The key problem faced by environmental scientists is to predictand recognize
the damaging effects of chemical pollutants on natural biota. The aim of this thesis was
to evaluate the potential for proteomics in ecotoxicology and environmental risk
assessment (ERA), with the hypothesis that proteomic technologies (i.e. ProteinChip
technology in combination with SELDI TOF MS) could be a useftil supplement to
existing methods of environmental assessment, by providing a sensitive, non-invasive,
rapid multi-endpoint assessment of effects of anthropogenic chemicals on organism in
vivo. Three invertebrate species, Mytilus edulis, Hyas araneus and Strongylocentrotus
droebachiensis was exposed to natural and anthropogenic chemicals in laboratory and
field studies. Results revealed that proteomics was a sensitive endpoint, as all exposure
regimes significantly affected protein expression. It was shown that plasma protein
expression profiles contained information that was compound, dose, site, species and
gender-specific. Regarding the latter; male and female organisms responded differently
to all exposures both quantitatively (e.g. in terms of number of affected protein species)
and qualitatively (e.g. in terms of tj^e of affected protein species). Furthermore,
genders have shown opposite responses following the same exposure regime. Equally,
species-specific responses were observed. Moreover, exposing organisms to graded
levels of contamination under controlled laboratory conditions and in the field revealed
that different subsets of proteomes were affected at different levels of exposure. This
finding represents an opportunity for appljdng proteomics for both prognostic (e.g. early
warning of potential adverse effects or assessment of recovery) and diagnostic purposes.
Moreover, those protein features that were changed by all exposure concentrations
showed complex dose-response relationships, including both linear and various types of
biphasic response-curves.
In summary, results from the present study indicate that proteomics have the
potential to be a useftil tool in ERA. For example, identification of key molecules could
elucidate mechanism of action related to mixture effects, gender and species-specific
susceptibility to environmental pollutants as well as dose-response relationships at low
doses. Furthermore, key proteins (i.e. putative biomarkers) could, be purified and
coupled to e.g. a biosensor for automated monitoring.
Date of Award | 2008 |
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Original language | English |
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Awarding Institution | |
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Proteomics and ecotoxicoldgy:.marine invertebrates and endocrine disrupting chemicals
BJORNSTAD, A. (Author). 2008
Student thesis: PhD