Issue 6, 2016

Embryonic exposure to 10 μg L−1 lead results in female-specific expression changes in genes associated with nervous system development and function and Alzheimer's disease in aged adult zebrafish brain

Abstract

A developmental lead (Pb) exposure has been proposed as an environmental risk factor for adult neurodegenerative diseases including Alzheimer’s disease (AD). Recent animal studies showed pathological characteristics of AD in adults with a developmental Pb exposure, but additional studies are needed to investigate this phenomenon. To further assess the relationship between an embryonic Pb exposure and latent neurological alterations, the brain of adult female and male zebrafish aged 12 months that were exposed to a control treatment or 10 μg L−1 Pb only during embryogenesis (1–72 hours after fertilization) were analyzed on a zebrafish-specific microarray platform. Gene ontology and pathway analysis revealed similarities in the top disease and functional categories in both sexes, but females had 4.3 times more genes altered than males. In addition, alterations in genes associated with nervous system development and function were more pronounced with a set of 89 genes associated with AD including amyloid precursor protein (APP), apolipoprotein (APOE), and sortlin-related receptor precursor (SORL1) observed to be changed in adult females. Our observations suggest that an embryonic exposure to Pb at levels as low as 10 μg L−1 disturb global gene expression patterns in a sex-specific manner that could lead to neurological alterations in later life. With these findings, future studies investigating the adverse neurological outcomes of these changes in gene expression will facilitate our understanding of the impact of an embryonic 10 μg L−1 Pb exposure on neurological disease pathogenesis and the inclusion of additional concentrations will broaden our knowledge of dose-dependent changes.

Graphical abstract: Embryonic exposure to 10 μg L−1 lead results in female-specific expression changes in genes associated with nervous system development and function and Alzheimer's disease in aged adult zebrafish brain

Supplementary files

Article information

Article type
Paper
Submitted
15 okt. 2015
Accepted
11 jan. 2016
First published
11 jan. 2016

Metallomics, 2016,8, 589-596

Author version available

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