Coordinatore | UNIVERSITY OF SUSSEX
Organization address
address: Sussex House contact info |
Nazionalità Coordinatore | United Kingdom [UK] |
Totale costo | 209˙033 € |
EC contributo | 209˙033 € |
Programma | FP7-PEOPLE
Specific programme "People" implementing the Seventh Framework Programme of the European Community for research, technological development and demonstration activities (2007 to 2013) |
Code Call | FP7-PEOPLE-2011-IEF |
Funding Scheme | MC-IEF |
Anno di inizio | 2012 |
Periodo (anno-mese-giorno) | 2012-06-01 - 2014-05-31 |
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UNIVERSITY OF SUSSEX
Organization address
address: Sussex House contact info |
UK (FALMER, BRIGHTON) | coordinator | 209˙033.40 |
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'Fish populations are declining in inland waters in many parts of Europe due, in part, to the impact of aquatic pollutants on fish health. In many aquatic environments fish are exposed to effluents from wastewater treatment works (WwTW), and these can contain complex mixtures of chemicals arising from human waste. The impact of many of these contaminants and their mixtures on fish health is unknown and remains to be investigated. With future pressures on water resources resulting in less dilution of WwTW effluents in some river catchments, there is a urgent need to develop monitoring tools to assess effluent exposure and its effects on fish health.The objectives of this project are to investigate how the (bio)chemical profiles change in fish blood as a result of exposure to WwTW effluents, and to identify key (bio)chemical signatures that could be used to monitor exposure to wastewater effluents. To do this, the fellow will use the exciting omics-based technique of metabolomics. This involves the holistic mass spectrometry profiling of as many of the biochemicals as possible in the blood and, in the context of this project, will also involve profiling of chemical contaminants and their metabolites also present in the samples. Fish will be exposed to WwTW effluents and the (bio)chemicals in their blood samples profiled to identify markers of effluent exposure and effect. The work will result in an array of candidate (bio)chemicals which can then be evaluated in future projects for biomonitoring of fish health in European rivers. The results will be of wide interest to the government regulatory bodies, environment protection groups, water and waste industries and the wider public in Europe. The project will bring Dr David to work with Professor Hill, and allow him to benefit from a number of scientific and complementary training activities which will prepare the fellow for an independent research career in environmental science.'
Fish populations are declining in many of Europe's inland waterways, partly as a result of exposure to aquatic pollutants such as from wastewater treatment plants.
The aim of the 'Fishing for markers of effluent exposure using metabolomics' (FISHMETABOLOME) project was find an array of biochemicals that can identify markers for exposure to and the effects of wastewater effluent on fish. In particular, researchers investigated changes in fish blood plasma metabolites and identified marker metabolites for use in monitoring fish exposure to toxic contaminants.
Sexually mature roach (Rutilus rutilus) were exposed either to water contaminated with effluent from wastewater treatment works or to a clean water control. After 15 days the fish were anaesthetised and the plasma and tissues removed and analysed.
The plasma samples were extracted using techniques developed as part of the project and the samples were profiled by mass spectrometry. Chemical and biochemical markers for effluent exposure were identified and compared with mass spectra from databases or from pure standards.
Results showed distinct differences between the control fish and those exposed to effluent for plasma, gonads, kidney and liver samples. This indicated significant changes in the tissue chemistry of effluent-exposed fish.
Contaminants identified as accumulating in fish tissue included endocrine disruptors and a mixture of many pharmaceuticals. Analyses of metabolites showed disturbances in eicosanoid, steroid, serotonin, bile acid, carnitine and sphingosine pathways. Some of these metabolite disruptions could be linked to the presence of chemical stressors in the fish tissue.
FISHMETABOLOME showed that sensitive non-targeted chemical profiling techniques can be used to detect mixtures of contaminants and the disruption of key metabolic pathways in fish tissue. Exposure to effluent resulted in disturbances to several fundamental signalling pathways in fish, including ion transport, immune function and reproduction.
A reduction in androgen and an increase in serotonin metabolites were also observed, indicating potential effects on the reproduction and nervous system of exposed fish. Therefore, the non-targeted approach could be extremely useful for investigating the health effects and contaminants found in fish exposed to wastewater effluent.
The work carried out by FISHMETABOLOME can provide tools and techniques for investigating the impact of a contaminated environment on aquatic organisms. It showed that fish in effluent-contaminated waters are highly vulnerable to exposure to several pharmaceuticals, which can affect behaviour, the immune system and reproduction.