时时的正确分类率为 100%,48 小时时为 80%。生成的分类器主要涉及代谢和生物合成过程、免疫反应和细胞凋亡。应用与 γH2AX 焦点(衡量 DNA 损伤的指标)表达变化相关的基因并不能提高分类效果。本研究表明,原代小鼠肝细胞中的基因表达谱能够区分真正的 GTX 和 FP-GTX 化合物。
