Gene expression profiling in respiratory tissues from rats exposed to mainstream cigarette smoke

doi:10.1093/carcin/bgg193

Carcinogenesis Advance Access originally published online on October 24, 2003

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Carcinogenesis, Vol. 25, No. 2, 169-178, February 2004
© Oxford University Press; all rights reserved

CANCER BIOLOGY

Gene expression profiling in respiratory tissues from rats exposed to mainstream cigarette smoke

Stephan Gebel¹^,, Bernhard Gerstmayer², Andreas Bosio², Hans-Jürgen Haussmann¹^,, Erik Van Miert³^, and Thomas Müller¹^,4^,

¹ Philip Morris Research Laboratories GmbH, Fuggerstrasse 3, D-51149 Köln, Germany, ² Memorec Stoffel GmbH, Stöckheimer Weg 1, D-50829 Köln, Germany^,+ and ³ Philip Morris Research Laboratories bvba, Grauwmeer 14, B-3001 Leuven, Belgium

Cigarette smoke (CS) is known to cause cancer and other diseases,but little is known about the global molecular and cellularchanges that occur prior to the appearance of clinically detectablesymptoms. Using DNA microarrays covering 2031 cDNA probes, weinvestigated differential gene expression in tissues of therat respiratory tract, i.e. respiratory nasal epithelium (RNE)and lungs of rats exposed either acutely (3 h) or subchronically(3 h/day, 5 days/week, 3 weeks) to mainstream CS with deatheither immediately or at 20 h after exposure. Differential geneexpression was most evident in RNE of rats exposed once andwas characterized by strong up-regulation of genes encodingoxidative stress-responsive and Phase II drug-metabolizing enzymes,such as haem oxygenase-1 and NAD(P)H:quinone oxidoreductase,which are all, at least in part, transcriptionally regulatedby NF-E2-related factor 2 (Nrf2). After 3 weeks of exposure,the strength of expression of this class of genes was markedlyreduced, pointing to an adaptive response. The generally lowerresponse in the lungs of exposed rats is indicative of a depositiongradient of active smoke constituents from the upper to thelower respiratory tract. In sharp contrast to the CS-inducedexpression of oxidative stress and Phase II-responsive genes,induction of the genes encoding the Phase I drug-metabolizingenzymes cytochrome P450 (CYP)1A1 and aldehyde dehydrogenase-3was not reduced after 3 weeks of exposure and was similarlyhigh in lungs and RNE. Gene expression patterns in rats allowedto recover for 20 h showed that the CS-induced transcriptionalchanges observed immediately after exposure returned almostcompletely to normal, even after 3 weeks of repeated CS exposure.In general, these results demonstrate that CS induces a specificdifferential gene expression pattern in vivo, which may be instrumentalin identifying the molecular mechanisms leading to the onsetof inflammatory and/or morphological changes.

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