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 Research Goals: To
identify gene expression signatures of mixtures of PAHs and chromium or arsenic.
Overview: Development of environmental policy relies on risk information about the
chemicals to which individuals are exposed. Although mechanisms are in
place to test the health effects of individual chemicals, there is little data
on the toxicity of complex environmental mixtures. In the absence of
specific data, default assumptions must be used when conducting risk assessment
for mixtures. For example, in the absence of evidence to the contrary, two
chemicals having similar toxic effects are assumed to act in an additive manner. This approach is not satisfactory for many complex mixtures in which a wide
spectrum of interactions, from repression of effects to synergy, may be
observed. Since most individuals are exposed to complex mixtures of
environmental contaminants, methods for assessing the risks of these exposures
need to be developed.
Most, if not all of the
toxic effects of PAH exposure are mediated by the aromatic hydrocarbon (Ah)
receptor. The Ah receptor is a ligand-activated transcription factor that,
in combination with the AH receptor nuclear translocator, is responsible for the
transcriptional activation of phase I detoxification genes, such as those coding
for the cytochromes P450 monooxygenases CYP1A1, CYP1B1, and CYP1A2, and of phase
II detoxification genes, such as those coding for quinone oxido-reductase
(NQO1), glutathione-S-transferase (GST1) and UDP-glucuronosyl transferase (UDPGT). Preliminary work has shown that exposure of cultured mammalian cells to chromateor arsenite disrupts the coordinate induction of phase I and phase II
genes by Ah receptor ligands. Chromate inhibits induction of phase II
genes to a greater extent than induction of phase I genes, whereas arsenite has
little effect on phase I gene induction, but superinduces phase II genes. These observations have led to the hypothesis that combined exposure to a
mixture of B[a]P and chromate or arsenite, 1) disrupts the regulatory mechanisms
that control transcription from B[a]P-inducible gene promoters; 2)causes
an uncoupling of phase I and phase II gene expression and a concomitant
imbalance in B[a]P metabolism; and 3) produces a characteristic "gene expression
signature" that can be used as a molecular biomarker of exposure and of the
health effects of the mixture. Results from this work will help develop a
means to predict the health risks arising from exposure to chemical mixtures.
Techniques Incorporated:
Global Gene Expression Analysis by Microarray Hybridization
Mass Spectrometry
Real Time PCR
Keywords:
Microarrays
Real Time PCR
Proteomics
Chromium
Arsenite
PAHs
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