New insights into organ-specific oxidative stress mechanisms using a novel biosensor zebrafish

Sulayman Mourabit; Jennifer A Fitzgerald; Robert P Ellis; Aya Takesono; Cosima S Porteus; Maciej Trznadel; Jeremy Metz; Matthew J Winter; Tetsuhiro Kudoh; Charles R Tyler

doi:10.1016/j.envint.2019.105138

New insights into organ-specific oxidative stress mechanisms using a novel biosensor zebrafish

Environ Int. 2019 Dec;133(Pt A):105138. doi: 10.1016/j.envint.2019.105138. Epub 2019 Oct 20.

Affiliations

¹ Biosciences, College of Life and Environmental Sciences, University of Exeter, UK. Electronic address: sulayman.mourabit@zhaw.ch.
² Biosciences, College of Life and Environmental Sciences, University of Exeter, UK.
³ Biosciences, College of Life and Environmental Sciences, University of Exeter, UK. Electronic address: c.r.tyler@exeter.ac.uk.

PMID: 31645010
DOI: 10.1016/j.envint.2019.105138

Abstract

Background: Reactive oxygen species (ROS) arise as a result from, and are essential in, numerous cellular processes. ROS, however, are highly reactive and if left unneutralised by endogenous antioxidant systems, can result in extensive cellular damage and/or pathogenesis. In addition, exposure to a wide range of environmental stressors can also result in surplus ROS production leading to oxidative stress (OS) and downstream tissue toxicity.

Objectives: Our aim was to produce a stable transgenic zebrafish line, unrestricted by tissue-specific gene regulation, which was capable of providing a whole organismal, real-time read-out of tissue-specific OS following exposure to a wide range of OS-inducing environmental contaminants and conditions. This model could, therefore, serve as a sensitive and specific mechanistic in vivo biomarker for all environmental conditions that result in OS.

Methods: To achieve this aim, we exploited the pivotal role of the electrophile response element (EpRE) as a globally-acting master regulator of the cellular response to OS. To test tissue specificity and quantitative capacity, we selected a range of chemical contaminants known to induce OS in specific organs or tissues, and assessed dose-responsiveness in each using microscopic measures of mCherry fluorescence intensity.

Results: We produced the first stable transgenic zebrafish line Tg (3EpRE:hsp70:mCherry) with high sensitivity for the detection of cellular RedOx imbalances, in vivo in near-real time. We applied this new model to quantify OS after exposure to a range of environmental conditions with high resolution and provided quantification both of compound- and tissue-specific ROS-induced toxicity.

Discussion: Our model has an extremely diverse range of potential applications not only for biomonitoring of toxicants in aqueous environments, but also in biomedicine for identifying ROS-mediated mechanisms involved in the progression of a number of important human diseases, including cancer.

Keywords: Biosensor; Oxidative stress; Toxicants; Zebrafish.

Publication types

Research Support, Non-U.S. Gov't

MeSH terms

Animals
Animals, Genetically Modified
Antioxidant Response Elements / genetics
Antioxidant Response Elements / physiology*
Antioxidants
Biomarkers
Biosensing Techniques*
Gene Expression Regulation / drug effects
Humans
Oxidative Stress / physiology*
Reactive Oxygen Species
Water Pollutants, Chemical / chemistry
Water Pollutants, Chemical / toxicity*
Zebrafish / genetics
Zebrafish / metabolism*

Substances

Antioxidants
Biomarkers
Reactive Oxygen Species
Water Pollutants, Chemical