Ecotoxicological risk assessment using DNA chips and cellular reporters.

Ecotoxicological risk assessment has long been based on (acute) effective concentration and lethal concentration (EC/LC50) endpoints in organisms from different trophic levels. These tests are insufficient adequately to assess the risk associated with many chemical classes. The introduction of advanced molecular techniques is leading to improved risk assessment and is also providing an alternative to the massive use of animal testing. Transcriptional profiling and DNA chips are highly informative and are among the most promising novel techniques for environmental risk assessment. Moreover, information discerned from these chips enables the identification of new discriminative biomarker genes. Based on these biomarker genes, cellular reporters can be constructed. These can be used in a high-throughput set-up and can facilitate ecotoxicological risk assessment significantly. Some important technical and interpretative hurdles still need to be overcome before a full implementation of ecotoxicogenomics in regulatory settings will occur.

Effluent impact assessment using microarray-based analysis in common carp: a systems toxicology approach.

Effluents are a main source of direct and continuous input of pollutants to the aquatic environment, and can cause ecotoxicological effects at different levels of biological organization. Since gene expression responses represent the primary interaction site between environmental contaminants and biota, they provide essential clues to understand how chemical exposure can affect organismal health. The aim of the present study was to investigate the applicability of a microarray approach for unraveling modes of action of whole effluent toxicity and impact assessment. A chronic toxicity test with common carp (Cyprinus carpio) was conducted where fish were exposed to a control and 100% effluent for 21 days under flow-through conditions. Microarray analysis revealed that effluent treatment mainly affected molecular pathways associated with the energy balance of the fish, including changes in carbohydrate and lipid metabolism, as well as digestive enzyme activity. These gene expression responses were in clear agreement with, and provided additional mechanistic information on various cellular and higher level effects observed for the same effluent. Our results demonstrate the benefit of toxicogenomic tools in a "systems toxicology" approach, involving the integration of adverse effects of chemicals and stressors across multiple levels of biological complexity.