Gene expression profile of zebrafish exposed to hypoxia during development

doi:10.1152/physiolgenomics.00128.2002

Gene expression profile of zebrafish exposed to hypoxia during development

Christopher Ton ¹^,2, Dimitri Stamatiou ² and Choong-Chin Liew ¹^,2

¹ Department of Laboratory Medicine and Pathobiology, University of Toronto, Toronto, Ontario, M5G 1L5, Canada
² Cardiovascular Genome Unit, Brigham and Women’s Hospital, Harvard Medical School, Boston, Massachusetts 02115

Understanding how vertebrates respond to hypoxia can have importantclinical implications. Fish have evolved the ability to survivelong exposure to low oxygen levels. However, little is knownabout the specific changes in gene expression that result fromhypoxia. In this study we used a zebrafish cDNA microarray toexamine the expression of >4,500 genes in zebrafish embryosexposed to 24 h of hypoxia during development. We tested thehypotheses that hypoxia changes gene expression profile of thezebrafish embryos and that these changes can be reverted byreexposure to a normoxic (20.8% O₂) environment. Our data wereconsistent with both of these hypotheses: indicating that zebrafishembryos undergo adaptive changes in gene expression in responseto hypoxia. Our study provides a striking genetic portrait ofthe zebrafish embryos’ adaptive responses to hypoxic stressand demonstrates the utility of the microarray technology asa tool for analyzing complex developmental processes in thezebrafish.

Danio rerio; cDNA microarray

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